WO2014015783A1

WO2014015783A1 - Flow controller and water treatment system having same

Info

Publication number: WO2014015783A1
Application number: PCT/CN2013/079857
Authority: WO
Inventors: 胡霄宗; 胡继宗; 涂泽红
Original assignee: Hu Xiaozong; Hu Jizong; Tu Zehong
Priority date: 2012-07-24
Filing date: 2013-07-23
Publication date: 2014-01-30
Also published as: CN104508340A; CN102788172A; CN102788172B; CN104508340B

Abstract

A multi-functional control valve capable of continuously supplying water, comprising a valve body (30), a cover (60), a fixed valve plate (10), and a movable valve plate (20); the movable valve plate (20) is connected to a valve rod (61); the control valve is provided with a water inlet (31), a water outlet (32), a sewage outlet (33), a first port (38) of a No.1 filter element, a second port (39) of the No.1 filter element, a first port (78) of a No.2 filter element, and a second port (79) of the No.2 filter element thereon; the fixed valve plate (10) is provided with a first through-hole (1A), a second through-hole (2A), a third through-hole (3A), and a fourth through-hole (4A) thereon; the first through-hole (1A) communicates with the first port (38) of the No.1 filter element; the second through-hole (2A) communicates with the second port (39) of the No.1 filter element; the third through-hole (3A) communicates with the first port (78) of the No.2 filter element; and the fourth through-hole (4A) communicates with the second port (79) of the No.2 filter element; the movable valve plate (20) is provided with a water inlet channel (21B), a water outlet channel (22B), and a sewage outlet channel (24B) thereon; the water inlet channel (21B) communicates with the water inlet (31); the water outlet channel (22B) communicates with the water outlet (32); and the sewage outlet channel (24B) communicates with the sewage outlet (33). The control valve uses a single valve for achieving continuous water supply during switching between two filter elements.

Description

Flow controller and water treatment system having the same

Technical field

The present invention relates to a fluid treatment system, and more particularly to a flow controller for a fluid treatment system, wherein the flow controller is adapted to control the flow of a plurality of fluids to achieve a fluid handling function of the fluid system, which is The movement of the second flow control element of the flow control relative to its first flow control element is adjusted to regulate and control the flow of fluid in different directions of the fluid treatment system.

Background technique

In existing industrial or domestic water treatment technologies, a continuous water supply multi-function control valve is often used to perform filtration, softening, and the like of the filter element, and the treated water can be continuously supplied during the flushing or regeneration stage. In order to achieve continuous water supply during the flushing or regeneration phase, two filter cartridges are generally used, that is to say, when one filter element is supplied with water, another filter element can be flushed or regenerated, so that the two filter elements can be switched back and forth to achieve continuous water supply. First of all, the existing continuous water supply multi-function control valve is generally realized by a piston type or a plane valve, and two sets of valve cores and two sets of drive systems are generally provided in the control valve, which makes the control more complicated and the failure rate is higher; Secondly, when the control valve switches between the two filter elements, there will be a short break, which makes it difficult to adapt the existing multi-way valve in systems with high continuous water supply requirements.

(1) Technical problems to be solved

The technical problem to be solved by the present invention is to provide a continuous water supply multi-function control valve, which overcomes the need for two sets of valve cores to realize continuous water supply in the existing control valve, so that the control valve has a complicated structure, a high failure rate, and when the filter element is switched. A short-term water break.

(ii) Technical solutions

In order to achieve the above object, the present invention provides a continuous water supply multi-function control valve, comprising a valve body, a cover, a fixed valve piece and a movable valve piece which are arranged in the valve body and which are rotated and sealed with an end face, a movable valve piece and a valve stem phase. Connection, the control valve is provided with a water inlet, a water outlet, a sewage outlet, a first interface of the first filter element, a second interface of the first filter element, a first interface of the second filter element and a second interface of the second filter element, and the fixed valve piece is provided with: The first through hole, the second through hole, the third through hole and the fourth through hole pass through an internal flow path of the control valve, and the first through hole communicates with the first interface of the first filter element, and the second through hole and the first filter element The second interface is connected, the third through hole is connected with the first interface of the second filter element, and the fourth through hole is connected with the second interface of the second filter element; the water inlet channel, the water outlet flow channel and the sewage flow path are arranged on the movable valve plate Through the internal flow path of the control valve, The water inlet channel is connected with the water inlet, the water outlet channel is connected with the water outlet, and the sewage channel is connected with the sewage outlet.

Further, the first through hole and the third through hole of the fixed valve piece are disposed on the outer ring and the middle ring of the fixed valve piece, and the second through hole and the fourth through hole of the fixed valve piece are disposed in the middle ring and the inner ring of the fixed valve piece on.

Further, the water inlet passage of the movable valve piece is disposed on the outer ring of the movable valve piece; the water outlet flow path of the movable valve piece is disposed on the center, the inner ring and the middle ring of the movable valve piece; the sewage flow path of the movable valve piece is set in motion On the middle ring of the valve.

Further, the center of the fixed valve piece is further provided with a ninth through hole, and the water outlet passage of the movable valve piece is a water outlet blind hole, and the outlet water conduction blind hole communicates with the water outlet through the ninth through hole.

Further, the outlet conduction blind hole includes a back cover, a side wall extending upward along the back cover, and a beam between the side walls, the beam being disposed at the top of the side wall.

Further, the sewage flow channel is a sewage through hole, and the sewage outlet is disposed on the cover, and the sewage through hole is sequentially connected to the sewage outlet on the cover through the first sewage through hole on the valve stem and the second sewage through hole on the cover.

Further, the sewage flow passage is a sewage through hole, and the sewage outlet is disposed on the valve body, and the sewage through hole is sequentially connected to the sewage outlet on the valve body through the first sewage through hole on the valve stem and the second sewage through hole on the cover.

Further, the control valve is further provided with a jet and a salt suction port, and the control valve is further provided with a jet outlet and a jet inlet connected to the jet; the fixed valve plate is also provided with a jet outlet flow passage and a jet The inlet flow passage communicates with the jet outlet through the internal flow passage of the control valve, and the jet inlet flow passage communicates with the jet inlet; the movable valve plate is further provided with a conduction blind hole.

Further, the jet outlet flow passage of the fixed valve piece includes a fifth through hole and a sixth through hole, and the fifth through hole and the sixth through hole communicate with each other and communicate with the jet outlet through the internal flow path of the control valve; The jet inlet flow passage of the valve piece includes a seventh through hole and an eighth through hole, and the seventh through hole and the eighth through hole communicate with each other and communicate with the jet inlet through the internal flow path of the control valve; the fifth through hole The sixth through hole, the seventh through hole and the eighth through hole are disposed on the middle ring of the fixed valve piece; the conductive blind hole of the movable valve piece is disposed on the middle ring of the movable valve piece.

Further, the control valve is further provided with a No. 1 jet, a No. 2 jet, a No. 1 suction port and a No. 2 suction port, and a No. 1 jet outlet connected to the No. 1 jet is arranged in the control valve and The first jet inlet is further provided with a second jet outlet and a second jet inlet connected to the second jet; the fixed valve plate is further provided with a fifth through hole, a sixth through hole, a seventh through hole and The eighth through hole passes through the inner flow passage of the control valve, and the fifth through hole communicates with the outlet of the first jet, the seventh through hole and the first one The inlet of the jet is connected, the sixth through hole is connected with the outlet of the second jet, and the eighth through hole is connected with the inlet of the second jet; the blind hole is also arranged on the movable valve piece; the fifth through hole, the sixth The through hole, the seventh through hole and the eighth through hole are disposed on the middle ring of the fixed valve piece; the conductive blind hole of the movable valve piece is disposed on the middle ring of the movable valve piece.

(3) Beneficial effects

Advantageous Effects of the Invention: Since only one set of spools is used to realize the function of continuous water supply, the structure of the system is simplified, the failure rate of the system is reduced, and at the same time, the rational design of the spool passage is made in the spool When the filter element is switched, a true continuous water supply is achieved, which eliminates the temporary water cut of the existing product.

Fluid control and / or treatment systems, such as water treatment systems, are common in industrial production and in people's real lives. A typical fluid handling system typically includes a flow control device and a processing unit, wherein the flow control device is adapted to control the flow of fluid to the processing unit, and the processing unit is adapted to process the fluid to be treated to obtain a treated fluid. When the fluid treatment system processes the fluid to be treated, such as when the water treatment system is to treat the treated water, the flow controller for controlling fluid flow for fluid processing purposes typically includes one or more single-function valves and/or multi-function valves. Flowing, processing units for treating fluids to obtain treated fluids are more commonly used with filtration devices such as membranes, activated carbon, and/or ion exchange devices, such as resin/ion exchange chromatography columns. In practical applications, membranes, activated carbon, and resins used in fluid handling systems often require frequent replacement or regeneration to enable good filtration or removal of ions from the fluid. When the user replaces or regenerates the filter membrane, activated carbon, resin, etc. of the processing unit of the fluid treatment system, it is often necessary to interrupt the fluid treatment of the fluid treatment system, which brings a large time cost to the user. Current common fluid handling systems, such as water treatment systems, typically include only one water treatment device capable of treating the treated water, and once damaged, the supply of treated water will cease. However, in some applications, especially in industrial applications, the continuous supply of standards-compliant fluids is important, such as the cooling water required in the steelmaking process, not only in compliance with standards, but also in continuous supply. Therefore, it is necessary to be able to treat the treated water uninterruptedly to continuously provide a water treatment system for the treated water.

Chinese Patent Application No. CN200610024561.0 discloses a water treatment system, wherein the water treatment system of the water treatment system comprises two three-way ball valves, two inlet pipes, one outlet pipe and two sewage pipes, the water treatment The processing unit of the system comprises two clean water buckets arranged in parallel, the clean water bucket has an open upper end opening and a central pipe, wherein the water inlet pipe and the upper end of the water purification bucket respectively The openings are connected to each other; when the outlet pipes are respectively connected with the central pipe of the purification bucket, the two purification buckets of the water treatment system are treated for purification; when an inlet pipe is connected to the upper opening of the corresponding purification bucket, And adjusting the corresponding three-way valve to disconnect the other inlet water source from the external water source and the corresponding sewage pipe, the two water purification tanks of the water treatment system are in a water treatment state, and one is in a backwash state, thereby The water treatment system is configured to continue processing the treated water and provide untreated water to the user while one of the water purification buckets is in the regeneration process.

However, this water treatment system also has a number of disadvantages. First, the water treatment system lacks the configuration using the regeneration solution, and the water treatment device of the water treatment system cannot be regenerated by the regeneration solution while providing the treated water. Secondly, the water treatment system requires at least two valves to regulate the communication between the inlet opening of the inlet pipe and the purification bucket and the drain pipe to control the flow of the water flow, which is inconvenient for the user. At the same time, the use of multiple valves also creates difficulties for the automatic control of the entire water treatment system. Finally, the use of multiple valves has resulted in the need to configure multiple interconnecting pipes throughout the water treatment system, resulting in a complicated installation of the entire water treatment system, which is inconvenient for the user.

Summary of the invention

The main advantage of the present invention is that it provides a flow control device that is suitable for use in a water treatment system and that controls a plurality of water flows in different directions at different working positions.

Another advantage of the present invention is that it provides a flow controller, wherein the flow controller includes a first flow control element and a second flow control element, wherein the first flow control element and the second flow control element are both a plurality of fluid passages are provided, and when the second control element rotates relative to the first flow control element, the fluid passages of the second flow control element respectively communicate with different fluid passages of the first flow control element, thereby enabling the control The flow device can control the multidirectional flow of fluid flowing between the first flow control element and the second flow control element, respectively, at different working positions.

Another advantage of the present invention is that it provides a flow controller, wherein the flow controller further includes a housing, wherein the housing has a plurality of fluid passages respectively connected to the first flow control element provided on the flow control device An opening through which the fluid can flow into the fluid passage of the first flow control element of the flow control device, such that when the second control element is rotated relative to the first flow control element, When the flow controller is in different working positions, the flow controller is capable of controlling the flow of fluid flowing into the fluid passage of the first flow control element provided in the flow control device.

Another advantage of the present invention is that it provides a flow controller, wherein the flow controller further includes a a flow blocking element, wherein the flow blocking element extends downward from a lower end portion of the first flow control body of the first flow control element of the flow control device to form a first flow guiding chamber and a second flow guiding chamber Wherein the flow blocking element is capable of separating fluid flowing through the first flow guiding chamber and the second flow guiding chamber.

Another advantage of the present invention is that it provides a flow controller, wherein the flow controller further includes a first jet and/or a second jet, wherein the first jet and the second jet are adapted The regeneration solution in the liquid distribution tank is sucked into and guided into a fluid passage provided in the first flow control body of the flow control device, and under the control and guidance of the flow control device, flows to the first connection with the flow control device a water treatment element or the second water treatment element to regenerate the water treatment resin particles of the first water treatment element or the second water treatment element.

Another advantage of the present invention is that it provides a flow control device in which the flow control device does not require precise components and complicated structures, and is simple in manufacturing process and low in cost.

Another advantage of the present invention is that it provides a water treatment system, wherein the water treatment system includes a flow controller and a water treatment unit, wherein the flow controller is adapted to control a plurality of fluids, such as a flow of water, the water The processing unit includes a first water treatment component and a second water treatment component, wherein when one of the first water treatment component or the second water treatment component of the processing unit needs to be replaced or regenerated, the other can continue to fluid The treatment, such as softening of the water to be treated, provides the user with untreated fluid, such as demineralized water, without interruption.

The other advantages and features of the invention are apparent from the following detailed description and the <RTIgt;

According to the present invention, the flow controller of the present invention capable of achieving the foregoing and other objects and advantages includes: a first flow control element and a second flow control element rotatably disposed on the first flow control element, wherein the a flow control element includes a first flow control body, the first flow control body includes a top end portion, wherein the top end portion forms a first flow control surface; the second flow control element includes a second flow control body, The second flow control body has a bottom end portion and a high end portion extending upward from the bottom end portion, the bottom end portion forming a second flow control surface; wherein the second flow control surface of the second flow control element is suitable Rotatably disposed on the first flow control surface of the first flow control element,

The flow controller has a first channel, a second channel, a third channel, a fourth channel, a fifth channel, a sixth channel, a seventh channel, an eighth channel, and a ninth channel. , a tenth channel, an eleventh channel, a twelfth channel, a thirteenth channel, a fourteenth channel, a fifteenth channel, a sixteenth channel, a tenth a seven channel, an eighteenth channel, a nineteenth channel, a twentieth channel, a twenty-first channel, a twenty-second channel, and a twenty-third channel, wherein the first channel, the first a second channel, the third channel, the fourth channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, the ninth channel, the tenth channel, the H^-channel, The twelfth channel, the thirteenth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel, and the seventeenth channel are respectively disposed on the first flow control body of the first current control component And extending from the first flow control surface of the first flow control body of the first flow control element; the eighteenth channel is disposed at a bottom end of the second flow control body and from a bottom of the second flow control body The second control flow of the end faces upwardly and outwardly and forms a conduction opening that is always in communication with the external space of the flow controller; the nineteenth channel, the twentieth channel, the second eleventh The channel, the twenty-second channel, and the twenty-third channel are respectively disposed on a bottom end portion of the second flow control body extends upward from a second flow control surface of the bottom end portion of the second flow control body, wherein the nineteenth channel and the second eleventh channel are respectively disposed on the second tenth The outside of the channel is in communication with the twentieth channel.

In order to achieve the foregoing and other objects of the present invention, the present invention still further provides a water treatment system, wherein the water treatment system comprises:

a flow controller; and

a water treatment unit, wherein the water treatment unit is disposed at the flow control device, and the water flow can flow between the water treatment unit and the flow controller under the control and guidance of the flow control device,

Wherein the flow control device comprises a first flow control element, a second flow control element and a casing, wherein the first flow control element comprises a first flow control body, and the first flow control body comprises a top end portion, wherein The top portion forms a first flow control surface; the second flow control element includes a second flow control body, the second flow control body has a bottom end portion and a high end portion extending upward from the bottom end portion, The bottom end portion defines a second flow control surface; wherein the second flow control surface of the second flow control element is adapted to be rotatably disposed on the first flow control surface of the first flow control element, wherein the flow control device Having a first channel, a second channel, a fourth channel, a fifth channel, a sixth channel, a ninth channel, a tenth channel, an eleventh channel, a thirteenth channel, a first Fourteen channels, one fifteenth channel, one eighteenth channel, one nineteenth channel, one twentieth channel, one twenty-first channel and one twenty-third channel, wherein the first channel, the first two Channel, the fourth channel, the fifth channel, the sixth channel, the ninth channel, the tenth channel, the H^-channel, the thirteenth channel, the fourteenth channel, and the fifteenth Channels are respectively disposed on the first flow control component The first flow control body extends downward from the first flow control surface of the first flow control body of the first flow control element; the nineteenth channel, the twentieth channel, the second H^ channel, and the The twenty-third channel is respectively disposed at a bottom end portion of the second flow control body and extends from a second control flow surface of the bottom end portion of the second flow control body, wherein the nineteenth channel and the twentieth channel a channel is respectively disposed outside the twentieth channel and is respectively connected to the twentieth channel, wherein the first flow control body of the first flow control component of the flow controller further includes a downward direction from the top end An extended lower end portion, wherein the outer casing includes a casing body, wherein the casing body extends outwardly and upwardly from a lower end portion of the first flow control body of the first flow control element and is enclosed as a first receiving chamber The eighteenth channel is disposed at a bottom end portion of the second flow control body and extends upward and outward from a second control flow surface of the bottom end portion of the second flow control body to form a first and the first a conduction opening in which the receiving chamber communicates, wherein the outer casing has a first opening a second opening, a third opening and a fourth opening, wherein the first receiving chamber is in communication with the first opening, the ninth channel extending downward from the first flow control surface of the first flow control element And extending from the lower end portion of the first flow control body of the first flow control element to communicate with the second opening; the tenth channel and the eleventh channel from the first of the first flow control element The control flow extends downwardly and communicates with the third opening; the thirteenth channel, the fourteenth channel and the fifteenth channel extend downward from the first control flow of the first flow control element and both The fourth opening is in communication, wherein the first opening of the outer casing of the flow control is in communication with an external water source; the third opening and the fourth opening of the outer casing of the flow control are respectively connected to the water treatment unit .

Further objects and advantages of the present invention will be fully realized from the following description and appended claims.

These and other objects, features and advantages of the present invention will become apparent from

DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a plan view of a valve body of the present invention.

Fig. 2 is a plan view showing the planar structure of the fixed valve piece of the first embodiment.

Fig. 3 is a plan view showing a movable valve piece of the first embodiment.

Fig. 4 is a bottom view of the movable valve piece of the first embodiment.

Figure 5 is a cross-sectional view taken along line 4C-C of Figure 4;

Fig. 6 is a structural schematic view showing the operation state of the No. 2 filter element in the first embodiment of the first filter element softening and salt absorption countercurrent regeneration. Fig. 7 is a schematic view showing the relative positions of the movable and fixed valve plates of Fig. 6.

Fig. 8 is a structural schematic view showing the state in which the first filter element is softened and the salt tank is hydrated in the first embodiment. Figure 9 is a schematic view showing the relative positions of the movable and fixed valve plates of Figure 8.

Fig. 10 is a structural schematic view showing the state in which the first filter element is softened and the second filter element is backwashed in the first embodiment.

Figure 11 is a schematic view showing the relative positions of the movable and fixed valve plates of Figure 10;

Fig. 12 is a structural schematic view showing the state in which the first filter element is softened and the second filter element is being flushed in the first embodiment.

Figure 13 is a schematic view showing the relative positions of the movable and fixed valve plates of Figure 12;

Fig. 14 is a structural schematic view showing the softening operation state of the first filter element in the first embodiment.

Figure 15 is a schematic view showing the relative positions of the movable and fixed valve plates of Figure 14.

Fig. 16 is a structural schematic view showing the operation state of the first filter element in the softening and salt absorption countercurrent regeneration of the No. 2 filter element in the first embodiment.

Figure 17 is a schematic view showing the relative positions of the movable and fixed valve plates of Figure 16;

Fig. 18 is a schematic view showing the relative positions of the movable and fixed valve plates in the softening state of the second filter element and the water supply state of the salt tank in the first embodiment.

Fig. 19 is a schematic view showing the relative positions of the movable and fixed valve plates in the state in which the No. 2 filter element is softened and the No. 1 filter element is backwashed.

Fig. 20 is a schematic view showing the relative positions of the movable and fixed valve plates in the state in which the No. 2 filter element is softened and the No. 1 filter element is being flushed.

Figure 21 is a schematic view showing the relative positions of the movable and fixed valve plates in the softened state of the second filter element in the first embodiment. Figure 22 is a plan view showing the planar structure of the fixed valve piece of the second embodiment.

Figure 23 is a plan view of the movable valve piece of the second embodiment.

Figure 24 is a bottom view of the movable valve piece of the second embodiment.

Figure 25 is a cross-sectional view taken along the line B-B of Figure 24;

Figure 26 is a schematic view showing the relative positions of the movable and fixed valve plates in the softened state of the first filter element in the second embodiment. Fig. 27 is a schematic view showing the relative positions of the movable and fixed valve plates in the second embodiment of the filter element softening and the second filter element backwashing state in the second embodiment.

Fig. 28 is a structural schematic view showing the operation state of the second filter element in the first embodiment of the second embodiment of the filter element softening and salt absorption downstream. Figure 29 is a schematic view showing the relative positions of the movable and fixed valve pieces of Figure 28.

Figure 30 is a schematic view showing the relative positions of the movable and fixed valve plates in the second embodiment of the filter element softening and the salt tank hydration state in the second embodiment.

Fig. 31 is a schematic view showing the relative positions of the movable and fixed valve plates in the second embodiment of the first embodiment in which the filter element is softened and the second filter element is being flushed.

Figure 32 is a schematic view showing the relative positions of the movable and fixed valve plates in the softening state of the second filter element in the second embodiment. Figure 33 is a schematic view showing the relative positions of the movable and fixed valve plates in the second embodiment in the softening of the second filter element and the backwashing state of the first filter element.

Fig. 34 is a schematic view showing the relative positions of the movable and fixed valve plates in the state in which the No. 2 filter element is softened and the salt is moved downstream to regenerate the No. 1 filter element.

Fig. 35 is a schematic view showing the relative positions of the movable and fixed valve plates in the second embodiment in the softening of the second filter element and the water supply state of the salt tank.

Figure 36 is a schematic view showing the relative positions of the moving and fixed valve plates in the second embodiment in the case where the No. 2 filter element is softened and the No. 1 filter element is being flushed.

Figure 37 is a plan view showing the planar structure of the valve plate of the third embodiment.

Figure 38 is a plan view showing a movable valve piece of the third embodiment.

Figure 39 is a bottom view of the movable valve piece of the third embodiment.

Figure 40 is a cross-sectional view taken along the line A-A of Figure 39.

Figure 41 is a schematic view showing the structure of the filtration operation state of the first filter element in the third embodiment.

Figure 42 is a schematic view showing the relative positions of the movable and fixed valve pieces in Figure 41.

Fig. 43 is a structural schematic view showing the third embodiment of the first filter element and the second filter element backwashing operation state in the third embodiment.

Figure 44 is a schematic view showing the relative positions of the movable and fixed valve pieces of Figure 43.

Fig. 45 is a structural schematic view showing the state in which the first filter element is filtered and the second filter element is being flushed in the third embodiment.

Figure 46 is a schematic view showing the relative positions of the movable and fixed valve pieces in Figure 45.

Fig. 47 is a structural schematic view showing the simultaneous operation state of the first and second filter elements of the third embodiment. Figure 48 is a schematic view showing the relative positions of the movable and fixed valve pieces in Figure 47.

Figure 49 is a schematic view showing the relative positions of the movable and fixed valve plates in the third embodiment in the filtration state of the second filter element. Figure 50 is a third embodiment of the filter in the second filter element, the first filter element backwashing state, fixed valve Relative position diagram.

Fig. 51 is a schematic view showing the relative positions of the movable and fixed valve plates in the third embodiment in the condition that the No. 2 filter is filtered and the No. 1 filter is being flushed.

Figure 52 is a schematic view showing the relative positions of the moving and fixed valve plates in the third embodiment of the filter element of the second and the first filter elements in the third embodiment.

Figure 53 is a schematic view of the sewage outlet interface of the fourth embodiment.

Figure 54A is a perspective view of a flow control device in accordance with a fifth preferred embodiment of the present invention.

Figure 54B is an assembled view of a flow control device in accordance with a fifth preferred embodiment of the present invention.

Figure 54C is a top plan view of a second flow control element of the flow control device in accordance with a fifth preferred embodiment of the present invention. Figure 54D is a bottom plan view of the second flow control element of the flow control device in accordance with the fifth preferred embodiment of the present invention. Figure 54E is a cross-sectional view showing the second flow control element of the flow control device according to the fifth preferred embodiment of the present invention, wherein the figure illustrates the twentieth channel and the second flow control element of the flow control device The twenty-one channels are connected.

Figure 54F is a top plan view of a wear member of a flow control device in accordance with a fifth preferred embodiment of the present invention.

Figure 54G is a top plan view of a first flow control element of a flow control device in accordance with a fifth preferred embodiment of the present invention. Figure 54H is a cross-sectional view showing the first flow control element of the flow control device according to the fifth preferred embodiment of the present invention, wherein the figure illustrates the seventh channel and the sixteenth channel and the first guide of the flow controller The through channels are connected.

Figure 541 is a cross-sectional view showing the first flow control element of the flow control device according to the fifth preferred embodiment of the present invention, wherein the figure illustrates the eighth channel and the seventeenth channel and the second guide of the flow controller The through channels are connected.

Figure 54J is a bottom plan view of a flow control device in accordance with a fifth preferred embodiment of the present invention.

Figure 54K is an assembled view of an alternative embodiment of a flow control device in accordance with a fifth preferred embodiment of the present invention, wherein the flow controller illustrated in the Figure is provided with two jets.

Figure 54L is a plan view showing an alternative embodiment of the first flow control element of the flow control device according to the fifth preferred embodiment of the present invention, wherein the figure illustrates that the flow controller is provided with two jets The first flow control element.

Figure 55A is a top plan view of a first flow control element of a flow control device in accordance with a fifth preferred embodiment of the present invention.

55B is a top plan view of a second flow control element of a flow controller according to a fifth preferred embodiment of the present invention. Figure.

55C is a top plan view of a first flow control surface of a first flow control element of a flow control device according to a fifth preferred embodiment of the present invention, wherein the dotted line in the figure shows the difference of the first control flow surface. Equal parts.

55D is a top plan view showing a second flow control surface of a second flow control element of the flow control device according to the fifth preferred embodiment of the present invention, wherein the dotted line in the figure shows the difference of the second control flow surface. Equally divided areas.

Figure 55E is a top plan view of a wear member of a flow control device in accordance with a fifth preferred embodiment of the present invention, wherein the figure illustrates an alternative implementation of the wear element of the flow control device.

Figure 56A is a top plan view of a flow control device according to a fifth preferred embodiment of the present invention, wherein the figure shows that when the flow controller is in the first working position, the first flow control element of the flow control device is opposite to the The position of the second flow control element.

Figure 56B is a top plan view of a flow control device according to a fifth preferred embodiment of the present invention, wherein the first flow control element of the flow control device is opposite to the current control device when the flow control device is in the second working position. The position of the second flow control element.

Figure 56C is a top plan view of a flow controller according to a fifth preferred embodiment of the present invention, wherein the figure shows that when the flow controller is in the third working position, the first flow control element of the flow control device is opposite to the The position of the second flow control element.

Figure 56D is a top plan view of a flow control device according to a fifth preferred embodiment of the present invention, wherein the figure shows that when the flow controller is in the fourth working position, the first flow control element of the flow control device is opposite to the The position of the second flow control element.

56E is a top plan view of a flow controller according to a fifth preferred embodiment of the present invention, wherein the first flow control component of the flow controller is opposite to the flow controller when the flow controller is in the fifth working position. The position of the second flow control element.

Figure 56F is a top plan view of a flow control device according to a fifth preferred embodiment of the present invention, wherein the first flow control element of the flow control device is opposite to the current control device when the flow controller is in the sixth working position. The position of the second flow control element.

Figure 56G is a top plan view of a flow control device according to a fifth preferred embodiment of the present invention, wherein the figure shows that when the flow controller is in the seventh working position, the first flow control element of the flow control device is opposite to the The position of the second flow control element.

Figure 56H is a top plan view of a flow controller according to a fifth preferred embodiment of the present invention, wherein the figure shows that when the flow controller is in the eighth working position, the first flow control element of the flow controller is opposite to the Second control The position of the flow component.

561 is a top plan view of a flow control device according to a fifth preferred embodiment of the present invention, wherein the first flow control component of the flow control device is opposite to the current control device when the flow controller is in the ninth working position. The position of the second flow control element.

Figure 56J is a top plan view of a flow controller according to a fifth preferred embodiment of the present invention, wherein the figure shows that when the flow controller is in the tenth working position, the first flow control element of the flow control device is opposite to the The position of the second flow control element.

Figure 57 is a cross-sectional view of a water treatment system in accordance with a fifth preferred embodiment of the present invention, wherein the flow control of the water treatment system is in the first working position.

Figure 58A is a perspective view of a flow control device in accordance with a sixth preferred embodiment of the present invention.

Figure 58B is an assembled view of a flow control device in accordance with a sixth preferred embodiment of the present invention.

Figure 58C is a top plan view of a second flow control element of the flow control device in accordance with a sixth preferred embodiment of the present invention. Figure 58D is a bottom plan view of the second flow control element of the flow control device in accordance with a sixth preferred embodiment of the present invention. Figure 58E is a cross-sectional view showing a second flow control element of the flow control device according to a sixth preferred embodiment of the present invention, wherein the figure illustrates the twentieth channel and the second flow control element of the flow control device The twenty-one channels are connected.

Figure 58F is a top plan view of a wear member of a flow control device in accordance with a sixth preferred embodiment of the present invention.

Figure 58G is a top plan view of the first flow control element of the flow control device in accordance with a sixth preferred embodiment of the present invention. 58H is a cross-sectional view showing a first flow control element of a flow controller according to a sixth preferred embodiment of the present invention, wherein the figure illustrates the seventh channel and the sixteenth channel and the first guide of the flow controller. The through channels are connected.

Figure 581 is a cross-sectional view showing a first flow control element of a flow controller according to a sixth preferred embodiment of the present invention, wherein the figure illustrates the eighth channel and the seventeenth channel and the second guide of the flow controller The through channels are connected.

Figure 58J is a bottom plan view of a flow control device in accordance with a sixth preferred embodiment of the present invention.

Figure 58K is an assembled view of an alternative embodiment of a flow control device in accordance with a sixth preferred embodiment of the present invention, wherein the flow controller illustrated in the Figure is provided with two jets.

Figure 58L is a plan view showing an alternative embodiment of the first flow control element of the flow controller according to the sixth preferred embodiment of the present invention, wherein the figure illustrates that the flow controller is provided with two jets The first flow control element. Figure 59A is a top plan view of a first flow control element of a flow control device in accordance with a sixth preferred embodiment of the present invention.

Figure 59B is a top plan view of a second flow control element of a flow control device in accordance with a sixth preferred embodiment of the present invention.

59C is a top plan view of a first flow control surface of a first flow control element of a flow controller according to a sixth preferred embodiment of the present invention, wherein the dotted line in the figure shows the difference of the first control flow surface. Equal parts.

59D is a top plan view of a second flow control surface of a second flow control element of a flow controller according to a sixth preferred embodiment of the present invention, wherein the dotted line in the figure shows the difference of the second control flow surface. Equally divided areas.

Figure 59E is a top plan view of a wear element of a flow control device in accordance with a sixth preferred embodiment of the present invention, wherein the figure illustrates an alternative implementation of the wear element of the flow control device.

60A is a top plan view of a flow controller according to a sixth preferred embodiment of the present invention, wherein the first flow control element of the flow controller is opposite to the current control device when the flow controller is in the first working position. The position of the second flow control element.

60B is a top plan view of a flow controller according to a sixth preferred embodiment of the present invention, wherein the first flow control component of the flow controller is opposite to the current control device when the flow controller is in the second working position. The position of the second flow control element.

60C is a top plan view of a flow controller according to a sixth preferred embodiment of the present invention, wherein the first flow control component of the flow controller is opposite to the current control device when the flow controller is in the third working position. The position of the second flow control element.

60D is a top plan view of a flow controller according to a sixth preferred embodiment of the present invention, wherein the figure shows that when the flow controller is in the fourth working position, the first flow control element of the flow controller is opposite to the current control device. The position of the second flow control element.

60E is a top plan view of a flow controller according to a sixth preferred embodiment of the present invention, wherein the first flow control component of the flow controller is opposite to the current control device when the flow controller is in the fifth working position. The position of the second flow control element.

60F is a top plan view of a flow controller according to a sixth preferred embodiment of the present invention, wherein the figure shows that when the flow controller is in the sixth working position, the first flow control component of the flow controller is opposite to the current control device. The position of the second flow control element.

60G is a top plan view of a flow controller according to a sixth preferred embodiment of the present invention, wherein the figure shows that when the current controller is in the seventh working position, the first flow control component of the flow controller is opposite to the current control device. Second control The position of the flow component.

Figure 60H is a top plan view of a flow controller according to a sixth preferred embodiment of the present invention, wherein the figure shows that when the flow controller is in the eighth working position, the first flow control element of the flow controller is opposite to the The position of the second flow control element.

Figure 601 is a top plan view of a flow controller according to a sixth preferred embodiment of the present invention, wherein the figure shows that when the flow controller is in the ninth working position, the first flow control element of the flow control device is opposite to the The position of the second flow control element.

Figure 60J is a top plan view of a flow controller according to a sixth preferred embodiment of the present invention, wherein the figure shows that when the flow controller is in the tenth working position, the first flow control element of the flow control device is opposite to the The position of the second flow control element.

Figure 61 is a cross-sectional view of a water treatment system in accordance with a sixth preferred embodiment of the present invention, wherein the flow control of the water treatment system is in the first working position.

Figure 62A is a perspective view of a flow control device in accordance with a seventh preferred embodiment of the present invention.

Figure 62B is an assembled view of a flow control device in accordance with a seventh preferred embodiment of the present invention.

Figure 62C is a top plan view of a second flow control element of the flow control device in accordance with a seventh preferred embodiment of the present invention. Figure 62D is a bottom plan view of the second flow control element of the flow control device in accordance with a seventh preferred embodiment of the present invention. 62E is a cross-sectional view of a second flow control element of a flow control device according to a seventh preferred embodiment of the present invention, wherein the figure illustrates the twentieth channel and the second flow control element of the flow control device. The twenty-one channels are connected.

Figure 62F is a top plan view of a wear member of a flow control device in accordance with a seventh preferred embodiment of the present invention.

Figure 62G is a top plan view of a first flow control element of a flow control device in accordance with a seventh preferred embodiment of the present invention. Figure 62H is a bottom plan view of a flow control device in accordance with a seventh preferred embodiment of the present invention.

Figure 63A is a top plan view of a first flow control element of a flow control device in accordance with a seventh preferred embodiment of the present invention.

Figure 63B is a top plan view of a second flow control element of the flow control device in accordance with a seventh preferred embodiment of the present invention.

63C is a top plan view of a first flow control surface of a first flow control element of a flow control device according to a seventh preferred embodiment of the present invention, wherein the dotted line in the figure shows the difference of the first control flow surface. Equal parts.

63D is a top plan view showing a second flow control surface of a second flow control element of the flow control device according to a seventh preferred embodiment of the present invention, wherein the dotted line in the figure shows the difference of the second control flow surface. Equally divided areas. Figure 63E is a top plan view of a wear member of a flow control device in accordance with a seventh preferred embodiment of the present invention, wherein the figure illustrates an alternative embodiment of the wear element of the flow control device.

64A is a top plan view of a flow control device according to a seventh preferred embodiment of the present invention, wherein the first flow control element of the flow control device is opposite to the current control device when the current control device is in the first working position. The position of the second flow control element.

64B is a top plan view of a flow control device according to a seventh preferred embodiment of the present invention, wherein the first flow control component of the flow control device is opposite to the current control device when the flow controller is in the second working position. The position of the second flow control element.

64C is a top plan view of a flow controller according to a seventh preferred embodiment of the present invention, wherein the first flow control component of the flow controller is opposite to the current control device when the flow controller is in the third working position. The position of the second flow control element.

64D is a top plan view of a flow control device according to a seventh preferred embodiment of the present invention, wherein the first flow control element of the flow control device is opposite to the current control device when the current control device is in the fourth working position. The position of the second flow control element.

64E is a top plan view of a flow controller according to a seventh preferred embodiment of the present invention, wherein the first flow control component of the flow controller is opposite to the current control device when the flow controller is in the fifth working position. The position of the second flow control element.

64F is a top plan view of a flow control device according to a seventh preferred embodiment of the present invention, wherein the first flow control component of the flow control device is opposite to the current control device when the current control device is in the sixth working position. The position of the second flow control element.

64G is a top plan view of a flow controller according to a seventh preferred embodiment of the present invention, wherein the figure shows that when the flow controller is in the seventh working position, the first flow control component of the flow controller is opposite to the current control device. The position of the second flow control element.

64H is a top plan view of a flow control device according to a seventh preferred embodiment of the present invention, wherein the first flow control component of the flow control device is opposite to the current control device when the flow controller is in the eighth working position. The position of the second flow control element.

Figure 65 is a cross-sectional view of a water treatment system in accordance with a seventh preferred embodiment of the present invention, wherein the flow control of the water treatment system is in the first working position.

Specific real

The following description is disclosed to enable any person skilled in the art to make and use the invention. In the following description The preferred embodiments are provided by way of example only, and are not intended to limit the scope of the invention. The general principles defined in the following description may be applied to other embodiments, alternatives, modifications, equivalents and applications without departing from the spirit and scope of the invention.

As shown in Fig. 6, in the case of using the present invention, the tank body can be treated with water to constitute the casing of the No. 1 filter water treatment tank 40 and the No. 2 filter water treatment tank 80, and the No. 1 filter element 44 and the No. 2 filter element 84 are respectively disposed in one In the filter water treatment tank 40 and the second filter water treatment tank 80, or directly filling the filter material in the water treatment tank to form the filter element 44 and the filter element 84, first installing the control valve on the No. 1 filter water treatment tank 40, the valve body The first interface 38 of the first filter element 30 of 30 is communicated with the outer side of the upper collecting umbrella 41 and the first filter element 44, and the second interface 39 of the first filter element is communicated with the first filter element 44 through the central tube 42 and the lower collecting umbrella 43, the valve body 30 is connected through two external pipes and the second filter water treatment tank 80. The first interface 78 of the second filter element is sequentially connected through the external pipe, the upper set umbrella 81 and the outer side of the second filter element 84, and the second interface of the second filter element 79 It also communicates with the second filter element 84 through the external pipe, the central pipe 82, the lower collecting umbrella 83, the water inlet 31 is connected to the water source, the sewage outlet 33 is connected to the drainage, and the salt absorption port 36 is passed through the hose 50 and the salt. Box 51 The salt valve 52 is connected. When the present invention is used as a filter valve, it is only necessary to close the salt suction port 36 or use the filter valve shown in the third embodiment. By rotating the valve stem 61 electrically or manually, the valve plate 20 can be rotated to switch and maintain different overlapping states of the valve plate 10 to achieve the different functions of the present invention. In the first and second embodiments, the present invention will be specifically described by using a resin filter as an example, and the third embodiment will be specifically described by using an activated carbon filter.

Embodiment 1: Countercurrent regeneration soft water valve.

As shown in Figures 1-6, the fixed and movable valve plate combinations shown in Figures 2-3 are used. Figures 4 and 5 are a bottom view and a cross-sectional view, respectively, of the movable valve plate 20. The utility model relates to a continuous water supply multi-function control valve, which comprises a valve body 30, a jet 37, a cover 60, a fixed valve piece 10 and a movable valve piece 20 which are placed in the valve body 30 and which are rotated and sealed with an end face, a movable valve piece 20 and a valve. The rods 61 are connected, and the control valve is provided with a water inlet 31, a water outlet 32, a jet outlet 34, a jet inlet 35, a salt suction port 36, a first filter element first interface 38, a first filter element second interface 39, two No. filter first interface 78, second filter second interface 79, the jet 37 communicates with the valve body 30 through the jet outlet 34 and the jet inlet 35. The jet 37 is provided with a salt suction port 36 on the cover 60. The sewage outlet 33 is provided; the fixed valve piece 10 and the movable valve piece 20 are provided with three rings, the three rings are the inner ring, the middle ring and the outer ring, and the plurality of through holes on the fixed valve piece 10 and the movable valve piece 20 are distributed in three The fixed valve piece 10 is provided with: a first through hole 1C, a second through hole 2C, a third through hole 3C, a fourth through hole 4C, a fifth through hole 5C, a sixth through hole 6C, and a seventh Through hole 7C, number The eight through holes 8C communicate with the first port 38 of the first filter element through the internal flow path of the control valve, and the second through hole 2C communicates with the second interface 39 of the first filter element, and the third through hole 3C The second through hole 4C is in communication with the second filter port 2 of the second filter element, and the fifth through hole 4C and the sixth through hole 6C are in communication with each other and communicate with the jet outlet 34. The seven through holes 7C and the eighth through holes 8C communicate with each other and communicate with the jet inlet 35. The center of the fixed valve plate 10 is further provided with a ninth through hole 9, and the ninth through hole 9 communicates with the water outlet 32, first The through hole 1C and the third through hole 3C are disposed on the outer ring and the middle ring of the fixed valve piece 10, and the second through hole 2C and the fourth through hole 4C are disposed on the middle ring and the inner ring of the fixed valve piece 10, and the fifth through hole 5C, the sixth through hole 6C, the seventh through hole 7C and the eighth through hole 8C are disposed on the center ring of the fixed valve piece 10; the movable valve piece 20 is provided with a water inlet passage 21C, a water outlet conduction blind hole 22C, and a conduction The blind hole 23C and the sewage through hole 24C, the water inlet passage 21C is disposed on the outer ring of the movable valve piece 20, and the outlet water conduction blind hole 22C is disposed at the center and the inner ring of the movable valve piece 20 and On the middle ring, the conduction blind hole 23C and the sewage through hole 24C are disposed on the middle ring of the movable valve piece 20. As shown in FIG. 4 to FIG. 5, the water outlet blind hole 22C includes a back cover, a side wall extending upward along the back cover, and The beam 25C between the side walls, the beam 25C is disposed at the top of the side wall, and the function of the beam 25C is to isolate the passage of the water conducting blind hole 22C to the middle ring and the inner ring of the fixed valve piece 10 so that there is no water between them. The water inlet passage 21C communicates with the water inlet 31 through the internal flow passage of the control valve, and the outlet water passage blind hole 22C communicates with the water outlet 32 through the ninth through hole 9 of the fixed valve plate 10, and the sewage through hole 24C sequentially passes through the valve. The first drain hole 63 of the rod 61 and the second drain hole 64 of the cover 60 communicate with the drain port 33 on the cover 60.

No. 1 filter softening, salt absorption countercurrent regeneration No. 2 filter function: As shown in Figure 6-7, by rotating the valve stem 61, the water inlet passage 21C on the movable valve plate 20 and the first through hole on the fixed valve plate 10 1C is overlapped and communicated, and the outlet conduction blind hole 22C is in overlapping communication with the second through hole 2C, the ninth through hole 9 and the fifth through hole 5C, and the conduction blind hole 23C is overlapped with the seventh through hole 7C and the fourth through hole 4C. The drain through hole 24C is in overlapping communication with the third through hole 3C. In the valve plate overlapping state, the water flow is as follows: the water entering the water inlet port 31 flows into the first through hole 1C of the fixed valve piece 10 from the water inlet passage 21C of the movable valve piece 20, because the first through hole 1C and the first one are The first interface 38 of the filter element is in communication, so the water flows through the first interface 38 of the first filter element, passes through the upper collecting umbrella 41, flows into the outer side of the filter element 44, is softened by the resin, flows into the lower collecting umbrella 43, and flows into the lower collecting umbrella 43 through the inner side of the filter element 45. The second interface 39 of the first filter element 39, because the second interface 39 of the first filter element communicates with the second through hole 2C, the water flows to the second through hole 2C because the outlet water passes through the blind hole 22C and the second through hole 2C, The nine through holes 9 and the fifth through holes 5C are in overlapping communication, so that one water flow passes through the diversion of the outlet water through the blind holes 22C, and flows to the ninth through holes 9, because the ninth through holes 9 and the effluent The port 32 is in communication, so that the water flows to the water outlet 32 for water supply, and the other water flow passes through the outlet of the outlet water blind hole 22C to flow to the fifth through hole 5C because the fifth through hole 5C communicates with the jet outlet 34. Therefore, the water flows through the jet outlet 34, passes through the jet 37, generates a negative pressure at the suction port 36 of the jet 37, and draws the brine in the salt tank 51 through the salt valve 52 and the hose 50, soft water and brine. The mixed brine flows to the jet inlet 35. Since the jet inlet 35 communicates with the seventh through hole 7C, the water flows to the seventh through hole 7C, and flows into the fourth through hole 4C through the flow guiding through the blind hole 23C. Because the fourth through hole 4C is in communication with the second filter element 79 of the second filter element, the water flows through the second interface 79 of the second filter element, then flows through the inner side 85 of the filter element, and flows through the lower collecting umbrella 83 to the filter element 84, from the resin layer. The lower part flows upward, and the mixed brine countercurrently regenerates the resin, and then flows through the upper collecting umbrella 81 to the first interface 78 of the second filter element. Since the first interface 78 of the second filter element communicates with the third through hole 3C, the water flows to the first Three-way hole 3C, because the sewage through hole 24C overlaps with the third through hole 3C , So that the water flows through hole 24C sewage, sewage then passes through a second through hole through a first discharge hole 63 on the stem 60 and the cover 61 through the drain 64 33 outfall. During this process, the sixth through hole 6C and the eighth through hole 8C are passively closed to cover the waterless flow.

No. 1 filter softening, salt tank hydration function: As shown in Figure 8-9, by rotating the valve stem 61, the water inlet passage 21C on the movable valve plate 20 and the first through hole 1C on the fixed valve plate 10 are overlapped and connected. The effluent conduction blind hole 22C is in overlapping communication with the second through hole 2C, the ninth through hole 9 and the seventh through hole 7C, and the conduction blind hole 23 C is in overlapping communication with the third through hole 3C and the fourth through hole 4C. The hole 24C is closed by the fixed valve piece 10. In the valve plate overlapping state, the water flow is as follows: the water entering the water inlet port 31 flows into the first through hole 1C of the fixed valve piece 10 from the water inlet passage 21C of the movable valve piece 20, because the first through hole 1C and the first one are The first interface 38 of the filter element is in communication, so the water flows through the first interface 38 of the first filter element, passes through the upper collecting umbrella 41, flows into the outer side of the filter element 44, is softened by the resin, flows into the lower collecting umbrella 43, and flows into the lower collecting umbrella 43 through the inner side of the filter element 45. The second interface 39 of the first filter element 39, because the second interface 39 of the first filter element communicates with the second through hole 2C, the water flows to the second through hole 2C because the outlet water passes through the blind hole 22C and the second through hole 2C, The nine through holes 9 and the seventh through holes 7C are in overlapping communication, so that one water flow passes through the diversion of the outlet water through the blind holes 22C and flows to the ninth through holes 9, because the ninth through holes 9 communicate with the water outlet 32, so the water flow The water flows to the water outlet 32, and the other water flows through the outlet of the water outlet blind hole 22C to the seventh through hole 7C. Since the seventh through hole 7C communicates with the jet inlet 35, the water flows to the jet inlet. 35, then enter through the salt port 36, the hose 50 and the salt valve 52 in sequence Box 51. In this process, although the conduction blind hole 23C overlaps with the third through hole 3C and the fourth through hole 4C, it is not water-free. The sewage through hole 24C is closed by the fixed valve plate 10 to cover the waterless flow; the fifth through hole 5C, the sixth through hole 6C and the eighth through hole 8C are closed to cover the waterless flow.

No. 1 filter softening, No. 2 filter backwash function: As shown in Fig. 10-11, by rotating the valve stem 61, the water inlet passage 21C on the movable valve plate 20 and the first through hole 1C on the fixed valve plate 10 are overlapped. The communication outlet blind hole 22C is in overlapping communication with the second through hole 2C, the ninth through hole 9 and the fourth through hole 4C, and the conduction blind hole 23C is only overlapped with the third through hole 3C, and the sewage through hole 24C and the first The three through holes 3C are overlapped and connected. In the valve plate overlap state, the water flow is as follows: the water flow entering the water inlet port 31 flows into the first through hole 1C of the fixed valve piece 10 from the water inlet passage 21C of the valve plate 20, because the first through hole 1C and the first one are The first interface 38 of the filter element is in communication, so the water flows through the first interface 38 of the first filter element, passes through the upper collecting umbrella 41, flows into the outer side of the filter element 44, is softened by the resin, flows into the lower collecting umbrella 43, and flows into the lower collecting umbrella 43 through the inner side of the filter element 45. The second interface 39 of the first filter element 39, because the second interface 39 of the first filter element communicates with the second through hole 2C, the water flows to the second through hole 2C because the outlet water passes through the blind hole 22C and the second through hole 2C, The nine through holes 9 and the fourth through holes 4C are in overlapping communication, so that one water flow passes through the diversion of the outlet water through the blind holes 22C and flows to the ninth through holes 9, because the ninth through holes 9 communicate with the water outlet 32, so the water flow The water flows to the water outlet 32, and the other water flows through the outlet of the water outlet blind hole 22C to the fourth through hole 4C. Since the fourth through hole 4C communicates with the second interface 79 of the second filter element, the water flows through No. 2 filter second interface 79, flow The inner side of the filter element 85 flows through the lower collecting umbrella 83, and after flushing the filter element 84, flows through the upper collecting umbrella 81 and flows to the first interface 78 of the second filter element, because the first interface 78 of the second filter element is connected to the third through hole 3C. Therefore, the water flows to the third through hole 3C. Since the drain through hole 24C and the third through hole 3C are in overlapping communication, the water flows to the drain through hole 24C, and sequentially passes through the first drain through hole 63 on the valve stem 61 and The second drain through hole 64 in the cover 60 is then drained through the drain port 33. During this process, the conduction blind hole 23C is only overlapped with the third through hole 3C, which serves as a closed cover; the fifth through hole 5C, the sixth through hole 6C, the seventh through hole 7C, and the eighth through hole 8C The passive valve plate 20 is closed to cover the waterless flow.

No. 1 filter softening, No. 2 filter flushing function: As shown in Fig. 12-13, by rotating the valve stem 61, the water inlet passage 21C on the movable valve plate 20 and the first through hole 1C on the fixed valve plate 10 are overlapped. The communication outlet blind hole 22C is in overlapping communication with the second through hole 2C, the ninth through hole 9 and the third through hole 3C, and the conduction blind hole 23C is only overlapped with the third through hole 3C, and the sewage through hole 24C and the first The four through holes 4C are overlapped and connected. In the valve plate overlap state, the water flow is as follows: the water flow entering the water inlet port 31 flows into the first through hole 1C of the fixed valve piece 10 from the water inlet passage 21C of the valve plate 20, because the first through hole 1C and the first through hole 1C The first interface 38 of the filter element is in communication, so the water flows through the first interface 38 of the first filter element, passes through the upper collecting umbrella 41, flows into the outer side of the filter element 44, is softened by the resin, flows into the lower collecting umbrella 43, and flows in through the inner side 45 of the filter element. Go to the second interface 39 of the first filter element, because the second interface 39 of the first filter element communicates with the second through hole 2C, the water flows to the second through hole 2C, because the outlet water passes through the blind hole 22C and the second through hole 2C, The ninth through hole 9 and the third through hole 3C are overlapped and connected, so that one water flow passes through the diversion of the outlet water conduction blind hole 22C and flows to the ninth through hole 9, because the ninth through hole 9 communicates with the water outlet 32, so The water flows to the water outlet 32 for water supply, and the other water flows through the outlet of the water outlet blind hole 22C to the third through hole 3C. Since the third through hole 3C communicates with the second interface 78 of the second filter element, the water flow The first interface 78 of the second filter element passes through the upper collecting umbrella 81, flows into the outer side of the filter element 84, rinses the residual brine, and flows into the lower collecting umbrella 83, and flows into the second interface 79 of the second filter element through the inner side 85 of the filter element, because The second filter port 79 is connected to the fourth through hole 4C. Therefore, the water flows to the fourth through hole 4C. Since the sewage through hole 24C and the fourth through hole 4C are in overlapping communication, the water flows to the sewage through hole 24C, and sequentially passes through the first sewage through hole 63 and the cover on the valve stem 61. The second drain hole 64 on the 60 is drained through the drain port 33. During this process, the conduction blind hole 23C is only overlapped with the third through hole 3C, which serves as a closed cover; the fifth through hole 5C, the sixth through hole 6C, the seventh through hole 7C, and the eighth through hole 8C The passive valve plate 20 is closed to cover the waterless flow.

No. 1 filter softening function: As shown in Fig. 14-15, by rotating the valve stem 61, the water inlet passage 21C on the movable valve plate 20 and the first through hole 1C on the fixed valve plate 10 are overlapped and connected, and the water outlet is blind. The hole 22C is in overlapping communication with the second through hole 2C and the ninth through hole 9. The conduction blind hole 23C is in overlapping communication with the third through hole 3C and the fourth through hole 4C, and the drain through hole 24C is closed by the fixed valve piece 10. In the valve plate overlapping state, the water flow is as follows: the water entering the water inlet port 31 flows into the first through hole 1C of the fixed valve piece 10 from the water inlet passage 21C of the movable valve piece 20, because the first through hole 1C and the first one are The first interface 38 of the filter element is in communication, so the water flows through the first interface 38 of the first filter element, passes through the upper collecting umbrella 41, flows into the outer side of the filter element 44, is softened by the resin, flows into the lower collecting umbrella 43, and flows into the lower collecting umbrella 43 through the inner side of the filter element 45. The second filter port No. 1 of the first filter element 39, because the second interface 39 of the first filter element communicates with the second through hole 2C, the water flows to the second through hole 2C because the outlet water passes through the blind hole 22C and the second through hole 2C, The nine through holes 9 are overlapped and communicated, so that the water flows through the outlet of the outlet water blind holes 22C and flows to the ninth through holes 9, because the ninth through holes 9 communicate with the water outlet 32, so that the water flows to the water outlet 32 to supply water. In this process, the via blind via 23C is in overlapping communication with the third via 3C and the fourth via 4C, but has no water flow; the fifth via 5C, the sixth via 6C, the seventh via 7C, and the eighth pass The hole 8C passive valve plate 20 is closed to cover the waterless flow; The blowdown through hole 24C is closed by the fixed valve piece 10 to cover the waterless flow.

The above five functions are to illustrate the five stations for rinsing and regenerating the No. 2 filter element while the No. 1 filter is softened. Since the design of the fixed valve plate 10 as shown in FIG. 2 is rotationally symmetrical, as shown in FIG. The left half of the fixed valve plate 10 corresponds to the No. 1 filter element 44, and the right half of the fixed valve plate 10 corresponds to the No. 2 filter element 84, so the five functions of the No. 2 filter element softening and flushing and regenerating the No. 1 filter element are similar to the above five functions. , here is a brief description.

No. 2 filter softening, salt absorption countercurrent regeneration No. 1 filter function: As shown in Figure 16-17, by rotating the valve stem 61, the water inlet passage 21C on the movable valve plate 20 and the third through hole on the fixed valve plate 10 3C is overlapped and communicated, and the outlet conduction blind hole 22C is in overlapping communication with the fourth through hole 4C, the ninth through hole 9 and the sixth through hole 6C, and the conduction blind hole 23C is overlapped with the eighth through hole 8C and the second through hole 2C. The drain through hole 24C is in overlapping communication with the first through hole 1C. In the valve plate overlapping state, the water flow is as follows: the water entering the water inlet port 31 flows into the third through hole 3C of the fixed valve piece 10 from the water inlet passage 21C of the movable valve piece 20, and flows through the first interface 78 of the second filter element The upper collecting umbrella 81 flows into the outer side of the filter element 84, is softened by the resin, flows into the lower collecting umbrella 83, flows into the second interface 79 of the second filter element through the inner side 85 of the filter element, and flows to the fourth through hole 4C, and the water flows through one way. The effluent conducts the diversion of the blind hole 22C, flows to the ninth through hole 9, and then flows to the water outlet 32 for water supply, and the other water flows through the outlet of the outlet water through the blind hole 22C, flows to the sixth through hole 6C, and flows through The jet outlet 34 is jetted through the jet 37 to generate a negative pressure at the suction port 36 of the jet 37, and the brine in the salt tank 51 is sucked through the salt valve 52 and the hose 50, and the mixed brine of soft water and brine flows to The jet inlet 35 flows to the eighth through hole 8C, flows through the conduction through the blind hole 23C to the second through hole 2C, flows through the second interface 39 of the first filter element, and then flows through the inner side of the filter element 45, through the lower set The umbrella 43 flows to the filter element 44 from the lower portion of the resin layer After flowing, the mixed brine countercurrently regenerates the resin, flows through the upper collecting umbrella 41, flows to the first interface 38 of the first filter element, flows to the first through hole 1C, flows to the sewage through hole 24C, and then passes through the first on the valve stem 61. A row of dirty through holes 63 and a second drain through hole 64 in the cover 60 are drained through the drain opening 33. During this process, the fifth through hole 5C and the seventh through hole 7C are passively closed to cover the waterless flow.

The second filter element softens and the salt tank hydration function: as shown in Fig. 18, by rotating the valve stem 61, the water inlet passage 21C on the movable valve piece 20 and the third through hole 3C on the fixed valve plate 10 are overlapped and connected, and the water discharge guide The blind via hole 22C is in overlapping communication with the fourth through hole 4C, the ninth through hole 9 and the eighth through hole 8C, and the conductive blind hole 23 C is in overlapping communication with the first through hole 1C and the second through hole 2C, and the dirty through hole 24C The fixed valve piece 10 is closed and covered. In the state in which the valve sheets are overlapped, the second filter element 84 is in a softened water supply state, while at the same time The tank is subjected to soft water hydration, and at this time, the No. 1 filter element 44 has no water flow.

No. 2 filter softening, No. 1 filter backwash function: As shown in FIG. 19, by rotating the valve stem 61, the water inlet passage 21C on the movable valve piece 20 and the third through hole 3C on the fixed valve piece 10 are overlapped and connected. The water outlet blind hole 22C is in overlapping communication with the fourth through hole 4C, the ninth through hole 9 and the second through hole 2C, and the conduction blind hole 23C is only overlapped with the first through hole 1C, and the sewage through hole 24C and the first through hole The holes 1C are overlapped and connected. In the state in which the valve sheets are overlapped, the second filter element 84 is in a softened water supply state, and the first filter element 44 is in a backwash state.

The second filter element is softened, and the first filter element is flushing function: as shown in FIG. 20, the water inlet passage 21C on the movable valve piece 20 and the third through hole 3C on the fixed valve plate 10 are overlapped and communicated by rotating the valve stem 61. The water outlet blind hole 22C is in overlapping communication with the fourth through hole 4C, the ninth through hole 9, and the first through hole 1C, and the conduction blind hole 23C is only overlapped with the first through hole 1C, and the sewage through hole 24C and the second through hole The holes 2C are overlapped and connected. In the state in which the valve sheets are overlapped, the No. 2 filter element 84 is in a softened water supply state, and the No. 1 filter element 44 is in a flushing state.

No. 2 filter softening function: As shown in FIG. 21, by rotating the valve stem 61, the water inlet passage 21C on the movable valve piece 20 and the third through hole 3C on the fixed valve plate 10 are overlapped and communicated, and the water outlet conduction blind hole 22C The fourth through hole 4C and the ninth through hole 9 are in overlapping communication, and the through hole 23C is in overlapping communication with the first through hole 1C and the second through hole 2C, and the drain through hole 24C is closed by the fixed valve piece 10. In the state in which the valve sheets are overlapped, the second filter element 84 is in a softened water supply state, and at this time, the first filter element 44 has no water flow.

Continuous water supply function when switching the filter element: As shown in Figs. 15, 17, the valve stem 61 is rotated, so that the movable valve piece 20 is switched from Fig. 15 to the process of Fig. 17, and the water inlet passage 21C and the water outlet of the movable valve piece 20 are turned on. The blind hole 22C is connected to the first through hole 1C and the second through hole 2C, respectively, and is switched to the water inlet channel 21C and only the first through hole 1C, and the water outlet blind hole 22C and the second through hole 2C. The fourth through hole 4C is connected to each other, and then switched to the water inlet passage 21C and the first through hole 1C and the third through hole 3C, and the water outlet blind hole 22C, the second through hole 2C, and the fourth through hole 4C. When connected, the last switch to the water inlet passage 21C and the outlet water passage blind hole 22C are respectively connected to the third through hole 3C and the fourth through hole 4C, respectively, so that the water supply from the first filter element 44 is switched to the second filter element 84. Continuous water supply when water is supplied. Similarly, as shown in Fig. 21 and Fig. 7, this embodiment also realizes the continuous water supply function when the water supply from the second filter element 84 is switched to the water supply of the first filter element 44.

Embodiment 2: Regenerate the soft water valve downstream.

As shown in Fig. 22-25 and Fig. 28, the fixed and movable valve plate combinations shown in Fig. 22 and Fig. 23 are used. 24 and 25 are a bottom view and a cross-sectional view, respectively, of the movable valve piece 20. The utility model relates to a continuous water supply multi-function control, which comprises a valve body 30, a jet 37, a cover 60, a fixed valve piece 10 and a movable valve piece 20 which are placed in the valve body 30 and which are rotated and sealed by an end surface, a movable valve piece 20 and a valve. The rods 61 are connected, and the control valve is provided with a water inlet 31, a water outlet 32, a jet outlet 34, a jet inlet 35, a salt suction port 36, a first filter element first interface 38, a first filter element second interface 39, two No. filter first interface 78, second filter second interface 79, the jet 37 communicates with the valve body 30 through the jet outlet 34 and the jet inlet 35. The jet 37 is provided with a salt suction port 36 on the cover 60. The sewage outlet 33 is provided; the fixed valve piece 10 and the movable valve piece 20 are provided with three rings, the three rings are the inner ring, the middle ring and the outer ring, and the plurality of through holes on the fixed valve piece 10 and the movable valve piece 20 are distributed in three The fixed valve plate 10 is provided with: a first through hole 1B, a second through hole 2B, a third through hole 3B, a fourth through hole 4B, a fifth through hole 5B, a sixth through hole 6B, and a seventh The through hole 7B and the eighth through hole 8B communicate with the first port 38 of the first filter element through the internal flow path of the control valve. The second through hole 2B is in communication with the second interface 39 of the first filter element, the third through hole 3B is in communication with the first interface 78 of the second filter element, and the fourth through hole 4B is connected with the second interface 79 of the second filter element. The through hole 5B and the sixth through hole 6B communicate with each other and communicate with the jet outlet 34, and the seventh through hole 7B and the eighth through hole 8B communicate with each other and communicate with the jet inlet 35, and the center of the fixed valve plate 10 is also disposed. There is a ninth through hole 9, the ninth through hole 9 is in communication with the water outlet 32, the first through hole 1B and the third through hole 3B are disposed on the outer ring and the middle ring of the fixed valve piece 10, and the second through hole 2B and the The four through holes 4B are disposed on the middle ring and the inner ring of the fixed valve piece 10, and the fifth through hole 5B, the sixth through hole 6B, the seventh through hole 7B and the eighth through hole 8B are disposed on the center ring of the fixed valve plate 10; The movable valve piece 20 is provided with a water inlet passage 21B, a water outlet blind hole 22B, a conduction blind hole 23B and a sewage through hole 24B. The water inlet passage 21B is disposed on the outer ring of the movable valve piece 20, and the water outlet is blind. 22B is disposed on the center, the inner ring and the middle ring of the movable valve piece 20, and the conduction blind hole 23B and the sewage through hole 24B are disposed on the middle ring of the movable valve piece 20, as shown in FIG. 24-25. The water conduction blind hole 22B includes a back cover, a side wall extending upward along the back cover, and a beam 25B between the side walls. The beam 25B is disposed at the top of the side wall, and the function of the beam 25B is to isolate the water conduction blind hole 22B. The passage of the middle ring and the inner ring of the fixed valve piece 10 are such that there is no water passing between them. Through the internal flow passage of the control valve, the water inlet passage 21B communicates with the water inlet 31, and the outlet water passage blind hole 22B passes through the fixed valve piece 10 The nine-way hole 9 communicates with the water outlet 32, and the drain hole 24B is sequentially communicated to the drain port 33 on the cover 60 through the first drain hole 63 of the valve stem 61 and the second drain hole 64 of the cover 60.

The difference between the second embodiment and the first embodiment is that the first embodiment is a countercurrent regeneration of salt absorption, and the embodiment The second is to promote the downstream regeneration of the salt. Therefore, the function of the No. 1 filter softening and the salt-passing regeneration No. 2 filter element of the second embodiment will be described in detail here. Other functions are only briefly described.

No. 1 filter softening function: As shown in FIG. 26, by rotating the valve stem 61, the water inlet passage 21B on the movable valve piece 20 and the first through hole 1B on the fixed valve piece 10 are overlapped and communicated, and the water outlet is blind through the blind hole 22B. The second through hole 2B and the ninth through hole 9 are in overlapping communication, and the conduction blind hole 23B is in overlapping communication with the fourth through hole 4B and the fifth through hole 5B, and the sewage through hole 24B and the seventh through hole 7B are in overlapping communication. In the state in which the valve sheets are overlapped, the No. 1 filter element 44 is in a softened water supply state, and at this time, the No. 2 filter element 84 has no water flow.

No. 1 filter softening, No. 2 filter backwash function: As shown in FIG. 27, by rotating the valve stem 61, the water inlet passage 21B on the movable valve piece 20 and the first through hole 1B on the fixed valve piece 10 are overlapped and connected. The outlet conduction blind hole 22B is in overlapping communication with the second through hole 2B, the ninth through hole 9 and the fourth through hole 4B, and the conduction blind hole 23B is in overlapping communication with the fifth through hole 5B and the seventh through hole 7B, and the discharge through hole 24B is in overlapping communication with the third through hole 3B. In the state in which the valve sheets are overlapped, the No. 1 filter element 44 is in a softened water supply state, and the No. 2 filter element 84 is in a backwash state.

The No. 1 filter softens and absorbs the salt downstream to regenerate the No. 2 filter function: As shown in Figure 28-29, by rotating the valve stem 61, the first passage on the water inlet passage 21B and the fixed valve plate 10 on the movable valve plate 20 The hole 1B is overlapped and communicated, and the outlet conduction blind hole 22B is in overlapping communication with the second through hole 2B, the ninth through hole 9 and the fifth through hole 5B, and the conduction blind hole 23B overlaps with the seventh through hole 7B and the third through hole 3B. In communication, the drain through hole 24B is in overlapping communication with the fourth through hole 4B. In the valve plate overlapping state, the water flow is as follows: the water entering the water inlet port 31 flows into the first through hole IB of the fixed valve piece 10 from the water inlet passage 21B of the movable valve piece 20, because the first through hole 1B and the first one are The first interface 38 of the filter element is in communication, so the water flows through the first interface 38 of the first filter element, passes through the upper collecting umbrella 41, flows into the outer side of the filter element 44, is softened by the resin, flows into the lower collecting umbrella 43, and flows into the lower collecting umbrella 43 through the inner side of the filter element 45. The second filter port No. 1 of the first filter element 39, because the second interface 39 of the first filter element communicates with the second through hole 2B, the water flows to the second through hole 2B because the outlet water passes through the blind hole 22B and the second through hole 2B, The nine through holes 9 and the fifth through holes 5B are in overlapping communication, so that one water flow passes through the diversion of the outlet water through the blind holes 22B and flows to the ninth through holes 9, because the ninth through holes 9 communicate with the water outlet 32, so the water flow The water flows to the water outlet 32, and the other water flows through the outlet of the water outlet blind hole 22B to the fifth through hole 5B. Since the fifth through hole 5B communicates with the jet outlet 34, the water flows through the jet outlet. 34, jetted through the jet 37, produced at the salt suction port 36 of the jet 37 A negative pressure, the mixed salt brine in the brine tank 51 through valves 52 and salt intake hose 50, soft water and brine flows ejector inlet 35, since the ejector inlet 35 and the seventh through hole 7B communicating, the The flow of water flows to the seventh through hole 7B, and the flow of the conduction through the blind hole 23B flows to the third through hole 3B. Since the third through hole 3B communicates with the first interface 78 of the second filter element, the water flows through the second number. The first interface 78 of the filter element then flows through the upper collecting umbrella 81 and flows into the filter element 84. The mixed brine flows downstream of the filter element 84 to regenerate the resin, then flows through the lower collecting umbrella 83, and flows through the inner side of the filter element 85 to the second interface of the second filter element. 79, because the second interface 79 of the second filter element communicates with the fourth through hole 4B, the water flows to the fourth through hole 4B. Since the sewage through hole 24B and the fourth through hole 4B are in overlapping communication, the water flows to the sewage through hole. 24B, and then through the first sewage through hole 63 on the valve stem 61 and the second sewage through hole 64 in the cover 60, and then drained through the sewage outlet 33. In this process, the sixth through hole 6B and the eighth through hole 8B are passively closed to cover the waterless flow.

No. 1 filter softening, salt tank hydration function: As shown in FIG. 30, by rotating the valve stem 61, the water inlet passage 21B on the movable valve piece 20 and the first through hole 1B on the fixed valve plate 10 are overlapped and connected, and the water discharge guide The blind via hole 22B is in overlapping communication with the second through hole 2B, the ninth through hole 9 and the seventh through hole 7B, and the conductive blind hole 23B is in overlapping communication with the third through hole 3B and the fourth through hole 4B, and the dirty through hole 24B is The fourth through holes 4B are overlapped and connected. In the state in which the valve sheets are overlapped, the No. 1 filter element 44 is in a softened water supply state, and at the same time, the salt tank is replenished with water. At this time, the No. 2 filter element 84 has no water flow.

The first filter element is softened and the second filter element is flushing function: as shown in FIG. 31, the water inlet passage 21B on the movable valve piece 20 and the first through hole 1B on the fixed valve plate 10 are overlapped and communicated by rotating the valve stem 61. The water outlet blind hole 22B is in overlapping communication with the second through hole 2B, the ninth through hole 9 and the third through hole 3B, and the conduction blind hole 23B is only overlapped with the fourth through hole 4B, and the sewage through hole 24B and the fourth through hole The holes 4B are overlapped and connected. In the state in which the valve sheets are overlapped, the No. 1 filter element 44 is in a softened water supply state, and the No. 2 filter element 84 is in a flushing state.

The above five functions are to illustrate the five stations for flushing and regenerating the No. 2 filter element while the No. 1 filter is softened. Since the design of the fixed valve piece 10 as shown in FIG. 22 is rotationally symmetrical, as shown in FIG. The left half of the fixed valve plate 10 corresponds to the No. 1 filter element 44, and the right half of the fixed valve plate 10 corresponds to the No. 2 filter element 84, so the five functions of the No. 2 filter element softening and flushing and regenerating the No. 1 filter element are similar to the above five functions. , so I won't go into details here.

No. 2 filter softening function: as shown in Figure 32.

No. 2 filter softening, No. 1 filter backwash function: as shown in Figure 33.

The No. 2 filter element softens and absorbs the salt downstream to regenerate the No. 1 filter function: as shown in Figure 34.

The second filter element softens and the salt tank hydration function: as shown in Figure 35. The No. 2 filter is softened and the No. 1 filter is flushing: as shown in Figure 36.

Continuous water supply function when switching the filter element: As shown in Figs. 31 and 32, the valve stem 61 is rotated to switch the movable valve piece 20 from Fig. 31 to Fig. 32, and the water inlet passage 21B of the movable valve piece 20 and the water outlet are turned on. The blind hole 22B is connected to the first through hole 1B and the second through hole 2B, respectively, and is switched to the water inlet channel 21B and the first through hole 1B and the third through hole 3B while the water outlet conduction blind hole 22B is The second through hole 2B and the fourth through hole 4B are connected to each other, and finally switched to the water inlet channel 21B and the water outlet conduction blind hole 22B are respectively connected to the third through hole 3B and the fourth through hole 4B, respectively, thereby realizing The No. 1 filter element 44 switches the water supply to the continuous water supply function when the No. 2 filter element 84 is supplied with water. Similarly, as shown in Fig. 36 and Fig. 26, this embodiment also realizes the continuous water supply function when switching from the water supply of the second filter element 84 to the water supply of the first filter element 44.

Example 3: Filter valve.

As shown in Figs. 37-41, the fixed and movable valve plate combinations shown in Figs. 37-38 are used, and Figs. 39 and 40 are a bottom view and a cross-sectional view, respectively, of the movable valve plate 20. The utility model relates to a continuous water supply multi-function control valve, which comprises a valve body 30, a cover 60, a fixed valve piece 10 and a movable valve piece 20 which are arranged in the valve body 30 and which are rotated and sealed by an end surface, and the movable valve piece 20 and the valve stem 61 are connected. The control valve is provided with a water inlet 31, a water outlet 32, a first filter element No. 1 of the first filter element 38, a second interface 39 of the first filter element, a first interface 78 of the second filter element, a second interface 79 of the second filter element, and a cover 60 There is a sewage outlet 33; the fixed valve piece 10 and the movable valve piece 20 are provided with three rings, three rings are an inner ring, a middle ring and an outer ring, and a plurality of through holes on the fixed valve piece 10 and the movable valve piece 20 are distributed in three On the ring; the fixed valve plate 10 is provided with: a first through hole 1A, a second through hole 2A, a third through hole 3A and a fourth through hole 4A, through the internal flow path of the control valve, the first through hole 1A and a The first interface 38 of the filter element is in communication, the second through hole 2A is in communication with the second interface 39 of the first filter element, the third through hole 3A is in communication with the first interface 78 of the second filter element, and the fourth through hole 4A and the second filter element The second interface 79 is in communication, and the center of the fixed valve plate 10 is further provided with a ninth through hole 9, and the ninth through hole 9 is connected with the water outlet 32, the first pass 1A and the third through hole 3A are disposed on the outer ring and the inner ring of the fixed valve piece 10, and the second through hole 2A and the fourth through hole 4A are disposed on the middle ring and the inner ring of the fixed valve piece 10; There are a water inlet passage 21A, a water outlet conduction blind hole 22A and a sewage discharge through hole 24A. The water inlet passage 21A is disposed on the outer ring of the movable valve piece 20, and the outlet water conduction blind hole 22A is disposed at the center and the inner ring of the movable valve piece 20. And on the middle ring, the sewage through hole 24A is disposed on the middle ring of the movable valve piece 20. As shown in FIG. 39-40, the water outlet blind hole 22A includes a back cover, a side wall extending upward along the back cover, and a sidewall between the side walls. The beam 25A, the beam 25A is disposed at the top of the side wall, and the function of the beam 25A is to isolate the passage of the water conducting blind hole 22A. The passage of the middle ring and the inner ring of the fixed valve plate 10 are such that there is no water passing between them. Through the internal flow passage of the control valve, the water inlet passage 21A communicates with the water inlet 31, and the outlet water passage blind hole 22A passes through the fixed valve piece 10 The nine-way hole 9 communicates with the water outlet 32, and the drain hole 24A is sequentially communicated to the drain port 33 on the cover 60 through the first drain hole 63 of the valve stem 61 and the second drain hole 64 of the cover 60.

The third embodiment is a filter valve, so the difference from the first embodiment and the second embodiment is that: in the third embodiment, there is no through hole in the jet and the fixed valve piece 10 associated with the jet, and there is no guide on the movable valve plate 20. Through blind holes. It can be said that the third embodiment is a simplified design of the first or second embodiment. Since the description is similar, only the individual functional bits will be briefly described herein.

No. 1 filter filter function: As shown in Fig. 41-42, by rotating the valve stem 61, the water inlet passage 21A on the movable valve plate 20 and the first through hole 1A on the fixed valve plate 10 are overlapped and connected, and the water outlet is blind. The hole 22A is in overlapping communication with the second through hole 2A and the ninth through hole 9, and the drain through hole 24A and the fourth through hole 4A are in overlapping communication. In the state in which the valve sheets are overlapped, the No. 1 filter element 44 is in a filtered water supply state, and at this time, the No. 2 filter element 84 has no water flow.

No. 1 filter filtration, No. 2 filter backwash function: As shown in FIG. 43-44, the water inlet passage 21A on the movable valve piece 20 and the first through hole 1A on the fixed valve plate 10 are overlapped by rotating the valve stem 61. The venting through hole 22A is in overlapping communication with the second through hole 2A, the ninth through hole 9 and the fourth through hole 4A, and the sump through hole 24A is in overlapping communication with the third through hole 3A. In the state in which the valve sheets are overlapped, the first filter element 44 is in the filtered water supply state, and the second filter element 84 is in the backwash state.

No. 1 filter filtration, No. 2 filter flushing function: As shown in Fig. 45-46, the water inlet passage 21A on the movable valve piece 20 and the first through hole 1A on the fixed valve plate 10 are overlapped by rotating the valve stem 61. The effluent conduction blind hole 22A is in overlapping communication with the second through hole 2A, the ninth through hole 9, and the third through hole 3A, and the smear through hole 24A and the fourth through hole 4A are in overlapping communication. In the state in which the valve sheets are overlapped, the No. 1 filter element 44 is in the filtered water supply state, and the No. 2 filter element 84 is in the normal flushing state.

Simultaneous filtration function of No. 1 and No. 2 filter elements: As shown in Fig. 47-48, by rotating the valve stem 61, the water inlet passage 21A on the movable valve piece 20 and the first through hole 1A and the first on the fixed valve piece 10 are simultaneously The three-way hole 3A is overlapped and communicated, and the water-passing blind hole 22A is simultaneously overlapped with the second through hole 2A, the fourth through hole 4A, and the ninth through hole 9, and the drain through hole 24A is closed by the fixed valve piece 10. In the state in which the valve plates are overlapped, the No. 1 and No. 2 filter elements are simultaneously in a filtered water supply state. This also explains the function of continuous water supply when switching the filter element.

The above four functions are to illustrate the first filter element as the primary filter element and the second filter element as the secondary filter element. 4 stations, since the design of the fixed valve plate 10 shown in Fig. 37 is rotationally symmetrical, as shown in Fig. 41, the left half of the fixed valve plate 10 corresponds to the first filter element 44, and the right half of the fixed valve plate 10 The part corresponds to the No. 2 filter element 84. Therefore, the four functional descriptions when the No. 2 filter element 84 is the main filter element and the No. 1 filter element 44 is the sub-filter element are similar to the above four functional descriptions, and are not described herein again.

Filter No. 2 filter function: as shown in Figure 49.

No. 2 filter filtration, No. 1 filter backwash function: as shown in Figure 50.

No. 2 filter filter, No. 1 filter is flushing function: as shown in Figure 51.

Simultaneous filtration function of No. 2 and No. 1 filter elements: as shown in Figure 52.

Embodiment 4: The drain outlet is on the valve body and is not on the cover.

As shown in FIG. 53, the valve body 30 is provided with a sewage outlet 33B, and the sewage through hole on the movable valve piece 20 sequentially passes through the first sewage through hole 63 on the valve stem 61 and the second sewage through hole 64 on the cover 60. It is connected to the drain port 33B on the valve body 30.

The fourth embodiment differs from the first, second and third embodiments only in that: the sewage outlets in the first, second and third embodiments are arranged on the cover, and the drainage channels are: through the sewage through holes and then through the valve stems in turn. The first discharge through hole and the second discharge through hole on the cover are connected to the drain outlet on the cover. Other instructions are similar and will not be described here.

Use two jets.

Two independent No. 1 and No. 2 jets are used. In the control valve, there is also a No. 1 jet outlet and a No. 1 jet inlet connected to the No. 1 jet, and a No. 2 jet is also provided. The second jet inlet and the second jet inlet are connected to each other, and the fifth through hole and the seventh through hole of the fixed valve piece are respectively communicated with the first jet through the first jet outlet and the first jet inlet. The No. 1 salt suction port is arranged on the No. 1 jet, and the sixth through hole and the eighth through hole of the fixed valve piece are respectively connected to the No. 2 jet through the No. 2 jet outlet and the No. 2 jet inlet, respectively. The salt port is set on the second jet. After adopting two independent No.1 jets and No.2 jets, the design of the flow passage inside the valve body is relatively simple. In the specific use, only the No. 1 salt suction port and the No. 2 suction port are used with the three-way and salt valve. In the first embodiment and the second embodiment, the fifth through hole and the sixth through hole are connected to the jet outlet through the internal flow passage of the valve body, and the seventh through hole and the eighth through hole are The jet inlets are connected, and although only one jet is used, the flow path design inside the valve body is complicated.

Control valve for floating bed.

Embodiments 1 and 2 are described by taking a fixed bed as an example, as long as the control valves in Embodiments 1 and 2 are used. The first interface of the No. 1 filter element and the second interface of the No. 1 filter element are interchanged with the two ports of the No. 1 filter element 44, and the second interface of the No. 2 filter element and the second interface of the No. 2 filter element and the No. 2 filter element 84 are interchanged. The floating bed embodiment can be obtained by swapping the connection positions of the two ports. Since the flow direction of the water in the water treatment tank is reversed, it is similar to the first embodiment and the second embodiment, and therefore will not be described herein.

The above is only a preferred embodiment of the present invention, and it should be noted that those skilled in the art can also make several improvements and retouchings without departing from the technical principles of the present invention. It should be considered as the scope of protection of the present invention. For example: adjusting the position of the water inlet passage, the outlet water conduction blind hole, the conduction blind hole and the sewage through hole on the movable valve piece, and changing the first through hole, the second through hole, the third through hole, and the fourth on the fixed valve piece The connection between the through hole and the first interface of the first filter element, the second interface of the first filter element, the first interface of the second filter element, and the second interface of the second filter element are all within the protection scope of the present invention.

Referring to Figures 54A-57 of the accompanying drawings of the present invention, a flow controller according to a fifth preferred embodiment of the present invention is illustrated, which is adapted to control multi-directional flow of water flow, wherein the flow controller includes a first control a flow element 10D and a second flow control element 20D rotatably disposed on the first flow control element 10D, wherein the first flow control element 10D includes a first flow control body 11D, and the first flow control body 11D includes a top end portion 111D, wherein the top end portion 111D forms a first flow control surface 100D; the second flow control element 20D includes a second flow control body 21D having a bottom end portion 211D and a a high-end portion 212D extending upward from the bottom end portion 211D, the bottom end portion 211D forming a second flow control surface 200D; wherein the second flow control surface 200D of the second flow control element 20D is adapted to be rotatably disposed on The first flow control surface 100D of the first flow control element 10D.

As shown in FIG. 55A to FIG. 55B of the accompanying drawings, further, as shown in FIG. 54C to FIG. 54G, the flow controller has a first passage 101D, a second passage 102D, and a third passage 103D. a fourth channel 104D, a fifth channel 105D, a sixth channel 106D, a seventh channel 107D, an eighth channel 108D, a ninth channel 109D, a tenth channel 1010D, a first H ^ - channel 1011D, A twelfth channel 1012D, a thirteenth channel 1013D, a fourteenth channel 1014D, a fifteenth channel 1015D, a sixteenth channel 1016D, a seventeenth channel 1017D, an eighteenth channel 1018D, one a nineteenth channel 1019D, a twentieth channel 1020D, a second H^-channel 1021D, a twenty-second channel 1022D, and a twenty-third channel 1023D, wherein the first channel 101D, the second channel 102D The third channel 103D, the fourth channel 104D, the fifth channel 105D, the first a six channel 106D, the seventh channel 107D, the eighth channel 108D, the ninth channel 109D, the tenth channel 1010D, the first H^-channel 1011D, the twelfth channel 1012D, the thirteenth channel 1013D, The fourteenth channel 1014D, the fifteenth channel 1015D, the sixteenth channel 1016D and the seventeenth channel 1017D are respectively disposed on the first flow control body 11D of the first flow control element 10D and are from the first control The first flow control surface 100D of the first flow control body 11D of the flow element 10D extends downward; the eighteenth passage 1018D is disposed at the bottom end portion 211D of the second flow control body 21D and from the second control flow body 21D The second flow control surface 200D of the bottom end portion 211D extends upwardly and outwardly and forms a conduction opening 10181D that is always in communication with the external space; the nineteenth channel 1019D, the twentieth channel 1020D, the second The H ^ - channel 1021D, the 22nd channel 1022D and the 23rd channel 1023D are respectively disposed at the bottom end portion 211D of the second flow control body 21D and from the bottom end portion 211D of the second flow control body 21D. The second flow control surface 200D extends upward, wherein the nineteenth channel 1019D and the second H^- Outer track are disposed in the twenty-1021D 1020D passage and are connected to the twentieth passage through 1020D. In other words, the conductive opening 10181D of the eighteenth channel 1018D can maintain the eighteenth channel 1018D always in communication with the external space, particularly the external space of the flow control. Preferably, the nineteenth channel 1019D, the twentieth channel 1020D, the second H^-channel 1021D, and the second twelve channel 1022D of the flow controller are respectively from the second of the second flow control element 20D The flow control surface 200D extends upward to the high end portion 212D of the second flow control element 21D; the second thirteenth passage 1023D extends upward from the second flow control surface 200D of the second flow control element 20D and penetrates the second control flow a second flow control body 21D of the component 20D, wherein the nineteenth channel 1019D is in communication with the twentieth channel 1020D; the second H^-channel 1021D is from the second flow control surface 200D of the second flow control component 20D Extending upwardly and inwardly to communicate with the twentieth channel 1020D.

As shown in FIG. 56A to FIG. 56J of the accompanying drawings, the second flow control element 20D is rotatable relative to the first flow control element 10D such that the flow control device has a first working position, a second working position, and a third a working position, a fourth working position, a fifth working position, a sixth working position, a seventh working position, an eighth working position, a ninth working position, and a tenth working position, wherein the control flow When the device is in the first working position, the eighteenth channel 1018D of the flow controller is in communication with the first channel 101D, and the nineteenth channel 1019D is in communication with the fourth channel 104D, the twentieth channel 1020D and the ninth channel 109D is in communication, the second H^-channel 1021D is in communication with the sixteenth channel 1016D, and the twenty-second channel 1022D is respectively associated with the seventeenth channel 1017D and the fourteenth channel 1014D is connected, the 23rd channel 1023D is in communication with the H^-channel 1011D; when the current controller is in the second working position, the 18th channel 1018D of the current controller is connected to the first channel 101D The 19th channel 1019D is in communication with the fourth channel 104D, the twentieth channel 1020D is in communication with the ninth channel 109D, and the second H^ channel 1021D is in communication with the seventeenth channel 1017D; When the flow controller is in the third working position, the eighteenth channel 1018D of the flow controller is in communication with the first channel 101D, and the nineteenth channel 1019D is in communication with the fourth channel 104D, the twentieth channel 1020D and the The nine-channel 109D is in communication, the second H^-channel 1021D is in communication with the fourteenth channel 1014D, and the twenty-third channel 1023D is in communication with the twelfth channel 1012D; when the current controller is in the fourth work In the position, the eighteenth channel 1018D of the flow controller is in communication with the first channel 101D, the nineteenth channel 1019D is in communication with the fourth channel 104D, and the twentieth channel 1020D is in communication with the ninth channel 109D. The second H ^ - channel 1021D is connected to the H ^ - channel 1011D The twenty-third channel 1023D is in communication with the fifteenth channel 1015D; when the current controller is in the fifth working position, the eighteenth channel 1018D of the flow controller is in communication with the first channel 101D, the first The nineteen channel 1019D is in communication with the fourth channel 104D, and the twentieth channel 1020D is in communication with the ninth channel 109D; when the current controller is in the sixth working position, the eighteenth channel 1018D of the flow controller is The tenth channel 1010D is in communication, the nineteenth channel 1019D is in communication with the thirteenth channel 1013D, the twentieth channel 1020D is in communication with the ninth channel 109D, and the second eleven channel 1021D is in communication with the seventh channel 107D The second channel 1022D is in communication with the fifth channel 105D and the eighth channel 108D, and the second thirteen channel 1023D is in communication with the second channel 102D; when the current controller is in the seventh working position The eighteenth channel 1018D of the flow controller is in communication with the tenth channel 1010D, the nineteenth channel 1019D is in communication with the thirteenth channel 1013D, and the twentieth channel 1020D is in communication with the ninth channel 109D. a second H ^ - channel 1021D and the eighth channel 108D When the flow controller is in the eighth working position, the eighteenth channel 1018D of the flow controller is in communication with the tenth channel 1010D, and the nineteenth channel 1019D is in communication with the thirteenth channel 1013D, the second The ten channel 1020D is in communication with the ninth channel 109D, the second H^ channel 1021D is in communication with the fifth channel 105D, and the second thirteen channel 1023D is in communication with the third channel 103D; when the current controller is in In the ninth working position, the eighteenth channel 1018D of the flow controller is in communication with the tenth channel 1010D, and the nineteenth channel 1019D is in communication with the thirteenth channel 1013D, the twentieth channel 1020D and the ninth channel 109D Connected, the second H ^ channel 1021D is in communication with the second channel 102D, the second thirteen channel 1023D and the first The six-channel 106D is in phase communication; when the flow controller is in the tenth working position, the eighteenth channel 1018D of the flow controller is in communication with the tenth channel 1010D, and the nineteenth channel 1019D is connected to the thirteenth channel 1013D. The twentieth channel 1020D is in communication with the ninth channel 109D. Preferably, when the flow controller is in the second working position, the second twelve channels 1022D are respectively connected to the first H ^ - channel 1011D and the fourteenth channel 1014D; when the current controller is in the third work When the bit is in position, the 22nd channel 1022D is in communication with the H^-channel 1011D; when the current controller is in the fourth working position, the 22nd channel 1022D is in communication with the twelfth channel 1012D; When the flow controller is in the fifth working position, the twenty-second channel 1022D is respectively connected to the twelfth channel 1012D and the fifteenth channel 1015D; when the current controller is in the seventh working position, the The second channel 1022D is in communication with the second channel 102D and the fifth channel 105D; when the current controller is in the eighth working position, the second channel 1022D is in communication with the second channel 102D; When the flow controller is in the ninth working position, the second twelve channel 1022D is in communication with the third channel 103D; when the current controller is in the tenth working position, the second twelve channel 1022D is respectively associated with the The third channel 103D is in communication with the sixth channel 106D. More preferably, when the current controller is in the first working position, the second channel 102D, the third channel 103D, the fifth channel 105D, the sixth channel 106D, the seventh channel 107D, the eighth channel 108D, the tenth channel 1010D, the twelfth channel 1012D, the thirteenth channel 1013D and the fifteenth channel 1015D are respectively blocked by the second flow control body 21D of the second flow control element 20D of the flow controller; When the current controller is in the second working position, the second channel 102D, the third channel 103D, the fifth channel 105D, the sixth channel 106D, the seventh channel 107D, the eighth channel 108D, the first The ten channel 1010D, the twelfth channel 1012D, the thirteenth channel 1013D, the fifteenth channel 1015D and the sixteenth channel 1016D are respectively controlled by the second flow control element of the second flow control element 20D of the current controller 21D blocking, the twenty-third channel 1023D is blocked by the first flow control body 11D of the first flow control element 10D of the flow controller; when the flow controller is in the third working position, the second channel 102D, the a third channel 103D, the fifth channel 105D, the sixth channel 106D, the first Seven channels 107D, the eighth channel 108D, the tenth channel 1010D, the thirteenth channel 1013D, the fifteenth channel 1015D, the sixteenth channel 1016D, and the seventeenth channel 1017D are respectively controlled by the current regulator The second flow control body 21D of the second flow control element 20D is blocked; when the flow controller is in the fourth working position, the second channel 102D, the third channel 103D, the fifth channel 105D, the sixth channel 106D The seventh channel 107D, the eighth channel 108D, the tenth channel 1010D, the thirteenth channel 1013D, the fourteenth channel 1014D, the sixteenth channel 1016D and the seventeenth channel 1017D are respectively blocked by the second flow control body 21D of the second flow control element 20D of the flow controller; when the flow controller is in the fifth working position, the a second channel 102D, the third channel 103D, the fifth channel 105D, the sixth channel 106D, the seventh channel 107D, the eighth channel 108D, the tenth channel 1010D, the first H^-channel 1011D, the The thirteenth channel 1013D, the fourteenth channel 1014D, the sixteenth channel 1016D and the seventeenth channel 1017D are respectively blocked by the second flow control body 21D of the second flow control element 20D of the flow controller, the first The second H^-channel 1021D and the twenty-third channel 1023D are respectively blocked by the first flow control body 11D of the first flow control element 10D of the flow controller; when the flow controller is in the sixth working position, the first a channel 101D, the third channel 103D, the fourth channel 104D, the sixth channel 106D, the H^-channel 1011D, the twelfth channel 1012D, the fourteenth channel 1014D, the fifteenth channel 1015D The sixteenth channel 1016D and the seventeenth channel 1017D are respectively replaced by the current regulator The second flow control body 21D of the second flow control element 20D is blocked; when the flow controller is in the seventh working position, the first channel 101D, the third channel 103D, the fourth channel 104D, the sixth channel 106D, The seventh channel 107D, the H-th channel 1011D, the twelfth channel 1012D, the fourteenth channel 1014D, the fifteenth channel 1015D, the sixteenth channel 1016D, and the seventeenth channel 1017D are respectively The second flow control body 21D of the second flow control element 20D of the flow controller is blocked, and the second thirteenth channel 1023D is blocked by the first flow control body 11D of the first flow control element 10D of the flow control device; When the flow controller is in the eighth working position, the first channel 101D, the fourth channel 104D, the sixth channel 106D, the seventh channel 107D, the eighth channel 108D, the first H^-channel 1011D, the first The twelve channel 1012D, the fourteenth channel 1014D, the fifteenth channel 1015D, the sixteenth channel 1016D and the seventeenth channel 1017D are respectively controlled by the second flow control element 20D of the current control device The body 21D is blocked; when the current controller is in the ninth working position, the first channel 101D The fourth channel 104D, the fifth channel 105D, the seventh channel 107D, the eighth channel 108D, the H^-channel 1011D, the twelfth channel 1012D, the fourteenth channel 1014D, the fifteenth The channel 1015D, the sixteenth channel 1016D and the seventeenth channel 1017D are respectively blocked by the second flow control body 21D of the second flow control element 20D of the flow controller; when the flow controller is in the tenth working position, The first channel 101D, the second channel 102D, the fourth channel 104D, the fifth channel 105D, the seventh channel 107D, the eighth channel 108D, the H^-channel 1011D, and the twelfth channel 1012D The fourteenth channel 1014D, the fifteenth channel 1015D, the sixteenth channel 1016D and the seventeenth channel 1017D are respectively controlled by the second flow control element 20D of the current controller The second flow control body 21D is blocked, and the second H^-channel 1021D and the second thirteenth channel 1023D are blocked by the first flow control body 11D of the first flow control element 10D of the flow controller.

As shown in FIG. 55A to FIG. 55B, the first channel 101D of the flow controller according to the fifth preferred embodiment of the present invention is respectively associated with the fourth channel 104D, the fifth channel 105D, and the sixth channel 106D. The seventh channel 107D, the eighth channel 108D, the ninth channel 109D, the tenth channel 1010D, the H^-channel 1011D, the twelfth channel 1012D, the thirteenth channel 1013D, the tenth The fourth channel 1014D, the fifteenth channel 1015D, the sixteenth channel 1016D and the seventeenth channel 1017D are spaced apart from each other in the first flow control body 11D of the first flow control element 10D; the second channel 102D And the fourth channel 104D, the fifth channel 105D, the sixth channel 106D, the seventh channel 107D, the eighth channel 108D, the ninth channel 109D, the tenth channel 1010D, the H-channel 1011D, the twelfth channel 1012D, the thirteenth channel 1013D, the fourteenth channel 1014D, the fifteenth channel 1015D, the sixteenth channel 1016D and the seventeenth channel 1017D are spaced apart from each other a first flow control body 11D of the first flow control element 10D; the third channel 103D and the Four channels 104D, the fifth channel 105D, the sixth channel 106D, the seventh channel 107D, the eighth channel 108D, the ninth channel 109D, the tenth channel 1010D, the H^-channel 1011D, the first The twelve channel 1012D, the thirteenth channel 1013D, the fourteenth channel 1014D, the fifteenth channel 1015D, the sixteenth channel 1016D and the seventeenth channel 1017D are spaced apart from each other at the first control flow a first flow control body 11D of the component 10D; the fourth channel 104D and the seventh channel 107D, the eighth channel 108D, the ninth channel 109D, the tenth channel 1010D, the first H^-channel 1011D, The twelfth channel 1012D, the thirteenth channel 1013D, the fourteenth channel 1014D, the fifteenth channel 1015D, the sixteenth channel 1016D and the seventeenth channel 1017D are spaced apart from the first control a first flow control body 11D of the flow element 10D; the fifth channel 105D and the seventh channel 107D, the eighth channel 108D, the ninth channel 109D, the tenth channel 1010D, the first H^-channel 1011D, The twelfth channel 1012D, the thirteenth channel 1013D, the fourteenth pass 1014D, the fifteenth channel 1015D, the sixteenth channel 1016D and the seventeenth channel 1017D are spaced apart from each other at the first flow control body 11D of the first flow control element 10D; the sixth channel 106D is respectively The seventh channel 107D, the eighth channel 108D, the ninth channel 109D, the tenth channel 1010D, the H^-channel 1011D, the twelfth channel 1012D, the thirteenth channel 1013D, the fourteenth Channel 1014D, the fifteenth channel 1015D, the sixteenth channel 1016D, and the seventeenth channel 1017D phase Separatingly disposed in the first flow control body 11D of the first flow control element 10D; the seventh passage 107D and the eighth passage 108D, the ninth passage 109D, the tenth passage 1010D, the first H ^ The channel 1011D, the twelfth channel 1012D, the thirteenth channel 1013D, the fourteenth channel 1014D, the fifteenth channel 1015D and the seventeenth channel 1017D are spaced apart from the first current-control element 10D. The first flow control body 11D; the sixteenth channel 1016D and the eighth channel 108D, the ninth channel 109D, the tenth channel 1010D, the first H^-channel 1011D, the twelfth channel 1012D, a thirteenth channel 1013D, the fourteenth channel 1014D, the fifteenth channel 1015D and the seventeenth channel 1017D are spaced apart from each other on the first flow control body 11D of the first flow control element 10D; Channel 108D and the ninth channel 109D, the tenth channel 1010D, the H-th channel 1011D, the twelfth channel 1012D, the thirteenth channel 1013D, the fourteenth channel 1014D, and the fifteenth channel 1015D is spaced apart from the first flow control body 11D of the first flow control element 10D; Channel 1017D and the ninth channel 109D, the tenth channel 1010D, the H-th channel 1011D, the twelfth channel 1012D, the thirteenth channel 1013D, the fourteenth channel 1014D, and the fifteenth channel 1015D is spaced apart from the first flow control body 11D of the first flow control element 10D; the ninth channel 109D and the tenth channel 1010D, the H^-channel 1011D, the twelfth channel 1012D, The thirteenth channel 1013D, the fourteenth channel 1014D and the fifteenth channel 1015D are spaced apart from each other in the first flow control body 11D of the first flow control element 10D; the tenth channel 1010D and the first The thirteenth channel 1013D, the fourteenth channel 1014D and the fifteenth channel 1015D are spaced apart from each other at the first flow control body 11D of the first flow control element 10D; the first H ^ - channel 1011D and the first The thirteenth channel 1013D, the fourteenth channel 1014D and the fifteenth channel 1015D are spaced apart from each other in the first flow control body 11D of the first flow control element 10D; the twelfth channel 1012D and the tenth The three channels 1013D, the fourteenth channel 1014D and the fifteenth channel 1015D are spaced apart from each other at the first a first flow control body 11D of the flow control element 10D; the eighteenth channel 1018D and the nineteenth channel 1019D, the twentieth channel 1020D, the second H^-channel 1021D, and the second twelve channel 1022D, respectively The second control flow body 21D of the second flow control element 20D is spaced apart from the twenty-third channel 1023D; the second and second channels 1022D and the nineteenth channel 1019D and the twentieth channel respectively 1020D and the second eleventh channel 1021D are spaced apart from the second flow control body 21D of the second flow control element 20D; the second thirteenth channel 1023D and the nineteenth channel 1019D, the twentieth The second control of the second flow control element 20D is spaced apart from the second eleven channel 1021D by the channel 1020D The flow body 21D is disposed at a second control flow body 21D of the second flow control element 20D spaced apart from the second thirteenth channel 1023D. Preferably, the second channel 102D and the third channel 103D are respectively connected to the first channel 101D; the fifth channel 105D and the sixth channel 106D are respectively connected to the fourth channel 104D; The channel 1011D and the twelfth channel 1012D are respectively in communication with the tenth channel 1010D; the fourteenth channel 1014D and the fifteenth channel 1015D are respectively associated with the thirteenth channel 1013D.

As shown in FIG. 55C to FIG. 55D, the top end portion 111D of the first flow control body 21D of the first flow control element 10D of the flow control device includes a first central portion 1111D, a first intermediate portion 1112D extending outwardly from the first central portion 1111D, a first extending portion 1113D extending outward from the first intermediate portion 1112D and a first edge portion extending outward from the first extending portion 1113D 1114D, and the bottom end portion 211D of the second flow control body 21D of the second flow control element 20D includes a second central portion 2111D and a second intermediate portion 2112D extending outward from the second central portion 2111D. a second extending portion 2113D extending outward from the second intermediate portion 2112D and a second edge portion 2114D extending outward from the second extending portion 2113D, wherein the first channel 101D and the tenth channel 1010D are respectively disposed on the second edge portion 2113D The first edge portion 1114D of the top end portion 111D; the second channel 102D, the third channel 103D, the fifth channel 105D, the sixth channel 106D, the seventh channel 107D, the eighth channel 108D, the Hth ^—Channel 1011D, the first The second channel 1012D, the fourteenth channel 1014D, the fifteenth channel 1015D, the sixteenth channel 1016D and the seventeenth channel 1017D are respectively disposed at the first extension 1113D of the top end portion 111D; the fourth channel 104D and the thirteenth channel 1013D are respectively disposed in the first intermediate portion 1112D of the top end portion 111D; the ninth channel 109D is disposed at the first central portion 1111D of the top end portion 111D; the eighteenth channel 1018D is disposed at a second edge portion 2114D of the bottom end portion 211D; the 19th channel 1019D is disposed at the second intermediate portion 2112D of the bottom end portion 211D; and the twentieth channel 1020D is disposed at the second center portion of the bottom end portion 211D 2111D; The second H^-channel 1021D, the twenty-second channel 1022D, and the twenty-third channel 1023D are respectively disposed in the second extension portion 2113D.

As shown in FIGS. 55A to 55B of the accompanying drawings, the first flow control surface 100D of the first flow control element 10D of the flow control device and the second control flow surface 200D of the second flow control element 20D are both circular, wherein The third channel 103D, the second channel 102D, the fifth channel 105D, the eighth channel 108D, the seventh channel 107D, the fifteenth channel 1015D, the twelfth channel 1012D, the H^-channel 1011D, The fourteenth channel 1014D, the seventeenth channel 1017D, the sixteenth channel 1016D and the sixth channel 106D are disposed clockwise in this order on the first flow control body 11D of the first flow control element 10D; The twenty-third channel 1023D, the twenty-second channel 1022D, and the second H^-channel 1021D are disposed clockwise in this order on the second flow control body 21D of the second flow control element 20D. Optionally, the third channel 103D, the second channel 102D, the fifth channel 105D, the eighth channel 108D, the seventh channel 107D, the fifteenth channel 1015D, the twelfth channel 1012D, and the H^- of the flow controller The channel 1011D, the fourteenth channel 1014D, the seventeenth channel 1017D, the sixteenth channel 1016D and the sixth channel 106D are arranged counterclockwise in this order on the first flow control body 11D of the first flow control element 10D; The twenty-third channel 1023D, the twenty-second channel 1022D, and the second H^-channel 1021D of the flow device are disposed counterclockwise in this order on the second flow control body 21D of the second flow control element 20D. Preferably, the first channel 101D, the second channel 102D, the third channel 103D, the fourth channel 104D, the fifth channel 105D, the sixth channel 106D, the seventh channel 107D, the eighth channel 108D The ninth channel 109D, the tenth channel 1010D, the first H^-channel 1011D, the twelfth channel 1012D, the thirteenth channel 1013D, the fourteenth channel 1014D, the fifteenth channel 1015D, the The sixteenth channel 1016D and the seventeenth channel 1017D are both radially disposed on the first flow control surface 100D of the first flow control element 10D, and the eighteenth channel 1018D, the nineteenth channel 1019D, the first The twenty-channel 1020D, the second H-channel 1021D, the twenty-second channel 1022D, and the twenty-third channel 1023D are respectively disposed radially on the second control surface of the second flow control element 20D. 55C to 55D, the first flow control surface 100D of the first flow control element 10D of the flow control device has a central portion 1000D indicated by a chain line in the figure, wherein the central portion 1000D is disposed at the a first central portion 1111D of the top end portion 111D of the first flow control body 11D of the flow control element 10D, A portion other than the central portion 1000D of the first flow control surface 100D is clockwise divided into a first portion 1001D, a second portion 1002D, a third portion 1003D, and a fourth portion 1004D, which are indicated by a chain line. A fifth portion 1005D, a sixth portion 1006D, a seventh portion 1007D, an eighth portion 1008D, a ninth portion 1009D, a tenth portion 10010D, an Hth portion 10011D, a twelfth portion 10012D a thirteenth portion 10013D, a fourteenth portion 10014D, a fifteenth portion 10015D and a sixteenth portion 10016D; the second flow control surface 200D of the second flow control element 20D of the flow control has a map a central area 2000D indicated by a middot line, wherein the central area 2000D is located at the a second central portion 2111D of the bottom end portion 211D of the second flow control body 21D of the second flow control element 20D, and a portion other than the central region 2000D of the second flow control surface 200D is equally divided into a dotted line by a clockwise A first area 2001D, a second area 2002D, a third area 2003D, a fourth area 2004D, a fifth area 2005D, a sixth area 2006D, a seventh area 2007D, an eighth area 2008D, A ninth region 2009D, a tenth region 20010D, a H-th region 20011D, a twelfth region 20022D, a thirteenth region 20013D, a fourteenth region 20014D, a fifteenth region 20015D, and a first a sixteenth region 20066D; wherein the first channel 101D is from the first portion 1001D of the first flow control surface 100D, the second portion 1002D, the third portion 1003D, the fourth portion 1004D, the fifth portion 1005D, and the The sixth portion 1006D extends downward; the second passage 102D extends downward from the fifth portion 1005D of the first control flow surface 100D; the third passage 103D is downward from the third portion 1003D of the first control flow surface 100D extend The fourth channel 104D is from the first portion 1001D of the first control flow surface 100D, the second portion 1002D, the third portion 1003D, the fourth portion 1004D, the fifth portion 1005D, the sixth portion 1006D, The seventh portion 1007D and the eighth portion 1008D extend downward; the fifth passage 105D extends downward from the sixth portion 1006D of the first control flow surface 100D; the sixth passage 106D from the first control flow surface 100D The second portion 1002D extends downward; the seventh passage 107D extends downward from the eighth portion 1008D of the first flow control surface 100D; the eighth passage 108D is downward from the seventh portion 1007D of the first control flow surface 100D Extending; the ninth channel 109D extends downward from the central portion 1000D of the first control flow surface 100D; the tenth channel 1010D is from the ninth portion 1009D of the first control flow surface 100D, the tenth portion 10010D, the The H--section 10011D, the twelfth portion 10012D, the thirteenth portion 10013D, and the fourteenth portion 10014D extend downward; the eleventh channel 1011D from the thirteenth portion of the first control surface 100D 10013D extends downward; the twelfth channel 1012D is from the first The H-th portion 10011D of the flow surface 100D extends downward; the thirteenth channel 1013D is from the ninth portion 1009D of the first control flow surface 100D, the tenth portion 10010D, the H-th portion 10011D, The twelfth portion 10012D, the thirteenth portion 10013D, the fourteenth portion 10014D, the fifteenth portion 10015D, and the sixteenth portion 10016D extend downward; the fourteenth channel 1014D from the first control surface The fourteenth portion 10014D of the 100D extends downward; the fifteenth channel 1015D extends downward from the tenth portion 10010D of the first control flow surface 100D; the sixteenth channel 1016D is from the first control flow surface 100D Sixteen sections 10016D extend downward; the seventeenth channel 1017D Extending downward from the fifteenth portion 10015D of the first control flow surface 100D; the eighteenth channel 1018D from the fifth region 2005D of the second control flow surface 200D, the sixth region 2006D, the seventh region 2007D And the eighth region 2008D extends upward; the nineteenth channel 1019D extends upward from the fifth region 2005D, the sixth region 2006D, the seventh region 2007D, and the eighth region 2008D of the second flow control surface 200D; The twentieth channel 1020D extends upward from the central region 2000D of the second control flow surface 200D; the second H^-channel 1021D extends upward from the sixteenth region 20016D of the second control flow surface 200D; The second channel 1022D extends upward from the fourteenth region 20014D and the fifteenth region 20015D of the second control flow surface 200D; the second thirteenth channel 1023D extends upward from the thirteenth region 20013D of the second control flow surface 200D .

As shown in FIG. 54B and FIG. 55C to FIG. 55D, the flow controller according to the fifth preferred embodiment of the present invention further includes a housing 30D, and the first of the first flow control element 10D of the flow controller The flow control body 11D further includes a lower end portion 112D extending downward from the top end portion 111D, wherein the outer casing 30D includes a casing body 31D, wherein the casing body 31D is from the first flow control body of the first flow control element 10D The lower end portion 112D of the 11D extends outward and upward and is enclosed as a first accommodating chamber 300D such that the outer casing body 31D is formed with an inner side wall 311D, an outer side wall 312D and an upper end opening 3001D having an opening upward, wherein The first accommodating chamber 300D is in communication with the conductive opening 10181D of the eighteenth channel 1018D, wherein the second flow control element 20D is adapted to be disposed on the first accommodating chamber 300D downwardly and disposed on the second accommodating surface 200D. The first flow control surface 100D of the first flow control element 10D.

It should be noted that the outer casing 30D has a first opening 301D, a second opening 302D, a third opening 303D, a fourth opening 304D, a fifth opening 305D, and a sixth opening 306D, wherein the first opening 301D The second opening 302D is in communication with the ninth channel 109D of the flow control device; the third opening 303D is respectively associated with the tenth channel 1010D of the flow controller, the H-th The channel 1011D is in communication with the twelfth channel 1012D; the fourth opening 304D is respectively connected to the thirteenth channel 1013D, the fourteenth channel 1014D and the fifteenth channel 1015D of the flow controller; The 305D is in communication with the seventh passage 107D of the flow control; the sixth opening 306D is in communication with the eighth passage 108D of the flow control. In other words, the ninth passage 109D extends downward from the first flow control surface 100D of the first flow control element 10D and outward from the lower end portion 112D of the first flow control body 11D of the first flow control element 10D. Extending to communicate with the second opening 302D; the tenth channel 1010D, the first H^-channel 1011D and the The twelfth channel 1012D extends downward from the first flow control surface 100D of the first flow control element 10D and extends outward from the lower end portion 112D of the first flow control body 11D of the first flow control element 10D to The third opening 303D is in communication; the thirteenth channel 1013D, the fourteenth channel 1014D and the fifteenth channel 1015D respectively extend downward from the first flow control surface 100D of the first flow control element 10D and are from the first The lower end portion 112D of the first flow control body 11D of a flow control element 10D extends outwardly to communicate with the fourth opening 304D; the seventh passage 107D is from the first flow control surface 100D of the first flow control element 10D Extending downwardly and extending outward from the lower end portion 112D of the first flow control body 11D of the first flow control element 10D to communicate with the fifth opening 305D; the eighth passage 108D from the first flow control element 10D The first flow control surface 100D extends downwardly and extends outward from the lower end portion 112D of the first flow control body 11D of the first flow control element 10D to communicate with the sixth opening 306D. Preferably, the lower end portion 112D of the first flow control body 11D of the first flow control element 10D is integrally formed with the inner side wall 311D of the outer casing body 31D of the outer casing 30D. More preferably, the first opening 301D, the second opening 302D, the third opening 303D, the fourth opening 304D, the fifth opening 305D and the sixth opening 306D of the outer casing 30D are respectively disposed on the outer casing 30D. Housing body 31D. Most preferably, the H-channel 1011D and the twelfth channel 1012D of the flow controller are respectively connected to the tenth channel 1010D; wherein the tenth channel 1010D, the H-channel 1011D and the first At least one of the twelve channels 1012D extends downward from the first flow control surface 100D of the first flow control element 10D and extends outward from the low end portion 112D of the first flow control body 11D of the first flow control element 10D. And communicating with the third opening 303D; the fourteenth channel 1014D and the fifteenth channel 1015D of the flow controller are respectively connected to the thirteenth channel 1013D; wherein the thirteenth channel 1013D, the first At least one of the fourteen channel 1014D and the fifteenth channel 1015D extends downward from the first flow control surface 100D of the first flow control element 10D and from the first flow control body 11D of the first flow control element 10D The lower end portion 112D extends outward to communicate with the fourth opening 303D.

Optionally, the first opening 301D is in communication with the first receiving chamber 300D, and the second opening 302D is in communication with the ninth channel 109D of the flow controller; the third opening 303D and the tenth of the flow controller The channel 1010D is in communication; the fourth opening 304D is in communication with the thirteenth channel 1013D of the flow controller; the fifth opening 305D is in communication with the seventh channel 107D of the flow controller; the sixth opening 306D and the control The eighth channel 108D of the flow device is in communication, wherein the first H^-channel 1011D and the twelfth channel 1012D are respectively connected to the tenth channel 1010D; the fourteenth channel 1014D and the fifteenth channel 1015D are respectively The thirteenth channel 1013D is in communication. That is, the tenth A channel 1011D and the twelfth channel 1012D are respectively connected to the tenth channel 1010D; the fourteenth channel 1014D and the fifteenth channel 1015D are respectively connected to the thirteenth channel 1013D; the ninth channel 109D is The first flow control surface 100D of the first flow control element 10D extends downwardly and extends outward from the lower end portion 112D of the first flow control body 11D of the first flow control element 10D to communicate with the second opening 302D. The tenth channel 1010D extends downward from the first flow control surface 100D of the first flow control element 10D and extends outward from the low end portion 112D of the first flow control body 11D of the first flow control element 10D to The third opening 303D is in communication; the thirteenth channel 1013D extends downward from the first flow control surface 100D of the first flow control element 10D and is low from the first flow control body 11D of the first flow control element 10D The end portion 112D extends outwardly to communicate with the fourth opening 304D; the seventh passage 107D extends downward from the first flow control surface 100D of the first flow control element 10D and from the first flow control element 10D A lower end portion 112D of a flow control body 11D extends outwardly to communicate with the fifth opening 305D; the eighth passage 108 D extends downward from the first flow control surface 100D of the first flow control element 10D and extends outward from the lower end portion 112D of the first flow control body 11D of the first flow control element 10D to form a sixth opening 306D Connected.

As shown in FIG. 54G to FIG. 541, the current regulator further has a first conduction channel 1025D and a second conduction channel 1026D, wherein the first conduction channel 1025D and the second conduction channel 1026D Provided in the first flow control body 11D of the first flow control element 10D; wherein the first conduction channel 1025D extends from the seventh channel 107D to the sixteenth channel 1016D and the seventh channel 107D and the first The sixteen channel 1016D is in communication; the second conductive channel 1026D extends from the eighth channel 108D to the seventeenth channel 1017D and connects the eighth channel 108D and the seventeenth channel 1017D.

As shown in FIG. 55C and FIG. 55D, the first edge portion 1114D of the top end portion 111D of the first flow control body 11D of the first flow control element 10D of the flow controller includes a first outer edge portion 11141D and a a first conductive portion 11142D extending outward from the first outer edge portion 11141D; a second edge portion 2114D of the bottom end portion 211D of the second flow control body 21D of the second flow control element 20D includes a second The outer edge portion 21141D and a first sealing portion 21142D extending outward from the second outer edge portion 21141D, wherein the first channel 101D and the tenth channel 1010D are respectively disposed on the first flow control element 10D of the flow controller The first outer edge portion 11141D of the first edge portion 1114D of the top end portion 111D of the first flow control body 11D; the eighteenth channel 1018D is disposed at the second flow control body 21D of the second flow control element 20D Second of the second edge portion 2114D of the bottom end portion 211D The outer edge portion 21141D; the first conductive channel 1025D is disposed at the first conductive portion 11142D of the first edge portion 1114D of the top end portion 111D of the first flow control body 11D of the first flow control element 10D of the flow control device and And extending to the seventh channel 107D and the sixteenth channel 1016D, respectively, to connect the seventh channel 107D and the sixteenth channel 1016D; the second conductive channel 1026D is disposed in the first control of the flow controller The first conductive portion 11142D of the first edge portion 1114D of the top end portion 111D of the first flow control body 11D of the flow element 10D extends to the eighth channel 108D and the seventeenth channel 1017D, respectively, to the eighth channel 108D is in communication with the seventeenth channel 1017D, wherein the bottom end of the second flow control body 21D of the second flow control element 20D when the second flow control element 20D is rotated relative to the first flow control element 10D The first sealing portion 21142D of the second edge portion 2114D of the portion 211D can respectively connect the first conductive channel 1025D and the second conductive channel 1026D with the first flow control body of the first flow control element 10D of the flow controller The outer space above the 11D is separated. Preferably, the first conductive channel 1025D and the second conductive channel 1026D of the current regulator, the first channel 101D, the second channel 102D, the third channel 103D, the fourth channel 104D, the a fifth channel 105D, the sixth channel 106D, the eighth channel 108D, the ninth channel 109D, the tenth channel 1010D, the H^-channel 1011D, the twelfth channel 1012D, and the thirteenth channel 1013D The fourteenth channel 1014D, the fifteenth channel 1015D and the seventeenth channel 1017D are spaced apart from each other in the first flow control body 11D of the first flow control element 10D; the second conduction channel 1026D is respectively The first channel 101D, the second channel 102D, the third channel 103D, the fourth channel 104D, the fifth channel 105D, the sixth channel 106D, the seventh channel 107D, the first Nine channel 109D, the tenth channel 1010D, the H^-channel 1011D, the twelfth channel 1012D, the thirteenth channel 1013D, the fourteenth channel 1014D, the fifteenth channel 1015D, and the sixteenth The channel 1016D is spaced apart from the first current control of the first flow control element 10D Body 11D. More preferably, the first conductive channel 1025D and the second conductive channel 1026D respectively extend downward from the first flow control surface 100D of the current regulator, so that the first conductive channel 1025D and the second conductive channel are turned on. The channel 1026D is adapted to be in communication with an upper outer space of the first flow control element 10D of the flow controller, wherein the second flow control element is disposed when the second flow control element 20D is disposed on the first flow control element 10D The first sealing portion 21142D of the second edge portion 2114D of the bottom end portion 211D of the second flow control body 21D of the 20D is adapted to respectively control the first conductive channel 1025D and the second conductive channel 1026D The outer space above the first flow control body 11D of the first flow control element 10D of the flow device is spaced apart, such that when the flow controller is in the first working position, the second working position, Flowing at the third working position, the fourth working position, the fifth working position, the sixth working position, the seventh working position, the eighth working position, the ninth working position, and the tenth working position Via the first conduction channel

The fluid of the 1025D and/or the second conduction passage 1026D does not flow upward toward the outer space of the first flow control element 10D of the flow controller.

As shown in FIG. 54G to FIG. 541, the first conductive path 1025D is disposed at the first edge of the top end portion 111D of the first flow control body 11D of the first flow control element 10D of the flow control device. The first conductive portion 11142D of the portion 1114D extends downward from the first flow control surface 100D of the first flow control element 10D, and the seventh passage 107D and the sixteenth passage 1016D of the flow control device respectively The first flow control surface 100D of the first flow control element 10D extends downwardly and outwardly and communicates with the first conductive passage 1025D, respectively, such that the first conductive passage 1025D connects the seventh passage 107D and the The sixteenth channel 1016D is in communication; the second conduction channel 1026D is disposed at the first conduction of the first edge portion 1114D of the top end portion 111D of the first flow control body 11D of the first flow control element 10D of the flow control device The portion 11142D extends downward from the first flow control surface 100D of the first flow control element 10D, and the eighth passage 108D and the seventeenth passage 1017D respectively from the first control flow surface of the first flow control element 10D 100D extends downwardly and outwardly and separately from the second conductive passage 10 The 26D is in communication such that the second conduction path 1026D connects the eighth channel 108D and the seventeenth channel 1017D.

As shown in FIG. 54F and FIG. 55E, the flow controller further includes a wear-resistant member 40D disposed between the first flow control element 10D and the second flow control element 20D, wherein the wear-resistant element 40D has a wear-resistant body 41D and a second seal portion 42D, wherein the wear-resistant body 41D has a wear-resistant surface 410D adapted to contact the second flow control surface 200D of the second flow control body 21D, wherein the wear-resistant surface The surface 410D is subjected to wear-resisting treatment, so that the friction generated by the second flow control body 21D of the second flow control element 20D relative to the first flow control body 11D of the first flow control element 10D can be reduced to extend the The service life of the flow controller, wherein when the wear element 40D is disposed between the first flow control element 10D of the flow control device and the second flow control element 20D, the second seal portion of the wear resistance element 40D The 42D can cover the first conduction channel 1025D and the second conduction channel 1026D of the flow controller, thereby the first conduction channel 1025D and the second conduction channel 1026D and the first flow control element 10 The outer space above the first flow control body 11D is spaced apart. That is, the second sealing portion 42D of the wear-resistant member 40D can separate the first conductive passage 1025D and the second conductive passage 1026D from the first accommodation chamber 300D of the outer casing 30D. In other words, when When the wear-resistant element 40D is disposed between the first flow control element 10D of the flow control device and the second flow control element 20D, the second seal portion 42D of the wear-resistant element 40D can seal the first conductive passage 1025D and The second conduction channel 1026D prevents the fluid flowing through the first conduction channel 1025D and/or the second conduction channel 1026D from flowing upwardly out of the first conduction channel 1025D and/or the second conduction channel 1026D . Further, the size and shape of the wear element 40D are designed and formed according to the first flow control surface 100D of the first flow control element 10D of the flow controller, so that when the wear element 40D is disposed on the flow control device When the first flow control element 10D and the second flow control element 20D are between, the second sealing portion 42D of the wear-resistant element 40D can seal the first conductive channel 1025D and the second conductive channel 1026D, wherein the resistance The grinding element 40D has a first interface 401D, a second interface 402D, a third interface 403D, a fourth interface 404D, a fifth interface 405D, a sixth interface 406D, a seventh interface 407D, and an eighth interface. 408D, a ninth interface 409D, a tenth interface 4010D, a H-th interface 4011D, a twelfth interface 4012D, a thirteenth interface 4013D, a fourteenth interface 4014D, a fifteenth interface 4015D, a sixteenth interface 4016D and a seventeenth interface 4017D, wherein the first interface 401D, the second interface 402D, the third interface 403D, the fourth interface 404D, the fifth interface 405D, the sixth interface 406D , The seventh interface 407D, the eighth interface 408D, the ninth interface 409D, the tenth interface 4010D, the H-th interface 4011D, the twelfth interface 4012D, the thirteenth interface 4013D, the fourteenth interface 4014D The fifteenth interface 4015D, the sixteenth interface 4016D, and the seventeenth interface 4017D extend up and down through the wear-resistant body 41D of the wear-resistant component 40D and sequentially with the first passage 101D of the flow control device, the first Two channels 102D, the third channel 103D, the fourth channel 104D, the fifth channel 105D, the sixth channel 106D, the seventh channel 107D, the eighth channel 108D, the ninth channel 109D, the tenth channel 1010D, the H^-channel 1011D, the twelfth channel 1012D, the thirteenth channel 1013D, the fourteenth channel 1014D, the fifteenth channel 1015D, the sixteenth channel 1016D, and the seventeenth channel 1017D - Correspondence. That is, the first interface 401D, the second interface 402D, the third interface 403D, the fourth interface 404D, the fifth interface 405D, the sixth interface 406D, the seventh interface 407D, the eighth interface 408D, the ninth interface 409D, the tenth interface 4010D, the H-th interface 4011D, the twelfth interface 4012D, the thirteenth interface 4013D, the fourteenth interface 4014D, the fifteenth interface 4015D, The sixteenth interface 4016D and the seventeenth interface 4017D are configured to enable the first interface 401D to communicate with the eighteenth channel of the flow controller when the current controller is in the first working position 1018D and the first channel 101D, the fourth interface 404D can communicate with the nineteenth channel 1019D and the fourth channel 104D, the ninth interface 409 can communicate with the twentieth channel 1020D and the ninth channel 109D, the sixteenth interface 4016D can communicate with the second H^-channel 1021D and the sixteenth channel 1016D, the seventeenth interface 1017D can communicate with the twenty-second channel 1022D and the seventeenth channel 1017D, and the fourteenth interface 4014D can communicate The twenty-second channel 1022D and the fourteenth channel 1014D, the first H-interface 4011D can communicate with the twenty-third channel 1023D and the eleventh channel 1011D; when the current controller is in the second working position The first interface 401D can communicate with the eighteenth channel 1018D of the current controller and the first channel 101D, and the fourth interface 404D can communicate with the nineteenth channel 1019D and the fourth channel 104D, and the ninth interface 409D can Connecting the twentieth channel 1020D and the ninth channel 109D, the seventeenth interface 4017D is capable of connecting the second H^-channel 1021D and the seventeenth channel 1017D; when the current controller is in the third working position, The first interface 401D is capable of communicating with the eighteenth of the flow controller The channel 1018D is connected to the first channel 101D, and the fourth interface 404D is capable of connecting the nineteenth channel 1019D and the fourth channel 104D. The ninth interface 409D is capable of connecting the twentieth channel 1020D and the ninth channel 109D. The interface 4014D can communicate with the second H^-channel 1021D and the fourteenth channel 1014D, the twelfth interface 4012D can communicate with the second thirteenth channel 1023D and the twelfth channel 1012D; when the current controller is in the In the four working positions, the first interface 401D can communicate with the eighteenth channel 1018D of the current controller and the first channel 101D, and the fourth interface 404D can communicate with the nineteenth channel 1019D and the fourth channel 104D, the ninth The interface 409D can communicate with the twentieth channel 1020D and the ninth channel 109D, and the H-th interface 4011D can communicate with the second H^-channel 1021D and the H-th channel 1011D, and the fifteenth interface 4015D can communicate with The twenty-third channel 1023D and the fifteenth channel 1015D; when the current controller is in the fifth working position, the first interface 401D can communicate with the eighteenth channel 1018D of the current controller and the first channel 101D, The fourth interface 404D is capable of connecting the nineteenth channel 1019D And the fourth channel 104D, the ninth interface 409D can communicate with the twentieth channel 1020D and the ninth channel 109D; when the current controller is in the sixth working position, the tenth interface 4010D can communicate with the flow controller The eighteenth channel 1018D and the tenth channel 1010D, the thirteenth interface 4013D can communicate with the nineteenth channel 1019D and the thirteenth channel 1013D, the ninth interface 409D can communicate with the twentieth channel 1020D and the ninth channel 109D, The seventh interface 407D can communicate with the second H^-channel 1021D and the seventh channel 107D, and the fifth interface 405D can communicate with the second twelve-channel 1022D and the fifth channel 105D, and the eighth interface 408D can communicate with The twentieth The second channel 1022D and the eighth channel 108D, the second interface 402D can communicate with the second thirteenth channel 1023D and the second channel 102D; when the current controller is in the seventh working position, the tenth interface 4010D can communicate The eighteenth channel 1018D and the tenth channel 1010D of the flow control device, the thirteenth interface 4013D can communicate with the nineteenth channel 1019D and the thirteenth channel 1013D, and the ninth interface 409D can communicate with the twentieth channel 1020D And the ninth channel 109D, the eighth interface 408D can communicate with the second H^-channel 1021D to communicate with the eighth channel 108D; when the current controller is in the eighth working position, the tenth interface 4010D can communicate with the The eighteenth channel 1018D and the tenth channel 1010D of the flow control device, the thirteenth interface 4013D can communicate with the nineteenth channel 1019D and the thirteenth channel 1013D, and the ninth interface 409D can communicate with the twentieth channel 1020D and The ninth channel 109D, the fifth interface 405D is capable of connecting the second H^-channel 1021D and the fifth channel 105D, the third interface 403D is capable of connecting the second thirteen channel 1023D and the third channel 103D; When the flow controller is in the ninth working position, The tenth interface 4010D is capable of communicating with the eighteenth channel 1018D and the tenth channel 1010D of the flow controller, and the thirteenth interface 4013D is capable of connecting the nineteenth channel 1019D with the thirteenth channel 1013D, the ninth interface 409D being capable of communicating The twentieth channel 1020D and the ninth channel 109D, the second interface 402D can communicate with the second H^-channel 1021D and the second channel 102D, the sixth interface 406D can communicate with the second thirteen channel 1023D and the first a six-channel 106D; when the flow controller is in the tenth working position, the tenth interface 4010D is capable of communicating with the eighteenth channel 1018D and the tenth channel 1010D of the flow controller, and the thirteenth interface 4013D is capable of connecting the tenth The nine-channel 1019D and the thirteenth channel 1013D, the ninth interface 409D can communicate with the twentieth channel 1020D and the ninth channel 109D. Preferably, when the current controller is in the second working position, the H-th interface 4011D can communicate with the second twelve-channel 1022D and the first H-channel 1011D, and the fourteenth interface 4014D can communicate with the first The twenty-two channel 1022D and the fourteenth channel 1014D; when the current controller is in the third working position, the eleventh interface 4011D can communicate with the second twelve channel 1022D and the first H ^ - channel 1011D; When the current controller is in the fourth working position, the twelfth interface 4012D can communicate with the twelfth channel 1022D and the twelfth channel 1012D; when the current controller is in the fifth working position, the twelfth The interface 4012D can communicate with the twenty-second channel 1022D and the twelfth channel 1012D, the fifteenth interface 4015D can communicate with the twenty-second channel 1022D and the fifteenth channel 1015D; when the current controller is at the seventh In the working position, the second interface 402D can communicate with the second and second channels 1022D and 102D, and the fifth interface 405D can communicate with the second and second channels 1022D and 5 When the controller is in the eighth working position, the second interface 402D can communicate with the second twelve channel 1022D and the second channel 102D; when the current controller is in the ninth working position, the third The interface 403D can communicate with the second channel 1022D and the third channel 103D. When the controller is in the tenth working position, the third interface 403D can communicate with the second channel 1022D and the third channel 103D. The sixth interface 406D can communicate with the second channel 1022D and the sixth channel 106D. Preferably, when the wear-resistant element 40D is disposed between the first flow control element 10D and the second flow control element 20D of the flow control device, the wear-resistant element 40D does not occur relative to the first flow control element 10D. The rotation of the first flow control body 11D. More preferably, the wear element 40D has a wear resistant surface 410D that has been smoothed to reduce its roughness. Most preferably, the wear element 40D is integrally formed with the first flow control body 21D of the first flow control element 20D.

It is noted that since the wear-resistant member 40D is provided with a second sealing portion 42D adapted to seal the first conductive passage 1025D and the second conductive passage 1026D, the second control of the second flow control member 20D The flow body 21D may no longer be provided with the first sealing portion 21142D.

Another embodiment of the flow control device according to the fifth preferred embodiment of the present invention is shown in FIG. 54K and FIG. 54L, wherein the outer casing 30D of the present invention further has a seventh opening 307D and An eighth opening 308D, wherein the sixteenth channel 1016D extends downward from the first flow control surface 100D of the first flow control element 10D and from the lower end of the first flow control body 11D of the first flow control element 10D The portion 112D extends outwardly to communicate with the seventh opening 307D, and the seventeenth passage 1017D extends downward from the first flow control surface 100D of the first flow control element 10D and from the first flow control element 10D The lower end portion 112D of the first flow control body 11D extends outward to communicate with the eighth opening 308D.

It can be understood that when the outer casing 30D of the present invention further has a seventh opening 307D communicating with the sixteenth passage 1016D of the flow controller and a seventeenth passage 1017D communicating with the flow controller The eighth opening 308D, the flow controller may no longer be provided with a first conductive passage 1025D connecting the seventh passage 107D of the flow controller and the sixteenth passage 1016D, and the flow control device may no longer be provided. A second conduction channel 1026D is connected to the eighth channel 108D of the flow controller and the seventeenth channel 1017D. In addition, since the first conductive channel 1025D and the second conductive channel 1026D are no longer provided in the current regulator, the bottom end portion 211D of the second flow control body 21D of the second flow control element 20D is The first sealing portion 21142D is no longer disposed in the two edge portions 2114D. Correspondingly, the aforementioned wear-resistant member 40D is no longer provided with the second sealing portion 42D. As shown in FIG. 54B of the accompanying drawings, the flow controller further includes a flow guiding element 50D, wherein the flow guiding element 50D includes a guiding body 51D, wherein the guiding body 51D is surrounded by a first guiding channel 510D. The guide body 51D of the flow guiding element 50D extends upward from the second flow control body 21D of the second flow control element 20D, and the first flow guiding channel 510D of the flow guiding element 50D and the first flow guiding device Twenty-three channels 1023D are connected.

As shown in Figure 54B of the drawings, the flow controller further includes a drive member 60D extending upward from the second flow control body 21D of the second flow control member 20D and a sealing member 70D extending upward from the drive member 60D. The driving element 60D is adapted to drive the second flow control body 21D of the second flow control element 20D of the flow controller to rotate relative to the first flow control body 11D of the first flow control element 10D; wherein the sealing element 70D It is adapted to be disposed in the outer casing 30D and to seal the first accommodation chamber 300D, thereby preventing fluid in the first accommodation chamber 300D from flowing out from the upper end opening 3001D of the first accommodation chamber 300D. Preferably, the sealing element 70D is in contact with the drive element 60D and is adapted to hold the drive element 60D in position to maintain the second flow control body 21D of the second flow control element 20D in place. Preferably, the drive element 60D of the flow control device is integrally formed with the flow guiding body 51D of the flow guiding element 50D.

As shown in FIG. 54J of the accompanying drawings, the flow controller according to the fifth preferred embodiment of the present invention further includes a flow blocking member 80D extending downward from the first flow control body 11D of the first flow control element 10D, and The outer casing body 31D of the outer casing 30D extends outward and downward from the lower end portion 112D of the first flow control body 11D of the first flow control element 10D, wherein the flow blocking member 80D and the outer casing body 31D form a partition a first flow guiding chamber 801D between the flow element 80D and the housing body 31D, and the flow blocking element 80D form a second flow guiding chamber 802D, wherein the first channel 101D, the second channel 102D and the first channel of the flow controller The three channels 103D extend downward from the first flow control surface 100D of the first flow control element 10D and are respectively connected to the first flow guiding chamber 801D; the fourth channel 104D, the fifth channel 105D and the third of the flow controller The six channels 106D extend downward from the first flow control surface 100D of the first flow control element 10D and are respectively in communication with the second flow guiding chamber 802D. Preferably, the second channel 102D and the third channel 103D of the flow controller are respectively connected to the first channel 101D, wherein at least one of the first channel 101D, the second channel 102D and the third channel 103D a first control flow surface 100D extending from the first flow control element 10D and communicating with the first flow guiding chamber 801D; the fifth channel 105D and the sixth channel 106D of the flow controller respectively The fourth channel 104D is in communication, wherein the fourth channel 104D, the fifth channel 105D, and the sixth channel 106D are One less extends from the first flow control surface 100D of the first flow control element 10D and communicates with the second flow guiding chamber 802D.

Referring to Figure 57 of the accompanying drawings, the present invention further provides a water treatment system, wherein the water treatment system includes a flow controller of the present invention and a water treatment unit 90D, wherein the water treatment unit 90D is disposed at the flow controller. And the water flow can flow between the water treatment unit 90D and the flow controller under the control and guidance of the flow control unit, wherein the water treatment unit 90D includes a first water treatment element 91D and a second water treatment element 92D. And a first fluidizer 93D, wherein the first water treatment element 91D has a first communication opening 911D and a second communication opening 912D, the second water treatment element 92D having a third communication opening 921D and a fourth communication Opening 922D, the first fluidizer 93D has a fifth communication opening 931D and a sixth communication opening 932D, wherein the first communication opening 911D of the first water treatment element 91D and the first flow guiding chamber of the flow control device 801D is in communication; the second communication opening 912D of the first water treatment component 91D is in communication with the second flow guiding chamber 802D of the flow control; the third communication opening 921D of the second water treatment component 92D and the control The third opening 303D of the flow device is in communication; the fourth communication opening 922D of the second water treatment element 92D is in communication with the fourth opening 304D of the flow controller; the fifth communication opening 931D of the first fluidizer 93D The fifth opening 305D of the flow controller is in communication with the sixth opening 932D of the first jet 93D and the sixth opening 306D of the flow controller. That is, the first opening 301D of the outer casing 30D of the flow controller of the water treatment system is in communication with an external water source, the third opening 303D, the fourth opening 304D, and the fifth opening 305D of the outer casing 30D. The sixth opening 306D is in communication with the water treatment unit 90D, respectively. Further, the first water treatment element 91D has a first water treatment portion 913D in which water to be treated flows from the first communication opening 911D of the first water treatment element 91D and from the first water treatment element 91D. When the second communication opening 912D flows out, or flows from the second communication opening 912D of the first water treatment element 91D and flows out from the first communication opening 911D of the first water treatment element 91D, the water to be treated is first The first water treatment portion 913D of the water treatment element 91D processes and obtains the treated water. Similarly, the second water treatment element 92D has a second water treatment portion 923D in which water to be treated flows from the third communication opening 921D of the second water treatment element 92D and from the second water treatment element 92D. The fourth communication opening 922D flows out, or flows from the fourth communication opening 922D of the second water treatment element 92D and flows out from the third communication opening 921D of the second water treatment element 92D, the water to be treated is The second water treatment portion 923D of the water treatment member 92D processes and obtains the treated water. It is to be noted that the first water treatment portion 913D of the first water treatment element 91D of the water treatment unit 90D and the second water treatment portion 923D of the second water treatment element 92D are each made of at least one water treatment material. If it is made of one or more of quartz sand, activated carbon, resin, stereoelastic filler, honeycomb filler or filter, the treated water is treated to remove impurities in the water to be treated or components not desired by the user.

As shown in Fig. 57 of the accompanying drawings, the water treatment unit 90D of the water treatment system according to the fifth preferred embodiment of the present invention further includes a liquid distribution tank 94D, wherein when the first fluidizer 93D is injecting water into the control When the sixth opening 306D of the outer casing 30D of the flow device, the regeneration solution in the liquid distribution tank 94D is sucked into the sixth opening 306D of the outer casing 30D of the flow controller, and the regeneration solution is respectively controlled and guided by the flow controller Flowing the second water treatment element 92D or the first water treatment element 91D of the water treatment unit to make the second water treatment portion 923D of the second water treatment element 92D or the first water of the first water treatment element 91D The processing unit 913D is reproduced.

It is noted that when the outer casing 30D of the flow control system of the water treatment system further has the seventh opening 307D and the eighth opening 308D, the water treatment unit 90D of the water treatment system further includes a second fluidizer 95D, wherein The second jet 95D has a seventh communication opening 951D and an eighth communication opening 952D, wherein the seventh communication opening 951D of the second jet 95D and the seventh of the outer casing 30D of the flow control system of the water treatment system The opening 307D is in communication; the eighth communication opening 952D of the second jet 95D is in communication with the eighth opening 308D of the outer casing 30D of the flow control system of the water treatment system, wherein the first jet 93D is in the water When the sixth opening 306D of the outer casing 30D of the flow controller is injected, the regeneration solution in the liquid distribution tank 94D is sucked into the sixth opening 306D of the outer casing 30D of the flow controller, and the regeneration solution is in the flow controller Controlling and directing the first water treatment element 91D to the water treatment unit to regenerate the first water treatment portion 913D of the first water treatment element 91D; when the second fluidizer 95D is spraying water When entering the eighth opening 308D of the outer casing 30D of the flow control device, the regeneration solution in the liquid distribution tank 94D is sucked into the eighth opening 308D of the outer casing 30D of the flow control device, and the regeneration solution is controlled by the flow control device. And guiding the second water treatment element 92D to the water treatment unit to regenerate the second water treatment unit 923D of the second water treatment element 92D.

As shown in Figure 56A of the accompanying drawings, when the flow controller of the water treatment system is in the first working position, the water to be treated is adapted to flow into the first portion of the outer casing 30D through the first opening 301D of the outer casing 30D of the flow control device. The accommodation chamber 300D flows into the first through the conduction opening 10181D of the eighteenth passage 1018D Channel 101D, then the water to be treated flows into the first water treatment element 91D through the first flow guiding chamber 801D and the first communication opening 911D of the first water treatment element 91D of the water treatment unit 90D of the water treatment system and is provided through After the treatment of the first water treatment unit 913D in the first water treatment element 91D, the treated water is obtained, and the treated water flows into the second communication opening 912D of the first water treatment element 91D under a suitable pressure. The second flow guiding chamber 802D of the flow controller then flows into the fourth passage 104D of the flow controller, and then flows into the twentieth passage 1020D of the flow controller through the nineteenth passage 1019D of the flow controller, and then passes through The twentieth channel 1020D flows into the ninth channel 109D and the second H^-channel 1021D, respectively, wherein the processed water flowing into the ninth channel 109D flows out through the second opening 302D of the outer casing 30D of the flow controller to For the user to use, the treated water flowing into the twenty-first channel 1021D flows into the sixteenth channel 1016D of the flow controller, and then flows into the seventh channel 107D through the first conductive channel 1025D and passes through the current regulator. The fifth opening 305D of the outer casing 30D flows into the first The jet 93D, and then the treated water is mixed by the first jet 93D, and the treated water is mixed with the regeneration solution from the dispensing tank 94D and injected into the outer casing 30D of the flow control device. a sixth opening 306D, and then, the mixed solution of the treated water and the regeneration solution flows into the eighth passage 108D of the flow controller and flows through the second conductive passage 1026D to the seventeenth passage 1017D of the flow controller, and then Then flowing through the twenty-second channel 1022D of the flow controller into the fourteenth channel 1014D and the thirteenth channel 1013D of the flow controller, and then flowing to the second water through the fourth opening 304D of the outer casing 30D of the flow controller. Processing element 92D and flowing into the second water treatment element 92D through the fourth communication opening 922D of the second water treatment element 92D, so that the mixed liquid formed by the treated water and the regeneration solution can be processed for the second water The second water treatment unit 923D of the element 92D performs a regeneration process, and the waste liquid generated by the regeneration process flows into the third opening 303D of the outer casing 30D of the flow controller through the third communication opening 921D of the second water treatment element 92D, and then flows in. The tenth channel 1010D of the flow controller And the H ^ - channel 1011D, finally flowing out through the second thirteenth channel 1023D and the first flow guiding channel 510D of the flow guiding element 50D; as shown in Figure 56B of the drawing, when the water treatment system of the water treatment system When in the second working position, the water to be treated is adapted to flow into the first receiving chamber 300D of the outer casing 30D through the first opening 301D of the outer casing 30D of the flow controller and flow into the through opening 10181D of the eighteenth passage 1018D. The first passage 101D, then the water to be treated flows into the first water treatment element 91D through the first flow guiding chamber 801D and the first communication opening 911D of the first water treatment element 91D of the water treatment unit 90D of the water treatment system After the treatment of the first water treatment unit 913D in the first water treatment element 91D, the treated water is obtained, and the treated water is at a suitable pressure. Flowing through the second communication opening 912D of the first water treatment element 91D into the second flow guiding chamber 802D of the flow controller, and then flowing into the fourth passage 104D of the flow controller, and then passing through the flow controller The nineteenth channel 1019D flows into the twentieth channel 1020D of the current controller, and then flows into the ninth channel 109D and the second H^-channel 1021D through the twentieth channel 1020D, respectively, into which the ninth channel 109D is processed. The rear water flows out through the second opening 302D of the outer casing 30D of the flow controller for the user to use, and the treated water flowing into the second eleventh channel 1021D flows into the seventeenth passage 1017D of the flow controller, and then passes through the The second conductive passage 1026D flows into the eighth passage 108D and flows into the first jet 93D through the sixth opening 306D of the outer casing 30D of the flow controller, and then flows into the liquid distribution tank 94D through the first jet 93D; As shown in Fig. 56C, when the flow controller of the water treatment system is in the third working position, the water to be treated is adapted to flow into the first accommodation chamber of the outer casing 30D through the first opening 301D of the outer casing 30D of the flow control device. 300D and flows into the through opening 10181D of the eighteenth channel 1018D The first passage 101D, then the water to be treated flows into the first water treatment element 91D through the first flow guiding chamber 801D and the first communication opening 911D of the first water treatment element 91D of the water treatment unit 90D of the water treatment system After the treatment of the first water treatment portion 913D provided in the first water treatment element 91D, the treated water is obtained, and the treated water passes through the second communication opening 912D of the first water treatment element 91D under a suitable pressure. Flowing into the second flow guiding chamber 802D of the flow controller, then flowing into the fourth passage 104D of the flow controller, and then flowing into the twentieth passage 1020D of the flow controller through the nineteenth passage 1019D of the flow controller, Then, the twentieth channel 1020D flows into the ninth channel 109D and the second H^-channel 1021D, respectively, wherein the processed water flowing into the ninth channel 109D flows out through the second opening 302D of the outer casing 30D of the flow controller. For the user to use, the treated water flowing into the second H^-channel 1021D flows into the fourteenth channel 1014D and the thirteenth channel 1013D of the flow controller, and then passes through the fourth casing 10D of the flow controller. Opening 304D flows to the second water treatment element 92D and The fourth communication opening 922D of the second water treatment element 92D flows into the second water treatment element 92D, so that the treated water can backwash the second water treatment part 923D of the second water treatment element 92D. The waste liquid generated by the backwashing process flows into the third opening 303D of the outer casing 30D of the flow controller through the third communication opening 921D of the second water treatment element 92D, and then flows into the tenth passage 1010D and the tenth of the flow controller. The second channel 1012D is finally discharged through the second thirteenth channel 1023D and the first flow guiding channel 510D of the flow guiding element 50D; as shown in FIG. 56D, when the flow control device of the water treatment system is in the fourth work In position, the water to be treated is adapted to flow into the first volume of the outer casing 30D through the first opening 301D of the outer casing 30D of the flow control device The chamber 300D flows into the first passage 101D through the conduction opening 10181D of the eighteenth passage 1018D, and then the water to be treated passes through the first flow guiding chamber 801D and the first water treatment of the water treatment unit 90D of the water treatment system. The first communication opening 911D of the element 91D flows into the first water treatment element 91D and passes through the treatment of the first water treatment unit 913D provided in the first water treatment element 91D, thereby obtaining treated water, and the treated water is suitable Under the pressure, the second communication opening 912D of the first water treatment element 91D flows into the second flow guiding chamber 802D of the flow controller, and then flows into the fourth passage 104D of the flow controller, and then passes through the flow controller. The nineteenth channel 1019D flows into the twentieth channel 1020D of the current controller, and then flows into the ninth channel 109D and the second H^-channel 1021D through the twentieth channel 1020D, respectively, into which the ninth channel 109D flows. The treated water flows out through the second opening 302D of the outer casing 30D of the flow controller for use by the user, and the treated water flowing into the second eleventh channel 1021D flows into the H ^ - channel 1011D of the flow controller and Tenth channel 1010D, and then through the flow controller The third opening 303D of the outer casing 30D flows to the second water treatment element 92D, and flows into the second water treatment element 92D through the third communication opening 921D of the second water treatment element 92D, so that the treated water can The second water treatment portion 923D of the second water treatment element 92D performs a positive flushing process, and the waste liquid generated by the positive flushing process flows into the outer casing 30D of the flow controller through the fourth communication opening 922D of the second water treatment component 92D. a four opening 304D, which then flows into the thirteenth channel 1013D and the fifteenth channel 1015D of the flow controller, and finally flows out through the second thirteenth channel 1023D and the first flow guiding channel 510D of the flow guiding element 50D; As shown in FIG. 56E, when the flow controller of the water treatment system is in the fifth working position, the water to be treated is adapted to flow into the first accommodation chamber 300D of the outer casing 30D through the first opening 301D of the outer casing 30D of the flow control device. And flowing into the first passage 101D through the conduction opening 10181D of the eighteenth passage 1018D, and then the water to be treated passes through the first flow guiding chamber 801D and the first water treatment element 91D of the water treatment unit 90D of the water treatment system. The first communication opening 911D flows in After the first water treatment element 91D is processed by the first water treatment unit 913D provided in the first water treatment element 91D, the treated water is obtained, and the treated water is treated by the first water under a suitable pressure. The second communication opening 912D of the element 91D flows into the second flow guiding chamber 802D of the flow controller, then flows into the fourth passage 104D of the flow controller, and then flows into the control flow through the nineteenth passage 1019D of the flow controller. The twentieth channel 1020D of the device flows into the ninth channel 109D through the twentieth channel 1020D, and finally flows out through the second opening 302D of the outer casing 30D of the flow controller for use by the user; 56F, when the flow control device of the water treatment system is in the sixth working position, the water to be treated is adapted to pass through the outer casing 30D of the flow control device. An opening 301D flows into the first accommodating chamber 300D of the outer casing 30D and flows into the tenth passage 1010D through the conductive opening 10181D of the eighteenth passage 1018D, and then the water to be treated passes through the third opening 303D of the outer casing 30D and the water treatment The third communication opening 921D of the second water treatment element 92D of the water treatment unit 90D of the system flows into the second water treatment element 92D and passes through the treatment of the second water treatment unit 923D provided in the second water treatment element 92D. The treated water is obtained, and the treated water flows into the fourth opening 304D of the outer casing 30D through the fourth communication opening 922D of the second water treatment element 92D under a suitable pressure, and then flows into the thirteenth passage of the flow controller. 1013D, and then flows into the twentieth channel 1020D of the flow controller through the nineteenth channel 1019D of the flow controller, and then flows into the ninth channel 109D and the second H^-channel through the twentieth channel 1020D, respectively. 1021D, wherein the treated water flowing into the ninth channel 109D flows out through the second opening 302D of the outer casing 30D of the flow controller for use by the user, and the treated water flowing into the second H^-channel 1021D flows into the control Seventh pass of the flow device 107D, then flows into the first jet 93D through the fifth opening 305D of the outer casing 30D of the flow control, and then, the treated water is under the action of the first jet 93D, the treated water and the liquid dispensing tank The regeneration solution of 94D is mixed and injected together into the sixth opening 306D of the outer casing 30D of the flow controller, and then, the mixed solution of the treated water and the regeneration solution flows into the eighth passage 108D of the flow controller, and then The second channel 1022D passing through the flow controller flows into the fifth channel 105D and the fourth channel 104D of the flow controller, and then passes through the second flow guiding chamber 802D and the first of the water treatment unit 90D of the water treatment system. The second communication opening 912D of the water treatment element 91D flows into the first water treatment element 91D, so that the mixed liquid formed by the treated water and the regeneration solution can be performed on the first water treatment portion 913D of the first water treatment element 91D. The regeneration process, the waste liquid generated by the regeneration process flows into the first flow guiding chamber 801D through the first communication opening 911D of the first water treatment component 91D, and then flows into the first channel 101D and the second channel 102D of the flow controller, Finally through the twenty-third pass 1023D and the first flow guiding channel 510D of the flow guiding element 50D flow out; as shown in FIG. 56G of the drawing, when the flow controller of the water treatment system is in the seventh working position, the water to be treated is adapted to pass the control flow The first opening 301D of the outer casing 30D flows into the first accommodation chamber 300D of the outer casing 30D and flows into the tenth passage 1010D through the conduction opening 10181D of the eighteenth passage 1018D, and then the water to be treated passes through the third of the outer casing 30D. The opening 303D and the third communication opening 921D of the second water treatment element 92D of the water treatment unit 90D of the water treatment system flow into the second water treatment element 92D and pass through the second water treatment provided in the second water treatment element 92D. After the treatment of the portion 923D, the treated water is obtained, and the treated water passes through the second water treatment element under a suitable pressure. The fourth communication opening 922D of 92D flows into the fourth opening 304D of the outer casing 30D, then flows into the thirteenth passage 1013D of the flow controller, and then flows into the flow controller through the nineteenth passage 1019D of the flow controller. The twenty-channel 1020D is then flowed into the ninth channel 109D and the second H^-channel 1021D via the twentieth channel 1020D, respectively, wherein the treated water flowing into the ninth channel 109D passes through the outer casing 30D of the flow control device. The second opening 302D flows out for the user to use, and the treated water flowing into the second eleventh channel 1021D flows into the eighth channel 108D of the flow controller, and then flows through the sixth opening 306D of the outer casing 30D of the flow controller. The first jet 93D is then flowed into the dosing tank 94D via the first jet 93D; as shown in FIG. 56H of the drawing, when the flow control device of the water treatment system is in the eighth working position, the water to be treated is suitable The first opening 301D of the outer casing 30D passing through the flow controller flows into the first accommodating chamber 300D of the outer casing 30D and flows into the tenth passage 1010D through the conductive opening 10181D of the eighteenth passage 1018D, and then the water to be treated passes through the a third opening 303D of the outer casing 30D and the water treatment system The third communication opening 921D of the second water treatment element 92D of the water treatment unit 90D flows into the second water treatment element 92D and is processed by the second water treatment unit 923D provided in the second water treatment element 92D. After treatment, the treated water flows into the fourth opening 304D of the outer casing 30D through the fourth communication opening 922D of the second water treatment element 92D under a suitable pressure, and then flows into the thirteenth passage 1013D of the flow controller. And then flowing through the nineteenth channel 1019D of the flow controller into the twentieth channel 1020D of the flow controller, and then flowing into the ninth channel 109D and the second H^-channel 1021D through the twentieth channel 1020D, respectively. The processed water flowing into the ninth passage 109D flows out through the second opening 302D of the outer casing 30D of the flow controller for use by the user, and the treated water flowing into the second eleventh passage 1021D flows into the flow control device. The fifth passage 105D and the fourth passage 104D then flow into the first water treatment element through the second flow guiding chamber 802D and the second communication opening 912D of the first water treatment element 91D of the water treatment unit 90D of the water treatment system 91D, thus making this process The water can backwash the first water treatment portion 913D of the first water treatment element 91D, and the waste liquid generated by the backwashing treatment flows into the first flow through the first communication opening 911D of the first water treatment element 91D. The chamber 801D then flows into the first channel 101D and the third channel 103D of the flow controller, and finally flows out through the second thirteen channel 1023D and the first flow guiding channel 510D of the flow guiding element 50D; As shown, when the flow control device of the water treatment system is in the ninth working position, the water to be treated is adapted to flow into the first accommodation chamber 300D of the outer casing 30D through the first opening 301D of the outer casing 30D of the flow control device and pass through the The conductive opening 10181D of the eighteenth channel 1018D flows into the tenth channel 1010D, and then the water to be treated passes through the outer casing 30D. The third opening 303D and the third communication opening 921D of the second water treatment element 92D of the water treatment unit 90D of the water treatment system flow into the second water treatment element 92D and pass through the second water treatment element 92D. After the treatment of the second water treatment unit 923D, the treated water is obtained, and the treated water flows into the fourth opening 304D of the outer casing 30D through the fourth communication opening 922D of the second water treatment element 92D under a suitable pressure, and then flows in. The thirteenth channel 1013D of the flow controller then flows into the twentieth channel 1020D of the flow controller through the nineteenth channel 1019D of the flow controller, and then flows into the ninth channel through the twentieth channel 1020D, respectively. 109D and the second H^-channel 1021D, wherein the treated water flowing into the ninth channel 109D flows out through the second opening 302D of the outer casing 30D of the flow controller for use by the user, flowing into the second eleventh channel The treated water of 1021D flows into the second passage 102D of the flow control device and the first passage 101D, and then passes through the first flow guiding chamber 801D and the first water treatment unit 91D of the water treatment unit 90D of the water treatment system. The communication opening 911D flows into the first water The component 91D, so that the treated water can perform a positive rinsing process on the first water treatment portion 913D of the first water treatment component 91D, and the waste liquid generated by the rinsing process passes through the second portion of the first water treatment component 91D The communication opening 912D flows into the second flow guiding chamber 802D, and then flows into the fourth channel 104D and the sixth channel 106D of the flow controller, and finally passes through the second thirteenth channel 1023D and the first flow guiding channel of the flow guiding member 50D. 510D flows out; as shown in Figure 56J of the accompanying drawings, when the flow controller of the water treatment system is in the tenth working position, the water to be treated is adapted to flow into the outer casing 30D through the first opening 301D of the outer casing 30D of the flow control device. The first accommodating chamber 300D flows into the tenth passage 1010D through the conductive opening 10181D of the eighteenth passage 1018D, and then the water to be treated passes through the third opening 303D of the outer casing 30D and the water treatment unit 90D of the water treatment system. The third communication opening 921D of the second water treatment element 92D flows into the second water treatment element 92D and passes through the treatment of the second water treatment unit 923D provided in the second water treatment element 92D, thereby obtaining treated water. After the water is at the right pressure The fourth communication opening 922D of the second water treatment element 92D flows into the fourth opening 304D of the outer casing 30D, and then flows into the thirteenth passage 1013D of the flow controller, and then passes through the nineteenth passage of the flow controller. The channel 1019D flows into the twentieth channel 1020D of the flow controller, and then flows into the ninth channel 109D through the twentieth channel 1020D, and finally flows out through the second opening 302D of the outer casing 30D of the flow controller for the user to use. .

Referring to Figures 58A-61 of the accompanying drawings of the present invention, a flow controller according to a sixth preferred embodiment of the present invention is illustrated, which is adapted to control multi-directional flow of water flow, wherein the flow controller includes a first control a flow element 10E and a second flow control element 20E rotatably disposed on the first flow control element 10E, The first flow control element 10E includes a first flow control body 11E, and the first flow control body 11E includes a top end portion 111E, wherein the top end portion 111E forms a first flow control surface 100E; the second flow control element 20E includes a second flow control body 21E having a bottom end portion 211E and a high end portion 212E extending upward from the bottom end portion 211E, the bottom end portion 211E forming a second flow control surface The second flow control surface 200E of the second flow control element 20E is adapted to be rotatably disposed on the first flow control surface 100E of the first flow control element 10E.

As shown in FIG. 58C to FIG. 58G of the accompanying drawings, further, as shown in FIG. 59A to FIG. 59B of the accompanying drawings, the flow controller has a first passage 101E, a second passage 102E, and a fourth passage 104E. A fifth channel 105E, a sixth channel 106E, a seventh channel 107E, an eighth channel 108E, a ninth channel 109E, a tenth channel 1010E, a second H^-channel 1011E, and a thirteenth channel 1013E a fourteenth channel 1014E, a fifteenth channel 1015E, a sixteenth channel 1016E, a seventeenth channel 1017E, an eighteenth channel 1018E, a nineteenth channel 1019E, a twentieth channel 1020E, a second channel 1021E, a second channel 1222E, and a second channel 1023E, wherein the first channel 101E, the second channel 102E, the fourth channel 104E, the fifth channel 105E, the a sixth channel 106E, the seventh channel 107E, the eighth channel 108E, the ninth channel 109E, the tenth channel 1010E, the first H^-channel 1011E, the thirteenth channel 1013E, and the fourteenth channel 101 4E, the fifteenth channel 1015E, the sixteenth channel 1016E and the seventeenth channel 1017E are respectively disposed on the first flow control body 11E of the first flow control element 10E and from the first flow control element 10E The first flow control surface 100E of the flow control body 11E extends downward; the eighteenth channel 1018E is disposed at the bottom end portion 211E of the second flow control body 21E and from the bottom end portion 211E of the second flow control body 21E. The second flow control surface 200E extends upwardly and outwardly and forms a conduction opening 10181E that is always in communication with the external space; the nineteenth channel 1019E, the twentieth channel 1020E, and the second H^ channel 1021E The second and second channels 1022E and the second and third channels 1023E are respectively disposed at the bottom end portion 211E of the second flow control body 21E and the second control flow from the bottom end portion 211E of the second flow control body 21E. The surface of the twentieth channel 1020E and the second eleven channel 1021E are respectively disposed outside the twentieth channel 1020E and are respectively connected to the twentieth channel 1020E. In other words, the conductive opening 10181E of the eighteenth channel 1018E can maintain the eighteenth channel 1018E in constant communication with the external space, particularly the external space of the flow control. Preferably, the nineteenth channel 1019E, the twentieth channel 1020E, the twentieth of the flow controller A channel 1021E and the second channel 1022E extend upward from the second flow control surface 200E of the second flow control element 20E to a high end portion 212E of the second flow control element 21E; the second thirteen channel 1023E The second flow control surface 200E of the second flow control element 20E extends upwardly and extends through the second flow control body 21E of the second flow control element 20E, wherein the nineteenth passage 1019E is in communication with the twentieth passage 1020E; The second H^-channel 1021E extends upwardly and inwardly from the second flow control surface 200E of the second flow control element 20E to communicate with the twentieth channel 1020E.

As shown in FIG. 60A to FIG. 60J of the accompanying drawings, the second flow control element 20E is rotatable relative to the first flow control element 10E such that the flow control device has a first working position, a second working position, and a third a working position, a fourth working position, a fifth working position, a sixth working position, a seventh working position, an eighth working position, a ninth working position, and a tenth working position, wherein the control flow When the device is in the first working position, the eighteenth channel 1018E of the flow controller is in communication with the first channel 101E, and the nineteenth channel 1019E is in communication with the fourth channel 104E, the twentieth channel 1020E and the ninth channel The 109E phase is connected; when the flow controller is in the second working position, the 18th channel 1018E of the flow controller is in communication with the first channel 101E, and the 19th channel 1019E is in communication with the fourth channel 104E, the first The twenty-channel 1020E is in communication with the ninth channel 109E, the second H^-channel 1021E is in communication with the fourteenth channel 1014E, and the second thirteenth channel 1023E is in communication with the first H^-channel 1011E; When the flow controller is in the third working position, the The eighteenth channel 1018E of the flow device is in communication with the first channel 101E, the nineteenth channel 1019E is in communication with the fourth channel 104E, and the second ten channel 1020E is in communication with the ninth channel 109E, the second H^- The channel 1021E is in communication with the sixteenth channel 1016E, and the second twelve channel 1022E is in communication with the seventeenth channel 1017E and the first H^-channel 1011E, respectively. The twenty-third channel 1023E and the fifteenth The channel 1015E is in communication; when the current controller is in the fourth working position, the eighteenth channel 1018E of the flow controller is in communication with the first channel 101E, and the nineteenth channel 1019E is in communication with the fourth channel 104E. The twentieth channel 1020E is in communication with the ninth channel 109E, and the second H^-channel 1021E is in communication with the seventeenth channel 1017E; when the current controller is in the fifth working position, the tenth of the flow controller The eight-channel 1018E is in communication with the first channel 101E, the nineteenth channel 1019E is in communication with the fourth channel 104E, and the second ten channel 1020E is in communication with the ninth channel 109E, the second H^-channel 1021E and the first H ^ - channel 1011E is connected, the twenty-third channel 1023E and the The fifteenth channel 1015E is in communication; when the current controller is in the sixth working position, the eighteenth channel 1018E of the flow controller is in communication with the tenth channel 1010E, the nineteenth channel 1019E and the thirteenth channel 1013E Connected, the The twentieth channel 1020E is in communication with the ninth channel 109E; when the flow controller is in the seventh working position, the eighteenth channel 1018E of the flow controller is in communication with the tenth channel 1010E, and the nineteenth channel 1019E is The thirteenth channel 1013E is in communication, the twentieth channel 1020E is in communication with the ninth channel 109E, the second H^-channel 1021E is in communication with the fifth channel 105E, and the second thirteenth channel 1023E is connected to the second The channel 102E is in communication; when the flow controller is in the eighth working position, the eighteenth channel 1018E of the flow controller is in communication with the tenth channel 1010E, and the nineteenth channel 1019E is in communication with the thirteenth channel 1013E. The twentieth channel 1020E is in communication with the ninth channel 109E, and the second eleven channel 1021E is in communication with the seventh channel 107E. The second twelf channel 1022E is associated with the second channel 102E and the eighth channel 108E, respectively. Connected, the twenty-third channel 1023E is in communication with the sixth channel 106E; when the current controller is in the ninth working position, the eighteenth channel 1018E of the flow controller is in communication with the tenth channel 1010E, The nineteenth channel 1019E is connected to the thirteenth channel 1013E The twentieth channel 1020E is in communication with the ninth channel 109E, and the second H^-channel 1021E is in communication with the eighth channel 108E; when the current controller is in the tenth working position, the flow controller is The eighteenth channel 1018E is in communication with the tenth channel 1010E, the nineteenth channel 1019E is in communication with the thirteenth channel 1013E, and the twentieth channel 1020E is in communication with the ninth channel 109E, the second eleven channel 1021E is The second channel 102E is in communication with the second channel 1023E. The second channel 1023E is in communication with the sixth channel 106E. Preferably, when the current controller is in the first working position, the second eleven channel 1021E and the sixth channel are 106E is in communication, the twenty-second channel 1022E is in communication with the fourteenth channel 1014E and the sixteenth channel 1016E, respectively, the second thirteen channel 1023E is in communication with the seventeenth channel 1017E; When the device is in the second working position, the twenty-second channel 1022E is respectively connected to the sixteenth channel 1016E and the seventeenth channel 1017E; when the current controller is in the fourth working position, the second twelve Channel 1022E and the first H ^ - channel 1011E and the tenth The channel 1015E is in communication, and the 23rd channel 1023E is in communication with the fifteenth channel 1015E. When the current controller is in the fifth working position, the 22nd channel 1022E is connected to the fifteenth channel 1015E. When the current controller is in the sixth working position, the second H^-channel 1021E is in communication with the fifteenth channel 1015E, and the second twelve channel 1022E is respectively associated with the fifth channel 105E and the seventh channel 107E is in communication, the twenty-third channel 1023E is in communication with the eighth channel 108E; when the current controller is in the seventh working position, the second twelve channel 1022E is respectively associated with the seventh channel 107E and the eighth The channel 108E is in communication; when the controller is in the ninth working position, the second channel 1022E is in communication with the second channel 102E and the sixth channel 106E, respectively, The twenty-third channel 1023E is in communication with the sixth channel 106E; when the current controller is in the tenth working position, the second twelve channel 1022E is in communication with the sixth channel 106E; more preferably, when the control When the flow device is in the first working position, the second channel 102E, the fifth channel 105E, the seventh channel 107E, the eighth channel 108E, the tenth channel 1010E, the first H^-channel 1011E, the tenth The three channels 1013E and the fifteenth channel 1015E are respectively blocked by the second flow control body 21E of the second flow control element 20E of the flow controller; when the flow controller is in the second working position, the second channel 102E, The fifth channel 105E, the sixth channel 106E, the seventh channel 107E, the eighth channel 108E, the tenth channel 1010E, the thirteenth channel 1013E, and the fifteenth channel 1015E are respectively controlled by the current regulator The second flow control body 21E of the second flow control element 20E is blocked; when the flow controller is in the third working position, the second channel 102E, the fifth channel 105E, the sixth channel 106E, and the seventh channel 107E The eighth channel 108E, the tenth channel 1010E, the thirteenth channel 1013E and the fourteenth channel 1014E are respectively blocked by the second flow control body 21E of the second flow control element 20E of the flow controller; when the flow controller is in the fourth working position, the second channel 102E, the first The five channels 105E, the sixth channel 106E, the seventh channel 107E, the eighth channel 108E, the tenth channel 1010E, the thirteenth channel 1013E, the fourteenth channel 1014E, and the sixteenth channel 1016E are respectively The second flow control body 21E of the second flow control element 20E of the flow controller is blocked; when the flow controller is in the fifth working position, the second channel 102E, the fifth channel 105E, the sixth channel 106E, The seventh channel 107E, the eighth channel 108E, the tenth channel 1010E, the thirteenth channel 1013E, the fourteenth channel 1014E, the sixteenth channel 1016E, and the seventeenth channel 1017E are respectively controlled by the flow The second flow control body 21E of the second flow control element 20E of the device is blocked; when the flow controller is in the sixth working position, the first channel 101E, the second channel 102E, the fourth channel 104E, the sixth Channel 106E, the H^-channel 1011E, the fourteenth channel 1014E, The sixteenth channel 1016E and the seventeenth channel 1017E are respectively blocked by the second flow control body 21E of the second flow control element 20E of the flow controller; when the flow controller is in the seventh working position, the first Channel 101E, the fourth channel 104E, the sixth channel 106E, the H^-channel 1011E, the fourteenth channel 1014E, the fifteenth channel 1015E, the sixteenth channel 1016E, and the seventeenth channel 1017E Blocked by the second flow control body 21E of the second flow control element 20E of the flow controller; when the flow controller is in the eighth working position, the first channel 101E, the fourth channel 104E, the fifth channel 105E, the H ^ - channel 1011E, the fourteenth channel 1014E, the fifteenth channel 1015E, the sixteenth channel 1016E and the seventeenth channel 1017E are respectively controlled by the second flow control element 20E of the current controller Second flow control ontology 21E blocking; when the current controller is in the ninth working position, the first channel 101E, the fourth channel 104E, the fifth channel 105E, the seventh channel 107E, the first H^-channel 1011E, the tenth The four-channel 1014E, the fifteenth channel 1015E, the sixteenth channel 1016E, and the seventeenth channel 1017E are respectively blocked by the second flow control body 21E of the second flow control element 20E of the flow controller; When the device is in the tenth working position, the first channel 101E, the fourth channel 104E, the fifth channel 105E, the seventh channel 107E, the eighth channel 108E, the first H^-channel 1011E, the fourteenth The channel 1014E, the fifteenth channel 1015E, the sixteenth channel 1016E, and the seventeenth channel 1017E are respectively blocked by the second flow control body 21E of the second flow control element 20E of the flow controller.

As shown in FIG. 59A to FIG. 59B, the first channel 101E of the flow controller according to the sixth preferred embodiment of the present invention is respectively associated with the fourth channel 104E, the fifth channel 105E, and the sixth channel 106E. The seventh channel 107E, the eighth channel 108E, the ninth channel 109E, the tenth channel 1010E, the H^-channel 1011E, the thirteenth channel 1013E, the fourteenth channel 1014E, the tenth The fifth channel 1015E, the sixteenth channel 1016E and the seventeenth channel 1017E are spaced apart from each other at the first flow control body 11E of the first flow control element 10E; the second channel 102E and the fourth channel 104E are respectively The fifth channel 105E, the sixth channel 106E, the seventh channel 107E, the eighth channel 108E, the ninth channel 109E, the tenth channel 1010E, the first H^-channel 1011E, the thirteenth channel 1013E, the fourteenth channel 1014E, the fifteenth channel 1015E, the sixteenth channel 1016E and the seventeenth channel 1017E are spaced apart from each other in the first flow control element 10E of the first flow control body 11E; The fourth channel 104E and the seventh channel 107E, the eighth channel 108E, and the ninth channel 109E, respectively The tenth channel 1010E, the H^-channel 1011E, the thirteenth channel 1013E, the fourteenth channel 1014E, the fifteenth channel 1015E, the sixteenth channel 1016E and the seventeenth channel 1017E are separated The first flow control body 11E is disposed at the first flow control element 10E; the fifth channel 105E is respectively associated with the seventh channel 107E, the eighth channel 108E, the ninth channel 109E, the tenth channel 1010E, The first H ^ - channel 1011E, the thirteenth channel 1013E, the fourteenth channel 1014E, the fifteenth channel 1015E, the sixteenth channel 1016E and the seventeenth channel 1017E are spaced apart from the first a first flow control body 11E of the flow control element 10E; the sixth channel 106E and the seventh channel 107E, the eighth channel 108E, the ninth channel 109E, the tenth channel 1010E, and the H-channel 1011E The thirteenth channel 1013E, the fourteenth channel 1014E, the fifteenth channel 1015E, the sixteenth channel 1016E, and the seventeenth channel 1017E are spaced apart from each other of the first flow control element 10E. a flow control body 11E; the seventh channel 107E and the eighth channel 108E, the ninth channel 109E, the tenth channel 1010E, the H-th channel 1011E, the thirteenth channel 1013E, the fourteenth channel 1014E, the fifteenth channel 1015E, and The seventeenth channel 1017E is spaced apart from the first flow control body 11E of the first flow control element 10E; the sixteenth channel 1016E is respectively associated with the eighth channel 108E, the ninth channel 109E, and the tenth The channel 1010E, the H-channel 1011E, the thirteenth channel 1013E, the fourteenth channel 1014E, the fifteenth channel 1015E and the seventeenth channel 1017E are spaced apart from each other. The first flow control body 11E of the 10E; the eighth channel 108E and the ninth channel 109E, the tenth channel 1010E, the H^-channel 1011E, the thirteenth channel 1013E, the fourteenth channel 1014E, and The fifteenth channel 1015E is spaced apart from the first flow control body 11E of the first flow control element 10E; the seventeenth channel 1017E and the ninth channel 109E, the tenth channel 1010E, the Hth ^—channel 1011E, the thirteenth channel 1013E, the fourteenth channel 1014E, and the fifteenth channel 1015E is spaced apart from the first flow control body 11E of the first flow control element 10E; the ninth channel 109E and the tenth channel 1010E, the H^-channel 1011E, the thirteenth channel 1013E, The fourteenth channel 1014E and the fifteenth channel 1015E are spaced apart from each other in the first flow control body 11E of the first flow control element 10E; the tenth channel 1010E and the thirteenth channel 1013E, respectively The fourteen channels 1014E and the fifteenth channel 1015E are spaced apart from the first flow control body 11E of the first flow control element 10E; the eleventh channel 1011E and the thirteenth channel 1013E, the tenth The four-channel 1014E and the fifteenth channel 1015E are spaced apart from each other in the first flow control body 11E of the first flow control element 10E; the eighteenth channel 1018E and the nineteenth channel 1019E, the twentieth The channel 1020E, the second H^-channel 1021E, the second twelve channel 1022E, and the second thirteen channel 1023E are spaced apart from each other and disposed on the second flow control body 21E of the second flow control element 20E; The twenty-two channels 1022E are respectively associated with the nineteenth channel 1019E, the twentieth channel 1020E, and the second eleven channel 1021E Separatingly disposed in the second flow control body 21E of the second flow control element 20E; the second thirteenth channel 1023E and the nineteenth channel 1019E, the twentieth channel 1020E and the second H ^ channel 1021E is spaced apart from the second flow control body 21E of the second flow control element 20E; the second and second channels 1022E are spaced apart from the second thirteenth channel 1023E by the second flow control element 20E. The second flow control body 21E. Preferably, the second channel 102E is in communication with the first channel 101E; the fifth channel 105E and the sixth channel 106E are respectively connected to the fourth channel 104E; the first H^-channel 1011E and the tenth channel 1010E is connected to each other; the fourteenth channel 1014E and the fifteenth channel 1015E are respectively associated with the thirteenth Channel 1013E is in communication.

As shown in FIG. 59C to FIG. 59D, the top end portion 111E of the first flow control body 21E of the first flow control element 10E of the flow control device includes a first central portion 1111E. a first intermediate portion 1112E extending outwardly from the first central portion 1111E, a first extending portion 1113E extending outward from the first intermediate portion 1112E, and a first edge portion extending outward from the first extending portion 1113E 1114E, and the bottom end portion 211E of the second flow control body 21E of the second flow control element 20E includes a second central portion 2111E and a second intermediate portion 2112E extending outward from the second central portion 2111E. a second extending portion 2113E extending outward from the second intermediate portion 2112E and a second edge portion 2114E extending outward from the second extending portion 2113E, wherein the first channel 101E and the tenth channel 1010E are respectively disposed at the second edge portion 2113E The first edge portion 1114E of the top end portion 111E; the second channel 102E, the fifth channel 105E, the sixth channel 106E, the seventh channel 107E, the eighth channel 108E, the H^-channel 1011E, the Fourteenth channel 1014E, the first The fifth channel 1015E, the sixteenth channel 1016E and the seventeenth channel 1017E are respectively disposed at the first extending portion 1113E of the top end portion 111E; the fourth channel 104E and the thirteenth channel 1013E are respectively disposed at the top end portion The first intermediate portion 1112E of the 111E; the ninth passage 109E is disposed at the first central portion 1111E of the distal end portion 111E; the eighteenth passage 1018E is disposed at the second edge portion 2114E of the bottom end portion 211E; The 19th channel 1019E is disposed at the second intermediate portion 2112E of the bottom end portion 211E; the twentieth channel 1020E is disposed at the second center portion 2111E of the bottom end portion 211E; the second H^-channel 1021E, the second The twelve channels 1022E and the twenty-third channels 1023E are respectively disposed at the second extension portion 2113E.

As shown in FIG. 59A to FIG. 59B of the drawing, the first flow control surface 100E of the first flow control element 10E of the flow control device and the second control flow surface 200E of the second flow control element 20E are both circular, wherein The second channel 102E, the eighth channel 108E, the seventh channel 107E, the fifth channel 105E, the fifteenth channel 1015E, the H^-channel 1011E, the seventeenth channel 1017E, the sixteenth channel 1016E, The fourteenth channel 1014E and the sixth channel 106E are disposed clockwise in this order on the first flow control body 11E of the first flow control element 10E; the second thirteenth channel 1023E and the twenty-second channel of the flow control device The 1022E and the second H^-channel 1021E are disposed clockwise in this order to the second flow control body 21E of the second flow control element 20E. Optionally, the second channel 102E, the eighth channel 108E, the seventh channel 107E, the fifth channel 105E, the fifteenth channel 1015E, the H^-channel 1011E, the seventeenth channel 1017E, and the tenth of the flow controller Six-channel 1016E, fourteenth channel 1014E and sixth channel 106E In this order, the first flow control body 11E of the first flow control element 10E is provided counterclockwise; the twenty-third channel 1023E, the twenty-second channel 1022E and the second H^-channel 1021E of the flow controller are This sequence is provided counterclockwise to the second flow control body 21E of the second flow control element 20E. Preferably, the first channel 101E, the second channel 102E, the fourth channel 104E, the fifth channel 105E, the sixth channel 106E, the seventh channel 107E, the eighth channel 108E, the ninth channel 109E The tenth channel 1010E, the first H^-channel 1011E, the thirteenth channel 1013E, the fourteenth channel 1014E, the fifteenth channel 1015E, the sixteenth channel 1016E, and the seventeenth channel 1017E are both The first control flow surface 100E of the first flow control element 10E is disposed in a radial direction, and the eighteenth channel 1018E, the nineteenth channel 1019E, the twentieth channel 1020E, and the second H^ channel 1021E are disposed. The second and second channels 1022 and 1023 are respectively disposed on the second flow control surface 200E of the second flow control element 20E.

As shown in FIG. 59C to FIG. 59D, the first flow control surface 100E of the first flow control element 10E of the flow control device has a central portion 1000E indicated by a chain line in the figure, wherein the central portion 1000E is disposed at the center portion 1000E. The first central portion H UE of the top end portion 111E of the first flow control body 11E of the first flow control element 10E, and the portion other than the central portion 1000E of the first control flow surface 100E is equally divided into a dotted line by a clockwise A first portion 1001E, a second portion 1002E, a third portion 1003E, a fourth portion 1004E, a fifth portion 1005E, a sixth portion 1006E, a seventh portion 1007E, an eighth portion 1008E, a ninth portion 1009E, a tenth portion 10010E, a H-th portion 10011E, a twelfth portion 10012E, a thirteenth portion 10013E, and a fourteenth portion 10014E; the second control flow of the flow controller The second flow control surface 200E of the element 20E has a central area 2000E indicated by a chain line in the figure, wherein the central area 2000E is provided at the bottom end portion 211E of the second flow control body 21E of the second flow control element 20E. Second central portion 2111E, and the second A portion other than the central area 2000E of the flow surface 200E is clockwise divided into a first area 2001E, a second area 2002E, a third area 2003E, a fourth area 2004E, and a fifth as indicated by a chain line. A region 2005E, a sixth region 2006E, a seventh region 2007E, an eighth region 2008E, a ninth region 2009E, a tenth region 20010E, a H-th region 20011E, a twelfth region 20012E, a first a thirteenth region 20013E and a fourteenth region 20014E; wherein the first channel 101E is from the first portion 1001E of the first control flow surface 100E, the second portion 1002E, the third portion 1003E, the fourth portion 1004E, The fifth part 1005E and the sixth part 1006E are extended downward The second channel 102E extends downward from the fourth portion 1004E of the first control surface 100E; the fourth channel 104E is from the first portion 1001E of the first control surface 100E, the second portion 1002E, The third portion 1003E, the fourth portion 1004E, the fifth portion 1005E, the sixth portion 1006E, and the seventh portion 1007E extend downward; the fifth channel 105E from the seventh portion 1007E of the first control flow surface 100E Extending downward; the sixth channel 106E extends downward from the first portion 1001E, the second portion 1002E, and the third portion 1003E of the first flow control surface 100E; the seventh channel 107E is from the first control surface The sixth portion 1006E of the 100E extends downward; the eighth passage 108E extends downward from the fifth portion 1005E of the first flow control surface 100E; the ninth passage 109E extends from the central portion 1000E of the first flow control surface 100E The tenth channel 1010E is from the eighth portion 1008E of the first control flow surface 100E, the ninth portion 1009E, the tenth portion 10010E, the H-th portion 10011E, the twelfth portion 10012E, and The thirteenth portion 10013E extends downward; the H^-channel 101 1E extends downward from the H^-portion 10011E of the first control flow surface 100E; the thirteenth channel 1013E is from the eighth portion 1008E of the first control flow surface 100E, the ninth portion 1009E, the tenth The portion 10010E, the H-th portion 10011E, the twelfth portion 10012E, the thirteenth portion 10013E, and the fourteenth portion 10014E extend downward; the fourteenth channel 1014E from the first control surface 100E The fourteenth portion 10014E extends downward; the fifteenth channel 1015E extends downward from the eighth portion 1008E, the ninth portion 1009E, and the tenth portion 10010E of the first flow control surface 100E; the sixteenth channel 1016E extends downward from a thirteenth portion 10013E of the first flow control surface 100E; the seventeenth passage 1017E extends downward from a twelfth portion 10012E of the first control flow surface 100E; the eighteenth passage 1018E The fifth region 2005E, the sixth region 2006E, and the seventh region 2007E of the second flow control surface 200E extend upward; the nineteenth channel 1019E is from the fifth region 2005E of the second flow control surface 200E, The sixth region 2006E and the seventh region 2007E extend upward; the twentieth channel 1020 E extending upward from a central region 2000E of the second flow control surface 200E; the second H^-channel 1021E extending upward from the first region 2001E of the second flow control surface 200E; the second twelve channel 1022E from the first The thirteenth region 20013E and the fourteenth region 20014E of the second control flow surface 200E extend upward; the twenty-third channel 1023E extends upward from the twelfth region 20012E of the second control flow surface 200E.

As shown in FIG. 58B and FIG. 59D, the flow controller according to the sixth preferred embodiment of the present invention further includes a housing 30E, and a first flow control body of the first flow control element 10E of the flow controller. 11E Further comprising a lower end portion 112E extending downwardly from the top end portion 111E, wherein the outer casing 30E includes a casing body 31E, wherein the casing body 31E is from the lower end of the first flow control body 11E of the first flow control element 10E The portion 112E extends outwardly and upwardly and encloses a first receiving chamber 300E such that the housing body 31E is formed with an inner side wall 311E, an outer side wall 312E and an opening upward upper end opening 3001E, wherein the first receiving portion The chamber 300E is in communication with the conductive opening 10181E of the eighteenth channel 1018E, wherein the second flow control element 20E is adapted to be disposed in the first receiving chamber 300E downwardly and disposed on the first control surface 300E. The first flow control surface of the flow element 10E

It should be noted that the outer casing 30E has a first opening 301E, a second opening 302E, a third opening 303E, a fourth opening 304E, a fifth opening 305E and a sixth opening 306E, wherein the first opening 301E And communicating with the first receiving chamber 300E, the second opening 302E is in communication with the ninth passage 109E of the flow controller; the third opening 303E is respectively associated with the tenth passage 1010E of the flow controller and the first H^- The channel 1011E is in communication with each other; the fourth opening 304E is respectively connected to the thirteenth channel 1013E, the fourteenth channel 1014E and the fifteenth channel 1015E of the flow controller; the fifth opening 305E is opposite to the flow controller The seventh passage 107E is in communication; the sixth opening 306E is in communication with the eighth passage 108E of the flow controller. In other words, the ninth passage 109E extends downward from the first flow control surface 100E of the first flow control element 10E and outward from the lower end portion 112E of the first flow control body 11E of the first flow control element 10E. Extending to communicate with the second opening 302E; the tenth channel 1010E and the eleventh channel 1011E respectively extend downward from the first flow control surface 100E of the first flow control element 10E and from the first flow control element The lower end portion 112E of the first flow control body 11E of the 10E extends outwardly to communicate with the third opening 303E; the thirteenth channel 1013E, the fourteenth channel 1014E and the fifteenth channel 1015E are respectively The first flow control surface 100E of the flow control element 10E extends downwardly and extends outward from the lower end portion 112E of the first flow control body 11E of the first flow control element 10E to communicate with the fourth opening 304E; The seven-channel 107E extends downward from the first flow control surface 100E of the first flow control element 10E and extends outward from the lower end portion 112E of the first flow control body 11E of the first flow control element 10E to The opening 305E is in communication; the eighth passage 108E extends downward from the first flow control surface 100E of the first flow control element 10E and The lower end portion 112E of the first flow control member of the first flow control body 10E 11E extend outwardly to connect with the opening 306E of the sixth pass. Preferably, the lower end portion 112E of the first flow control body 11E of the first flow control element 10E is integrally formed with the inner side wall 311E of the outer casing body 31E of the outer casing 30E. More preferably, the outer casing The first opening 301E, the second opening 302E, the third opening 303E, the fourth opening 304E, the fifth opening 305E and the sixth opening 306E of the 30E are respectively disposed on the casing body 31E of the outer casing 30E. Most preferably, the H-th channel 1011E of the flow controller is in communication with the tenth channel 1010E; wherein at least one of the tenth channel 1010E and the H-channel 1011E is from the first current-control element The first flow control surface 100E of the 10E extends downwardly and extends outward from the lower end portion 112E of the first flow control body 11E of the first flow control element 10E to communicate with the third opening 303E; the flow controller The fourteenth channel 1014E and the fifteenth channel 1015E are respectively in communication with the thirteenth channel 1013E; wherein at least one of the thirteenth channel 1013E, the fourteenth channel 1014E and the fifteenth channel 1015E Extending downward from the first flow control surface 100E of the first flow control element 10E and extending outward from the lower end portion 112E of the first flow control body 11E of the first flow control element 10E, and the fourth opening 303E Connected.

Optionally, the first opening 301E is in communication with the first receiving chamber 300E, and the second opening 302E is in communication with the ninth channel 109E of the flow controller; the third opening 303E and the tenth of the flow controller The channel 1010E is in communication; the fourth opening 304E is in communication with the thirteenth channel 1013E of the flow controller; the fifth opening 305E is in communication with the seventh channel 107E of the flow controller; the sixth opening 306E is connected to the control The eighth channel 108E of the flow device is in communication, wherein the first H ^ - channel 1011E is in communication with the tenth channel 1010E; the fourteenth channel 1014E and the fifteenth channel 1015E are respectively connected to the thirteenth channel 1013E . That is, the H-channel 1011E is in communication with the tenth channel 1010E; the fourteenth channel 1014E and the fifteenth channel 1015E are respectively connected to the thirteenth channel 1013E; the ninth channel 109E is The first flow control surface 100E of the first flow control element 10E extends downwardly and extends outward from the lower end portion 112E of the first flow control body 11E of the first flow control element 10E to communicate with the second opening 302E. The tenth channel 1010E extends downward from the first flow control surface 100E of the first flow control element 10E and extends outward from the low end portion 112E of the first flow control body 11E of the first flow control element 10E to The third opening 303E is in communication; the thirteenth channel 1013E extends downward from the first flow control surface 100E of the first flow control element 10E and is low from the first flow control body 11E of the first flow control element 10E The end portion 112E extends outwardly to communicate with the fourth opening 304E; the seventh passage 107E extends downward from the first flow control surface 100E of the first flow control element 10E and from the first flow control element 10E a lower end portion 112E of a flow control body 11E extends outwardly to communicate with the fifth opening 305E; the eighth passage 108E A first flow control element 100E flow control surface 10E extending downwardly from the first flow control body and the first flow control element 10E of the lower end 11E The portion 112E extends outward to communicate with the sixth opening 306E.

As shown in FIG. 58G to FIG. 581 of the accompanying drawings, the current controller further has a first conductive channel 1025E and a second conductive channel 1026E, wherein the first conductive channel 1025E and the second conductive channel 1026E Provided in the first flow control body 11E of the first flow control element 10E; wherein the first conduction channel 1025E extends from the seventh channel 107E to the sixteenth channel 1016E and the seventh channel 107E and the first The sixteen channel 1016E is in communication; the second conductive channel 1026E extends from the eighth channel 108E to the seventeenth channel 1017E and connects the eighth channel 108E and the seventeenth channel 1017E.

As shown in FIG. 59C and FIG. 59D of the drawing, the first edge portion 1114E of the top end portion 111E of the first flow control body 11E of the first flow control element 10E of the flow control device includes a first outer edge portion 11141E and a a first conductive portion 11142E extending outward from the first outer edge portion 11141E; a second edge portion 2114E of the bottom end portion 211E of the second flow control body 21E of the second flow control element 20E includes a second The outer edge portion 21141E and a first sealing portion 21142E extending outward from the second outer edge portion 21141E, wherein the first channel 101E and the tenth channel 1010E are respectively disposed on the first flow control element 10E of the flow controller The first outer edge portion 11141E of the first edge portion 1114E of the top end portion 111E of the first flow control body 11E; the eighteenth channel 1018E is disposed at the second flow control body 21E of the second flow control element 20E a second outer edge portion 21141E of the second edge portion 2114E of the bottom end portion 211E; the first conductive channel 1025E is disposed at the top end portion 111E of the first flow control body 11E of the first flow control element 10E of the flow control device The first conductive portion 11142E of the first edge portion 1114E extends to the seventh channel 107E and the sixteenth channel 1016, respectively. E, the seventh passage 107E is connected to the sixteenth passage 1016E; the second conductive passage 1026E is disposed at the top end portion 111E of the first flow control body 11E of the first flow control element 10E of the flow control device The first conductive portion 11142E of the first edge portion 1114E extends to the eighth channel 108E and the seventeenth channel 1017E, respectively, to connect the eighth channel 108E and the seventeenth channel 1017E, wherein When the second flow control element 20E is rotated relative to the first flow control element 10E, the first sealing portion 21142E of the second edge portion 2114E of the bottom end portion 211E of the second flow control body 21E of the second flow control element 20E The first conductive channel 1025E and the second conductive channel 1026E can be separated from the external space above the first flow control body 11E of the first flow control element 10E of the flow controller, respectively. Preferably, the first conductive channel 1025E is respectively associated with the second conductive channel 1026E of the current regulator, the first channel 101E, the second channel 102E, the fourth channel 104E, and the fifth channel 105E. The sixth channel 106E, the eighth channel 108E, the ninth channel 109E, the tenth channel 1010E, the H^-channel 1011E, the thirteenth channel 1013E, the fourteenth channel 1014E, the fifteenth channel 1015E, and the seventeenth channel 1017E phase Separatingly disposed in the first flow control body 11E of the first flow control element 10E; the second conductive path 1026E is respectively associated with the first channel 101E, the second channel 102E, and the fourth channel of the flow controller 104E, the fifth channel 105E, the sixth channel 106E, the seventh channel 107E, the ninth channel 109E, the tenth channel 1010E, the H^-channel 1011E, the thirteenth channel 1013E, the tenth The four-channel 1014E, the fifteenth channel 1015E and the sixteenth channel 1016E are spaced apart from each other at the first flow control body 11E of the first flow control element 10E. More preferably, the first conductive channel 1025E and the second conductive channel 1026E respectively extend downward from the first flow control surface 100E of the current regulator, such that the first conductive channel 1025E and the second conductive channel are turned on. The channel 1026E is adapted to be in communication with the upper outer space of the first flow control element 10E of the flow controller, wherein the second flow control element is disposed when the second flow control element 20E is disposed on the first flow control element 10E The first sealing portion 21142E of the second edge portion 2114E of the bottom end portion 211E of the second flow control body 21E of the 20E is adapted to respectively control the first conductive channel 1025E and the second conductive channel 1026E The outer space above the first flow control body 11E of the first flow control element 10E of the flow device is spaced apart such that when the flow controller is in the first working position, the second working position, the third working position, Flowing through the first conduction channel when the fourth working position, the fifth working position, the sixth working position, the seventh working position, the eighth working position, the ninth working position, and the tenth working position The first control of the fluid of the 1025E and/or the second conduction channel 1026E does not flow upward to the flow controller The external space of the flow element 10E.

As shown in FIG. 58G to FIG. 581, the first conductive path 1025E is disposed at the first edge of the top end portion 111E of the first flow control body 11E of the first flow control element 10E of the flow control device. The first conductive portion 11142E of the portion 1114E extends downward from the first flow control surface 100E of the first flow control element 10E, and the seventh passage 107E and the sixteenth passage 1016E of the flow control device respectively The first flow control surface 100E of the first flow control element 10E extends downwardly and outwardly and communicates with the first conductive passage 1025E, respectively, such that the first conductive passage 1025E the seventh passage 107E and the The sixteenth channel 1016E is in communication; the second conduction channel 1026E is disposed at the first conduction of the first edge portion 1114E of the top end portion 111E of the first flow control body 11E of the first flow control element 10E of the flow control device The portion 11142E extends downward from the first flow control surface 100E of the first flow control element 10E, and the eighth channel 108E and the seventeenth channel 1017E respectively from the first control flow surface of the first flow control element 10E 100E extends downwardly and outwardly and is respectively associated with the second conductive channel 1026E Connected such that the second conductive path 1026E communicates the eighth channel 108E with the seventeenth channel 1017E.

As shown in FIG. 58F and FIG. 59E, the flow controller further includes a wear-resistant member 40E detachably disposed between the first flow control element 10E and the second flow control element 20E, wherein the wear-resistant element The component 40E has a wear resistant body 41E and a second seal portion 42E, wherein the wear resistant body 41E has a wear resistant surface 410E adapted to contact the second flow control surface 200E of the second flow control body 21E, wherein The wear-resistant surface 410E is subjected to wear-resisting treatment, so that the friction generated by the second flow control body 21E of the second flow control element 20E relative to the first flow control body 11E of the first flow control element 10E can be reduced. To extend the service life of the flow controller, wherein when the wear element 40E is disposed between the first flow control element 10E of the flow control device and the second flow control element 20E, the wearable element 40E The second sealing portion 42E can cover the first conductive channel 1025E and the second conductive channel 1026E of the flow controller, thereby the first conductive channel 1025E and the second conductive channel 1026E and the first control The outer space above the first flow control body 11E of the flow element 10 is spaced apart. That is, the second sealing portion 42E of the wear-resistant member 40E can separate the first conductive passage 1025E and the second conductive passage 1026E from the first accommodation chamber 300E of the outer casing 30E. In other words, when the wear element 40E is disposed between the first flow control element 10E of the flow control device and the second flow control element 20E, the second seal portion 42E of the wear resistant element 40E can seal the first a conductive via 1025E and the second conductive via 1026E to prevent fluid flowing through the first conductive via 1025E and/or the second conductive via 1026E from flowing upwardly out of the first conductive via 1025E and/or The second conductive path 1026Eo further, the size and shape of the wear-resistant element 40E are designed and formed according to the first flow control surface 100E of the first flow control element 10E of the flow controller, so that when the wear-resistant element 40E is provided When the first flow control element 10E of the flow control device is between the second flow control element 10E and the second flow control element 20E, the second sealing portion 42E of the wear resistance component 40E can seal the first conduction channel 1025E and the second conduction Channel 1026E, wherein the wear element 40E has a first interface 401E, a second interface 402E, a fourth interface 404E, a fifth interface 405E, a sixth interface 406E, a seventh interface 407E, and an eighth interface. 408E, a ninth interface 409E, a tenth interface 4010E An eleventh interface 4011E, a thirteenth interface 4013E, a fourteenth interface 4014E, a fifteenth interface 4015E, a sixteenth interface 4016E and a seventeenth interface 4017E, wherein the first interface 401E, the first interface a second interface 402E, the fourth interface 404E, the fifth interface 405E, the sixth interface 406E, the seventh interface 407E, the eighth interface 408E, the ninth interface 409E, the first The ten interface 4010E, the first H^-interface 4011E, the thirteenth interface 4013E, the fourteenth interface 4014E, the fifteenth interface 4015E, the sixteenth interface 4016E, and the seventeenth interface 4017E are vertically penetrated The wear-resistant body 41E of the grinding element 40E and the first passage 101E, the second passage 102E, the fourth passage 104E, the fifth passage 105E, the sixth passage 106E, the seventh of the flow control device Channel 107E, the eighth channel 108E, the ninth channel 109E, the tenth channel 1010E, the H^-channel 1011E, the thirteenth channel 1013E, the fourteenth channel 1014E, the fifteenth channel 1015E, The sixteenth channel 1016E corresponds to the seventeenth channel 1017E. That is, the first interface 401E, the second interface 402E, the fourth interface 404E, the fifth interface 405E, the sixth interface 406E, the seventh interface 407E, the eighth interface 408E, and the ninth interface 409E, the tenth interface 4010E, the H-th interface 4011E, the thirteenth interface 4013E, the fourteenth interface 4014E, the fifteenth interface 4015E, the sixteenth interface 4016E, and the seventeenth interface 4017E The first interface 401E is configured to be able to communicate with the eighteenth channel 1018E of the flow controller and the first channel 101E when the current controller is in the first working position, and the fourth interface 404E can communicate with the nineteenth The channel 1019E and the fourth channel 104E, the ninth interface 409E can communicate with the twentieth channel 1020E and the ninth channel 109E; when the current controller is in the second working position, the first interface 401E can communicate with the current controller The eighteenth channel 1018E and the first channel 101E, the fourth interface 404E can communicate with the nineteenth channel 1019E and the fourth channel 104E, the ninth interface 409E can communicate with the twentieth channel 1020E and the ninth channel 109E, The fourteenth interface 4014E is capable of connecting the first H ^ - channel 1021E and the fourteenth channel 1014E, the H ^ - interface 4011E can communicate with the second thirteen channel 1023E and the first H ^ - channel 1011E; when the current controller is in the third working position, The first interface 401E can communicate with the eighteenth channel 1018E of the current controller and the first channel 101E. The fourth interface 404E can communicate with the nineteenth channel 1019E and the fourth channel 104E. The ninth interface 409 can communicate with the first interface 401E. The twentieth channel 1020E and the ninth channel 109E, the sixteenth interface 4016E can communicate with the second H^-channel 1021E and the sixteenth channel 1016E, and the seventeenth interface 1017E can communicate with the second twelve channel 1022E And the seventeenth channel 1017E, the first H^-interface 4011E can communicate with the second twelve channel 1022E and the first H^-channel 1011E, the fifteenth interface 4015E can communicate with the second thirteen channel 1023E and the The fifteenth channel 1015E; when the current controller is in the fourth working position, the first interface 401E can communicate with the eighteenth channel 1018E of the current controller and the first channel 101E, and the fourth interface 404E can communicate with the The nineteenth channel 1019E and the fourth channel 104E, the ninth interface 409E The twenty enough communication channels and 1020E The ninth channel 109E, the seventeenth interface 4017E is capable of connecting the second H^-channel 1021E and the seventeenth channel 1017E; when the current controller is in the fifth working position, the first interface 401E can communicate with the The eighteenth channel 1018E of the flow control device and the first channel 101E, the fourth interface 404E is capable of communicating with the nineteenth channel 1019E and the fourth channel 104E, the ninth interface 409E being capable of connecting the twentieth channel 1020E and the ninth The channel 109E, the first H^-interface 4011E can communicate with the second eleven channel 1021E and the first H^-channel 1011E, and the fifteenth interface 4015E can communicate with the thirteenth channel 1023E and the fifteenth channel 1015E When the current controller is in the sixth working position, the tenth interface 4010E can communicate with the eighteenth channel 1018E and the tenth channel 1010E of the flow controller, and the thirteenth interface 4013E can communicate with the nineteenth channel 1019E And the thirteenth channel 1013E, the ninth interface 409E can communicate with the twentieth channel 1020E and the ninth channel 109E; when the current controller is in the seventh working position, the tenth interface 4010E can communicate with the flow controller Eighteenth channel 1018E and tenth channel 1010E, the first The third interface 4013E can communicate with the nineteenth channel 1019E and the thirteenth channel 1013E, and the ninth interface 409E can communicate with the twentieth channel 1020E and the ninth channel 109E, and the fifth interface 405E can communicate with the second H^- The channel 1021E and the fifth channel 105E, the second interface 402E can communicate with the second thirteen channel 1023E and the second channel 102E; when the current controller is in the eighth working position, the tenth interface 4010E can communicate with the channel The eighteenth channel 1018E and the tenth channel 1010E of the flow control device, the thirteenth interface 4013E can communicate with the nineteenth channel 1019E and the thirteenth channel 1013E, and the ninth interface 409E can communicate with the twentieth channel 1020E and The ninth channel 109E, the seventh interface 407E can communicate with the second H^-channel 1021E and the seventh channel 107E, and the second interface 402E can communicate with the second twelve channel 1022E and the second channel 102E, the first channel The eighth interface 408E can communicate with the twenty-second channel 1022E and the eighth channel 108E, the sixth interface 406E can communicate with the second thirteenth channel 1023E and the sixth channel 106E; when the current controller is in the ninth working position When the tenth interface 4010E can connect The eighteenth channel 1018E and the tenth channel 1010E of the flow control device, the thirteenth interface 4013E can communicate with the nineteenth channel 1019E and the thirteenth channel 1013E, and the ninth interface 409E can communicate with the twentieth channel 1020E And the ninth channel 109E, the eighth interface 408E can communicate with the second H^-channel 1021E to communicate with the eighth channel 108E; when the current controller is in the tenth working position, the tenth interface 4010E can communicate with the The eighteenth channel 1018E and the tenth channel 1010E of the flow control device, the thirteenth interface 4013E can communicate with the nineteenth channel 1019E and the thirteenth channel 1013E, and the ninth interface 409E can communicate with the twentieth channel 1020E and Ninth channel 109E, the second interface 402E can communicate with the second H^-channel 1021E and the second channel 102E, the sixth interface 406E can communicate with the second thirteen channel 1023E and the sixth channel 106E; preferably, when the current controller is in the first In the working position, the sixth interface 406E can communicate with the second eleven channel 1021E and the sixth channel 106E, and the fourteenth interface 4014E can communicate with the second twelve channel 1022E and the fourteenth channel 1014E, the first The sixteen interface 4016E can communicate with the twenty-second channel 1022E and the sixteenth channel 1016E, and the seventeenth interface 4017E can communicate with the twenty-third channel 1023E and the seventeenth channel 1017E; when the current controller is In the second working position, the sixteenth interface 4016E can communicate with the twenty-second channel 1022E and the sixteenth channel 1016E, and the seventeenth interface 4017E can communicate with the twenty-second channel 1022E and the seventeenth channel When the controller is in the fourth working position, the eleventh interface 4011E can communicate with the twenty-second channel 1022E and the eleventh channel 1011E, and the fifteenth interface 4015E can communicate with the second twelve Channel 1022E and the fifteenth channel 1015E, the first The fifteen interface 4015E can communicate with the twenty-third channel 1023E and the fifteenth channel 1015E; when the current controller is in the fifth working position, the fifteenth interface 4015E can communicate with the second twelve channel 1022E and the The fifteenth channel 1015E; when the current controller is in the sixth working position, the fifteenth interface 4015E can communicate with the second H^-channel 1021E and the fifteenth channel 1015E, and the fifth interface 405E can communicate with the The twenty-second channel 1022E and the fifth channel 105E, the seventh interface 407E can communicate with the second twelve channel 1022E and the seventh channel 107E, and the eighth interface 408E can communicate with the second thirteen channel 1023E and the The eighth channel 108E; when the current controller is in the seventh working position, the seventh interface 407E can communicate with the second and second channels 1022E and 107E, and the eighth interface 408E can communicate with the second The channel 1022E and the eighth channel 108E; when the current controller is in the ninth working position, the second interface 402E can communicate with the second channel 1022E and the second channel 102E, and the sixth interface 406E can communicate with the channel a twenty-second channel 1022E and the sixth channel 106E, The sixth interface 406E can communicate with the second thirteenth channel 1023E and the sixth channel 106E. When the current controller is in the tenth working position, the sixth interface 406E can communicate with the second twelfth channel 1022E and the first Six channels 106E; preferably, when the wear element 40E is disposed between the first flow control element 10E and the second flow control element 20E of the flow control device, the wear resistant element 40E does not occur relative to the first The rotation of the first flow control body 11E of the flow control element 10E. More preferably, the wear element 40E has a wear resistant surface 410E that has been smoothed to reduce its roughness. Most preferably, the wear element 40E is integrally formed with the first flow control body 11E of the first flow control element 10E. It is to be noted that since the wear-resistant member 40E is provided with the second sealing portion 42E adapted to seal the first conductive passage 1025E and the second conductive passage 1026E, the second control of the second flow control member 20E The flow body 21E may no longer be provided with the first sealing portion 21142E.

FIG. 58K and FIG. 58L are diagrams showing another alternative embodiment of the flow controller according to the sixth preferred embodiment of the present invention, wherein the outer casing 30E of the present invention further has a seventh opening 307E and An eighth opening 308E, wherein the sixteenth channel 1016E extends downward from the first flow control surface 100E of the first flow control element 10E and from the lower end of the first flow control body 11E of the first flow control element 10E The portion 112E extends outwardly to communicate with the seventh opening 307E, and the seventeenth passage 1017E extends downward from the first flow control surface 100E of the first flow control element 10E and from the first flow control element 10E The lower end portion 112E of the first flow control body 11E extends outward to communicate with the eighth opening 308E.

It can be understood that when the outer casing 30E of the present invention further has a seventh opening 307E communicating with the sixteenth passage 1016E of the flow controller and a seventeenth passage 1017E communicating with the flow controller The eighth opening 308E, the flow controller may no longer be provided with a first conductive channel 1025E connecting the seventh channel 107E of the current controller and the sixteenth channel 1016E, and the flow controller may no longer be provided. A second conduction channel 1026E that communicates the eighth channel 108E of the flow controller with the seventeenth channel 1017E. In addition, since the current control device is no longer provided with the first conductive channel 1025E and the second conductive channel 1026E, the bottom end portion 211E of the second flow control body 21E of the second flow control element 20E is The first sealing portion 21142E is no longer provided by the two edge portions 2114E. Correspondingly, the aforementioned wear-resistant member 40E is no longer provided with the second seal portion 42E.

As shown in FIG. 58B of the accompanying drawings, the flow controller further includes a flow guiding element 50E, wherein the flow guiding element 50E includes a guiding body 51E, wherein the guiding body 51E is surrounded by a first guiding channel 510E. The guide body 51E of the flow guiding element 50E extends upward from the second flow control body 21E of the second flow control element 20E, and the first flow guiding channel 510E of the flow guiding element 50E and the first of the flow control device Twenty-three channels 1023E are connected.

As shown in Figure 58B of the drawings, the flow controller further includes a drive member 60E extending upward from the second flow control body 21E of the second flow control element 20E and a sealing member 70E extending upward from the drive member 60E. Wherein the driving element 60E is adapted to drive the second flow control body 21E of the second flow control element 20E of the flow controller to rotate relative to the first flow control body 11E of the first flow control element 10E; wherein the sealing element 70E Suitable for being disposed in the outer casing 30E and sealing the first accommodating chamber 300E, thereby preventing fluid in the first accommodating chamber 300E from being opened from the upper end of the first accommodating chamber 300E Port 3001E flows out. Preferably, the sealing element 70E is in contact with the drive element 60E and is adapted to hold the drive element 60E in position to maintain the second flow control body 21E of the second flow control element 20E in place. Preferably, the drive element 60E of the flow control device is integrally formed with the flow guiding body 51E of the flow guiding element 50E.

As shown in FIG. 58J of the accompanying drawings, the flow controller according to the sixth preferred embodiment of the present invention further includes a flow blocking member 80E extending downward from the first flow control body 11E of the first flow control element 10E, and The outer casing body 31E of the outer casing 30E extends outward and downward from the lower end portion 112E of the first flow control body 11E of the first flow control element 10E, wherein the flow blocking member 80E forms a partition with the outer casing body 31E. The first flow guiding chamber 801E between the flow element 80E and the outer casing body 31E, and the flow blocking element 80E form a second flow guiding chamber 802E, wherein the first channel 101E and the second channel 102E of the flow controller are The first flow control surface 100E of the first flow control element 10E extends downwardly and communicates with the first flow guiding chamber 801E respectively; the fourth channel 104E, the fifth channel 105E and the sixth channel 106E of the flow controller are The first flow control surface 100E of the first flow control element 10E extends downward and communicates with the second flow guiding chamber 802E, respectively. Preferably, the second channel 102E of the flow controller is in communication with the first channel 101E, wherein at least one of the first channel 101E and the second channel 102E is controlled by the first control element 10E. The flow surface 100E extends downwardly and communicates with the first flow guiding chamber 801E; the fifth channel 105E and the sixth channel 106E of the flow controller are respectively connected to the fourth channel 104E, wherein the fourth channel 104E At least one of the fifth channel 105E and the sixth channel 106E extends downward from the first flow control surface 100E of the first flow control element 10E and is in communication with the second flow guiding chamber 802E.

Referring to Figure 61 of the accompanying drawings, the present invention further provides a water treatment system, wherein the water treatment system includes a flow controller of the present invention and a water treatment unit 90E, wherein the water treatment unit 90E is disposed in the flow controller. And the water flow can flow between the water treatment unit 90E and the flow controller under the control and guidance of the flow control unit, wherein the water treatment unit 90E includes a first water treatment element 91E and a second water treatment element 92E. And a first fluidizer 93E, wherein the first water treatment element 91E has a first communication opening 911E and a second communication opening 912E, the second water treatment element 92E having a third communication opening 921E and a fourth communication Opening 922E, the first fluidizer 93E has a fifth communication opening 931E and a sixth communication opening 932E, wherein the first communication opening 911E of the first water treatment element 91E and the first flow guiding chamber of the flow control device 801E is in communication; the second communication opening 912E of the first water treatment component 91E and the second flow of the flow controller The chamber 802E is in communication; the third communication opening 921E of the second water treatment component 92E is in communication with the third opening 303E of the flow controller; the fourth communication opening 922E of the second water treatment component 92E and the control flow The fourth opening 304E of the device is in communication; the fifth communication opening 931E of the first jet 93E is in communication with the fifth opening 305E of the flow controller; the sixth communication opening 932E of the first fluidizer 93E is The sixth opening 306E of the flow controller is in communication. That is, the first opening 301E of the outer casing 30E of the flow controller of the water treatment system is in communication with an external water source, the third opening 303E, the fourth opening 304E, and the fifth opening 305E of the outer casing 30E. The sixth opening 306E is in communication with the water treatment unit 90E. Further, the first water treatment element 91E has a first water treatment portion 913E in which water to be treated flows from the first communication opening 911E of the first water treatment element 91E and from the first water treatment element 91E When the second communication opening 912E flows out or flows from the second communication opening 912E of the first water treatment element 91E and flows out from the first communication opening 911E of the first water treatment element 91E, the water to be treated is first The first water treatment unit 913E of the water treatment element 91E processes and obtains the treated water. Similarly, the second water treatment element 92E has a second water treatment portion 923E in which water to be treated flows from the third communication opening 921E of the second water treatment element 92E and from the second water treatment element 92E. The fourth communication opening 922E flows out, or flows from the fourth communication opening 922E of the second water treatment element 92E and flows out from the third communication opening 921E of the second water treatment element 92E, the water to be treated is The second water treatment unit 923E of the water treatment element 92E processes and obtains the treated water.

It is to be noted that the first water treatment portion 913E of the first water treatment element 91E of the water treatment unit 90E and the second water treatment portion 923E of the second water treatment element 92E are each made of at least one water treatment material. If it is made of one or more of quartz sand, activated carbon, resin, stereoelastic filler, honeycomb filler or filter, the treated water is treated to remove impurities in the water to be treated or components not desired by the user.

As shown in Fig. 61 of the accompanying drawings, the water treatment unit 90E of the water treatment system according to the sixth preferred embodiment of the present invention further includes a liquid distribution tank 94E, wherein when the first fluid radiator 93E is injecting water into the control When the sixth opening 306E of the outer casing 30E of the flow device, the salt solution in the liquid distribution tank 94E is sucked into the sixth opening 306E of the outer casing 30E of the flow control device, and the salt solution is respectively controlled and guided by the flow control device. Flowing to the second water treatment component 92E or the first water treatment component 91E of the water treatment unit such that the second water treatment portion 923E of the second water treatment component 92E or the first water of the first water treatment component 91E The processing unit 913E is reproduced. It is noted that when the outer casing 30E of the flow control system of the water treatment system further has the seventh opening 307E and the eighth opening 308E, the water treatment unit 90E of the water treatment system further includes a second fluidizer 95E, wherein The second jet 95E has a seventh communication opening 951E and an eighth communication opening 952E, wherein the seventh communication opening 951E of the second jet 95E and the seventh of the outer casing 30E of the flow control system of the water treatment system The opening 307E is in communication; the eighth communication opening 952E of the second jet 95E is in communication with the eighth opening 308E of the outer casing 30E of the flow control system of the water treatment system, wherein the first jet 93E is in the water jet When entering the sixth opening 306E of the outer casing 30E of the flow control device, the salt solution in the liquid distribution tank 94E is sucked into the sixth opening 306E of the outer casing 30E of the flow control device, and the salt solution is controlled in the flow control device. And directing the first water treatment component 91E to the water treatment unit to regenerate the first water treatment portion 913E of the first water treatment component 91E; when the second fluidizer 95E is injecting water into the control The eighth opening 308E of the outer casing 30E of the flow device The salt solution in the liquid distribution tank 94E is sucked into the eighth opening 308E of the outer casing 30E of the flow control device, and the salt solution flows to the second water treatment of the water treatment unit under the control and guidance of the flow control device. Element 92E causes regeneration of second water treatment portion 923E of second water treatment element 92E.

As shown in Figure 60A of the accompanying drawings, when the flow controller of the water treatment system is in the first working position, the water to be treated is adapted to flow into the first portion of the outer casing 30E through the first opening 301E of the outer casing 30E of the flow control device. The accommodating chamber 300E flows into the first passage 101E through the conduction opening 10181E of the eighteenth passage 1018E, and then the water to be treated passes through the first flow guiding chamber 801E and the first water treatment of the water treatment unit 90E of the water treatment system The first communication opening 911E of the element 91E flows into the first water treatment element 91E and passes through the treatment of the first water treatment unit 913E provided in the first water treatment element 91E, thereby obtaining treated water, and the treated water is suitable Under the pressure, the second communication opening 912E of the first water treatment element 91E flows into the second flow guiding chamber 802E of the flow controller, and then flows into the fourth passage 104E of the flow controller, and then passes through the flow controller. The nineteenth channel 1019E flows into the twentieth channel 1020E of the flow controller, and then flows into the ninth channel 109E through the twentieth channel 1020E, and finally flows out through the second opening 302E of the outer casing 30E of the flow controller to For the user to use; as shown in Figure 60B of the accompanying drawings When the flow control device of the water treatment system is in the second working position, the water to be treated is adapted to flow into the first accommodation chamber 300E of the outer casing 30E through the first opening 301E of the outer casing 30E of the flow control device and pass the eighteenth The conduction opening 10181E of the channel 1018E flows into the first channel 101E, and then the water to be treated flows in through the first flow guiding chamber 801E and the first communication opening 911E of the first water treatment element 91E of the water treatment unit 90E of the water treatment system. The first water treatment element 91E is disposed on the first After the treatment of the first water treatment unit 913E in the water treatment element 91E, the treated water is obtained, and the treated water flows into the flow controller through the second communication opening 912E of the first water treatment element 91E under a suitable pressure. The second flow guiding chamber 802E then flows into the fourth channel 104E of the flow controller, and then flows into the twentieth channel 1020E of the flow controller through the nineteenth channel 1019E of the flow controller, and then passes through the second The ten-channel 1020E flows into the ninth channel 109E and the second H^-channel 1021E, respectively, wherein the treated water flowing into the ninth channel 109E flows out through the second opening 302E of the outer casing 30E of the flow controller for the user Using, the treated water flowing into the twenty-first channel 1021E flows into the fourteenth channel 1014E and the thirteenth channel 1013E of the flow controller, and then flows to the second through the fourth opening 304E of the outer casing 30E of the flow controller. The water treatment element 92E flows into the second water treatment element 92E via the fourth communication opening 922E of the second water treatment element 92E, thereby enabling the treated water to be subjected to the second water treatment of the second water treatment element 92E Department 923E performs backwashing, backwashing The generated waste liquid flows into the third opening 303E of the outer casing 30E of the flow control device through the third communication opening 921E of the second water treatment element 92E, and then flows into the tenth passage 1010E and the H^- of the flow control device. The channel 101 IE finally flows out through the twenty-third channel 1023E and the first flow guiding channel 510E of the flow guiding element 50E; as shown in FIG. 60C of the drawing, when the flow controller of the water treatment system is in the third work In position, the water to be treated is adapted to flow into the first receiving chamber 300E of the outer casing 30E through the first opening 301E of the outer casing 30E of the flow control device and into the first passage 101E through the conductive opening 10181E of the eighteenth passage 1018E. Then, the water to be treated flows into the first water treatment element 91E through the first flow guiding chamber 801E and the first communication opening 911E of the first water treatment element 91E of the water treatment unit 90E of the water treatment system, and is provided in the first After the treatment of the first water treatment unit 913E in the water treatment element 91E, the treated water is obtained, and the treated water flows into the control flow through the second communication opening 912E of the first water treatment element 91E under a suitable pressure. Second diversion chamber 802E, then flow into the The fourth channel 104E of the flow device then flows into the twentieth channel 1020E of the flow controller through the nineteenth channel 1019E of the flow controller, and then flows into the ninth channel 109E through the twentieth channel 1020E and the a second H^-channel 1021E, wherein the treated water flowing into the ninth channel 109E flows out through the second opening 302E of the outer casing 30E of the flow controller for use by the user, flowing into the second H^-channel 1021E After treatment, water flows into the sixteenth channel 1016E of the flow controller, and then flows into the seventh channel 107E through the first conduction channel 1025E and flows into the first streamer 93E through the fifth opening 305E of the outer casing 30E of the flow controller. Then, the treated water is mixed by the first jet 93E, and the treated water is mixed with the salt solution from the dosing tank 94E and injected into the control flow. a sixth opening 306E of the outer casing 30E, and then, the mixed liquid of the treated water and the salt solution flows into the eighth passage 108E of the flow controller and flows through the second conductive passage 1026E to the flow controller. The seventeen channel 1017E, and then through the twenty-second channel 1022E of the flow controller, flows into the H-channel 1011E and the tenth channel 1010E of the flow controller, and then passes through the third opening of the outer casing 30E of the flow controller. 303E flows to the second water treatment element 92E, and flows into the second water treatment element 92E through the third communication opening 921E of the second water treatment element 92E, so that the mixed liquid formed by the treated water and the salt solution can The second water treatment unit 923E of the second water treatment element 92E is subjected to a regeneration process, and the waste liquid generated by the regeneration process flows into the outer casing 30E of the flow controller through the fourth communication opening 922E of the second water treatment element 92E. a fourth opening 304E, which then flows into the thirteenth channel 1013E and the fifteenth channel 1015E of the flow control, and finally flows out through the second thirteenth channel 1023E and the first flow guiding channel 510E of the flow guiding element 50E; Figure 60D, when the water treatment system of the water treatment system In the fourth working position, the water to be treated is adapted to flow into the first receiving chamber 300E of the outer casing 30E through the first opening 301E of the outer casing 30E of the flow controller and flow into the through opening 10181E of the eighteenth passage 1018E. The first passage 101E, then the water to be treated flows into the first water treatment element 91E through the first flow guiding chamber 801E and the first communication opening 911E of the first water treatment element 91E of the water treatment unit 90E of the water treatment system After the treatment of the first water treatment unit 913E in the first water treatment element 91E, the treated water is obtained, and the treated water passes through the second communication opening 912E of the first water treatment element 91E under a suitable pressure. Flowing into the second flow guiding chamber 802E of the flow controller, then flowing into the fourth passage 104E of the flow controller, and then flowing into the twentieth channel 1020E of the flow controller through the nineteenth passage 1019E of the flow controller, Then, the ninth channel 1020E flows into the ninth channel 109E and the second H^-channel 1021E, respectively, wherein the processed water flowing into the ninth channel 109E flows out through the second opening 302E of the outer casing 30E of the flow controller. For users to use, inflow The treated water of the second H^-channel 1021E flows into the seventeenth channel 1017E of the flow controller, and then flows into the eighth channel 108E through the second conduction channel 1026E and passes through the sixth portion of the outer casing 30E of the flow controller. The opening 306E flows into the first jet 93E and then flows into the dosing tank 94E via the first jet 93E; as shown in Fig. 60E of the drawing, when the flow control device of the water treatment system is in the fifth working position, The treated water is adapted to flow into the first receiving chamber 300E of the outer casing 30E through the first opening 301E of the outer casing 30E of the flow control device and into the first passage 101E through the conductive opening 10181E of the eighteenth passage 1018E, and then to be treated Water flows into the first water through the first flow guiding chamber 801E and the first communication opening 911E of the first water treatment element 91E of the water treatment unit 90E of the water treatment system After the processing element 91E is processed by the first water treatment unit 913E provided in the first water treatment element 91E, the treated water is obtained, and the treated water passes through the first water treatment element 91E under a suitable pressure. The second communication opening 912E flows into the second flow guiding chamber 802E of the flow controller, then flows into the fourth passage 104E of the flow controller, and then flows into the flow controller through the nineteenth passage 1019E of the flow controller. a twenty-channel 1020E, and then flows into the ninth channel 109E and the second H^-channel 1021E via the twentieth channel 1020E, respectively, wherein the treated water flowing into the ninth channel 109E passes through the outer casing 30E of the flow control device The second opening 302E flows out for the user to use, and the treated water flowing into the second eleven channel 1021E flows into the H^-channel 1011E and the tenth channel 1010E of the flow controller, and then passes through the outer casing of the flow controller. The third opening 303E of the 30E flows to the second water treatment element 92E, and flows into the second water treatment element 92E through the third communication opening 921E of the second water treatment element 92E, so that the treated water can be The second water treatment unit 923E of the second water treatment element 92E The positive rinsing process is performed, and the waste liquid generated by the rinsing process flows into the fourth opening 304E of the outer casing 30E of the flow controller through the fourth communication opening 922E of the second water treatment element 92E, and then flows into the tenth of the flow controller. The three-channel 1013E and the fifteenth channel 1015E finally flow out through the twenty-third channel 1023E and the first flow guiding channel 510E of the flow guiding element 50E; as shown in FIG. 60F of the drawing, when the water treatment system is controlled When the flow device is in the sixth working position, the water to be treated is adapted to flow into the first accommodation chamber 300E of the outer casing 30E through the first opening 301E of the outer casing 30E of the flow control device and pass through the conduction opening 10181E of the eighteenth passage 1018E. Flowing into the tenth passage 1010E, the water to be treated then flows into the second water treatment element through the third opening 303E of the outer casing 30E and the third communication opening 921E of the second water treatment element 92E of the water treatment unit 90E of the water treatment system 92E is treated by the second water treatment unit 923E provided in the second water treatment element 92E to obtain treated water, and the treated water is subjected to the fourth pressure of the second water treatment element 92E under a suitable pressure. The communication opening 922E flows into the The fourth opening 304E of the casing 30E then flows into the thirteenth passage 1013E of the flow controller, and then flows into the twentieth passage 1020E of the flow controller through the nineteenth passage 1019E of the flow controller, and then passes through the The twenty-channel 1020E flows into the ninth passage 109E, and finally flows out through the second opening 302E of the outer casing 30E of the flow controller for the user to use; as shown in FIG. 60G of the drawing, when the water treatment system is controlled When the device is in the seventh working position, the water to be treated is adapted to flow into the first receiving chamber 300E of the outer casing 30E through the first opening 301E of the outer casing 30E of the flow controller and flow through the conducting opening 10181E of the eighteenth passage 1018E. The tenth channel 1010E, the water to be treated subsequently passes through the third opening 303E of the outer casing 30E and the second water of the water treatment unit 90E of the water treatment system The third communication opening 921E of the processing element 92E flows into the second water treatment element 92E and passes through the treatment of the second water treatment unit 923E provided in the second water treatment element 92E, thereby obtaining treated water, and the treated water is The fourth communication opening 922E of the second water treatment element 92E flows into the fourth opening 304E of the outer casing 30E by a suitable pressure, and then flows into the thirteenth passage 1013E of the flow controller, and then passes through the flow controller. The nineteenth channel 1019E flows into the twentieth channel 1020E of the flow controller, and then flows into the ninth channel 109E and the second H^-channel 1021E through the twentieth channel 1020E, respectively, into which the ninth channel 109E flows. The treated water flows out through the second opening 302E of the outer casing 30E of the flow controller for the user to use, and the treated water flowing into the second eleventh channel 1021E flows into the fifth passage 105E and the fourth passage of the flow control device. 104E, then flowing into the first water treatment element 91E through the second flow guiding chamber 802E and the second communication opening 912E of the first water treatment element 91E of the water treatment unit 90E of the water treatment system, thereby enabling the treated water to The first water treatment The first water treatment portion 913E of the element 91E performs a backwashing process, and the waste liquid generated by the backwashing process flows into the first flow guiding chamber 801E through the first communication opening 911E of the first water treatment element 91E, and then flows into the control flow. The first channel 101E and the second channel 102E of the device finally flow out through the second thirteen channel 1023E and the first flow guiding channel 510E of the flow guiding element 50E; as shown in FIG. 60H of the drawing, when the water treatment system When the flow controller is in the eighth working position, the water to be treated is adapted to flow into the first receiving chamber 300E of the outer casing 30E through the first opening 301E of the outer casing 30E of the flow controller and to conduct through the eighteenth passage 1018E. The opening 10181E flows into the tenth passage 1010E, and then the water to be treated flows into the second water through the third opening 303E of the outer casing 30E and the third communication opening 921E of the second water treatment element 92E of the water treatment unit 90E of the water treatment system. After the processing element 92E is processed by the second water treatment unit 923E provided in the second water treatment element 92E, the treated water is obtained, and the treated water passes through the second water treatment element 92E under a suitable pressure. Fourth communication opening 922E flow The fourth opening 304E of the outer casing 30E then flows into the thirteenth passage 1013E of the flow controller, and then flows into the twentieth passage 1020E of the flow controller through the nineteenth passage 1019E of the flow controller, and then passes through the The twentieth channel 1020E flows into the ninth channel 109E and the second H^-channel 1021E, respectively, wherein the treated water flowing into the ninth channel 109E flows out through the second opening 302E of the outer casing 30E of the flow controller for The user uses, the treated water flowing into the twenty-first channel 1021E flows into the seventh channel 107E of the flow controller, and then flows into the first fluidizer 93E through the fifth opening 305E of the outer casing 30E of the flow controller, and then The treated water is mixed by the first jet 93E, and the treated water is mixed with the salt solution from the dispensing tank 94E and injected into the a sixth opening 306E of the outer casing 30E of the flow controller, and then, the mixed liquid of the treated water and the salt solution flows into the eighth passage 108E of the flow controller, and then passes through the twenty-second passage of the flow control device. 1022E flows into the second passage 102E and the first passage 101E of the flow controller, and then flows in through the first flow guiding chamber 801E and the first communication opening 911E of the first water treatment element 91E of the water treatment unit 90E of the water treatment system The first water treatment element 91E, so that the mixed liquid formed by the treated water and the salt solution can regenerate the first water treatment unit 913E of the first water treatment element 91E, and the waste liquid generated by the regeneration treatment passes through the The second communication opening 912E of the first water treatment element 91E flows into the second flow guiding chamber 802E, and then flows into the fourth channel 104E and the sixth channel 106E of the flow controller, and finally through the second thirteen channel 1023E and the The first flow guiding channel 510E of the flow guiding element 50E flows out; as shown in the drawing 601 of the drawing, when the flow controller of the water treatment system is in the ninth working position, the water to be treated is adapted to pass through the outer casing of the flow control device. The first opening 301E of 30E flows into the first portion of the outer casing 30E The accommodating chamber 300E flows into the tenth passage 1010E through the conductive opening 10181E of the eighteenth passage 1018E, and then the water to be treated passes through the third opening 303E of the outer casing 30E and the second water of the water treatment unit 90E of the water treatment system The third communication opening 921E of the processing element 92E flows into the second water treatment element 92E and passes through the treatment of the second water treatment unit 923E provided in the second water treatment element 92E to obtain treated water, and the treated water is The fourth communication opening 922E of the second water treatment element 92E flows into the fourth opening 304E of the outer casing 30E by a suitable pressure, and then flows into the thirteenth passage 1013E of the flow controller, and then passes through the flow controller. The nineteenth channel 1019E flows into the twentieth channel 1020E of the flow controller, and then flows into the ninth channel 109E and the second H^-channel 1021E through the twentieth channel 1020E, respectively, into which the ninth channel 109E flows. After the treatment, the water flows out through the second opening 302E of the outer casing 30E of the flow controller for the user to use, and the treated water flowing into the second eleven channel 1021E flows into the eighth passage 108E of the flow controller, and then passes through the The outer casing of the flow controller 30E The sixth opening 306E flows into the first jet 93E, and then flows into the dosing tank 94E via the first jet 93E; as shown in FIG. 60J of the drawing, when the flow control device of the water treatment system is in the tenth working position The water to be treated is adapted to flow into the first receiving chamber 300E of the outer casing 30E through the first opening 301E of the outer casing 30E of the flow control device and into the tenth passage 1010E through the conductive opening 10181E of the eighteenth passage 1018E, and then The water to be treated flows into the second water treatment element 92E through the third opening 303E of the outer casing 30E and the third communication opening 921E of the second water treatment element 92E of the water treatment unit 90E of the water treatment system and is disposed in the second After the treatment of the second water treatment unit 923E in the water treatment element 92E, the treated water is obtained, and the treated water passes through the second water under a suitable pressure. The fourth communication opening 922E of the processing element 92E flows into the fourth opening 304E of the outer casing 30E, then flows into the thirteenth passage 1013E of the flow controller, and then flows into the flow controller through the nineteenth passage 1019E of the flow controller. The twentieth channel 1020E, and then flows into the ninth channel 109E and the second H^-channel 1021E via the twentieth channel 1020E, respectively, wherein the processed water flowing into the ninth channel 109E passes through the outer casing of the flow controller The second opening 302E of the 30E flows out for the user to use, and the treated water flowing into the second H^-channel 1021E flows into the second channel 102E and the first channel 101E of the flow controller, and then passes through the first diversion flow. The chamber 801E and the first communication opening 911E of the first water treatment element 91E of the water treatment unit 90E of the water treatment system flow into the first water treatment element 91E, thereby enabling the treated water to be capable of the first water treatment element 91E The first water treatment unit 913E performs a positive flushing process, and the waste liquid generated by the positive flushing process flows into the second flow guiding chamber 802E through the second communication opening 912E of the first water treatment element 91E, and then flows into the flow control device. Four channels 104E and sixth channel 10 6E, finally flowing out through the twenty-third channel 1023E and the first flow guiding channel 510E of the flow guiding element 50E.

Referring to Figures 62A-65 of the accompanying drawings of the present invention, a flow controller according to a seventh preferred embodiment of the present invention is illustrated, which is adapted to control multi-directional flow of water flow, wherein the flow controller includes a first control a flow element 10F and a second flow control element 20F rotatably disposed on the first flow control element 10F, wherein the first flow control element 10F includes a first flow control body 11F, and the first flow control body 11F includes a top end portion 111F, wherein the top end portion 111F forms a first flow control surface 100F; the second flow control element 20F includes a second flow control body 21F having a bottom end portion 211F and a a bottom portion 211F extending from the bottom end portion 211F, the bottom end portion 211F forming a second flow control surface 200F; wherein the second flow control surface 200F of the second flow control element 20F is adapted to be rotatably disposed on The first flow control surface 100F of the first flow control element 10F.

As shown in FIG. 62C to FIG. 62G of the accompanying drawings, further, as shown in FIG. 63A to FIG. 63B of the accompanying drawings, the flow controller has a first passage 101F, a second passage 102F, and a fourth passage 104F. A fifth channel 105F, a sixth channel 106F, a ninth channel 109F, a tenth channel 1010F, a first H ^ - channel 1011F, a thirteenth channel 1013F, a fourteenth channel 1014F, a fifteenth Channel 1015F, an eighteenth channel 1018F, a nineteenth channel 1019F, a twentieth channel 1020F, a second H^-channel 1021F, and a twenty-third channel 1023F, wherein the first channel 101F, the first Two channels 102F, the fourth channel 104F, the fifth channel 105F, the sixth channel 106F, the ninth channel 109F, the tenth channel 1010F, the first H ^ - channel 1011F, the thirteenth channel 1013F, the fourteenth channel 1014F and the fifteenth channel 1015F are respectively disposed on the first flow control body 11F of the first flow control element 10F and The first flow control surface 100F of the first flow control body 11F of the first flow control element 10F extends downward; the eighteenth passage 1018F is disposed at the bottom end portion 211F of the second flow control body 21F and is controlled by the second control The second flow control surface 200F of the bottom end portion 211F of the flow body 21F extends upwardly and outwardly and forms a conduction opening 10181F that is always in communication with the external space; the nineteenth channel 1019F, the twentieth channel 1020F, The second H ^ - channel 1021F and the second thirteenth channel 1023F are respectively disposed at the bottom end portion 211F of the second flow control body 21F and the second control flow from the bottom end portion 211F of the second flow control body 21F The face 200F extends upward, wherein the nineteenth channel 1019F and the second two H^-channels 1021F are respectively disposed outside the twentieth channel 1020F and are respectively connected to the twentieth channel 1020F. In other words, the conductive opening 10181F of the eighteenth channel 1018F maintains the eighteenth channel 1018F in constant communication with the external space, particularly the external space of the flow control. Preferably, the nineteenth channel 1019F, the twentieth channel 1020F and the second H^ channel 1021F of the flow controller respectively extend upward from the second flow control surface 200F of the second flow control element 20F to the a high-end portion 212F of the second flow control element 21F; the second thirteen-channel 1023F extends upward from the second flow control surface 200F of the second flow control element 20F and runs through the second flow control body of the second flow control element 20F. 21F, wherein the nineteenth channel 1019F is in communication with the twentieth channel 1020F; the second H^-channel 1021F extends upward and inward from the second flow control surface 200F of the second flow control element 20F, thereby It is in communication with the twentieth channel 1020F.

As shown in FIGS. 64A to 64H of the drawings, the second flow control element 20F is rotatable relative to the first flow control element 10F such that the flow control device has a first working position, a second working position, and a third a working position, a fourth working position, a fifth working position, a sixth working position, a seventh working position and an eighth working position, wherein the flow controller is when the current controller is in the first working position The eighteenth channel 1018F is in communication with the first channel 101F, the nineteenth channel 1019F is in communication with the fourth channel 104F, and the twentieth channel 1020F is in communication with the ninth channel 109F; when the current controller is in the second In the working position, the eighteenth channel 1018F of the flow controller is in communication with the first channel 101F, the nineteenth channel 1019F is in communication with the fourth channel 104F, and the twentieth channel 1020F is in communication with the ninth channel 109F. The second H^-channel 1021F is in communication with the fourteenth channel 1014F, and the second thirteenth channel 1023F is in communication with the H^-channel 1011F; when the current controller is in the third working position, the current controller Eighteenth channel 1018F and first channel 101F Communication, the first The 19th channel 1019F is in communication with the fourth channel 104F, the twentieth channel 1020F is in communication with the ninth channel 109F, and the second H^-channel 1021F is in communication with the H^-channel 1011F, the second thirteen channel The 1023F is in communication with the fifteenth channel 1015F; when the flow controller is in the fourth working position, the eighteenth channel 1018F of the flow controller is connected to the first channel 101F and the tenth channel 1010F, respectively. The channel 1019F is in communication with the fourth channel 104F and the thirteenth channel 1013F, respectively, and the twentieth channel 1020F is in communication with the ninth channel 109F; when the current controller is in the fifth working position, the tenth of the flow controller The eight-channel 1018F is in communication with the tenth channel 1010F, the nineteenth channel 1019F is in communication with the thirteenth channel 1013F, and the twentieth channel 1020F is in communication with the ninth channel 109F; when the current controller is in the sixth working position The eighteenth channel 1018F of the flow controller is in communication with the tenth channel 1010F, the nineteenth channel 1019F is in communication with the thirteenth channel 1013F, and the twentieth channel 1020F is in communication with the ninth channel 109F. Second H ^ - channel 1021F and fifth channel 105F Connected, the twenty-third channel 1023F is in communication with the second channel 102F; when the current controller is in the seventh working position, the eighteenth channel 1018F of the flow controller is in communication with the tenth channel 1010F, the first The nineteenth channel 1019F is in communication with the thirteenth channel 1013F, the twentieth channel 1020F is in communication with the ninth channel 109F, and the second H^ channel 1021F is in communication with the second channel 102F, the second thirteen channel 1023F The sixth channel 106F is in communication with the sixth channel 106F; when the current controller is in the eighth working position, the eighteenth channel 1018F of the flow controller is respectively connected to the first channel 101F and the tenth channel 1010F, and the nineteenth channel 1019F The fourth channel 104F and the thirteenth channel 1013F are respectively connected, and the twentieth channel 1020F is in communication with the ninth channel 109F. Preferably, when the flow controller is in the first working position, the twenty-third channel 1023F is in communication with the fourteenth channel 1014F; when the current controller is in the fourth working position, the second eleventh channel The 1021F is in communication with the fifteenth channel 1015F; when the flow controller is in the fifth working position, the twenty-third channel 1023F is in communication with the fifth channel 105F; when the current controller is in the eighth working position The second H^-channel 1021F is in communication with the sixth channel 106F. More preferably, when the flow controller is in the first working position, the second channel 102F, the fifth channel 105F, the sixth channel 106F, the tenth channel 1010F, the first H^-channel 1011F, the first The thirteenth channel 1013F and the fifteenth channel 1015F are respectively blocked by the second flow control body 21F of the second flow control element 20F of the current control device, and the second eleventh channel 1021F is controlled by the first flow of the flow control device. The first flow control body 11F of the component 10F is blocked; when the flow controller is in the second working position, the second channel 102F, the fifth channel 105F, the sixth channel 106F, the tenth channel 1010F, the tenth The three-channel 1013F and the fifteenth channel 1015F are respectively controlled by the flow The second flow control body 21F of the second flow control element 20F of the device is blocked; when the flow controller is in the third working position, the second channel 102F, the fifth channel 105F, the sixth channel 106F, the tenth The channel 1010F, the thirteenth channel 1013F and the fourteenth channel 1014F are respectively blocked by the second flow control body 21F of the second flow control element 20F of the flow controller; when the flow controller is in the fourth working position, The second channel 102F, the fifth channel 105F, the sixth channel 106F, the H^-channel 1011F, and the fourteenth channel 1014F are respectively controlled by the second flow control element 20F of the current regulator. The second channel 1023F is blocked by the first flow control body 11F of the first flow control component 10F of the flow control device. When the flow controller is in the fifth working position, the first channel 101F, The second channel 102F, the fourth channel 104F, the sixth channel 106F, the H-channel 1011F, the fourteenth channel 1014F, and the fifteenth channel 1015F are respectively controlled by the second flow of the current controller. The second flow control body 21F of the component 20F is blocked, and the second H^-channel 1021F is blocked by the flow control device. The first flow control body 11F of the first flow control element 10F is blocked; when the flow control device is in the sixth working position, the first channel 101F, the fourth channel 104F, the sixth channel 106F, the first H^- The channel 1011F, the fourteenth channel 1014F and the fifteenth channel 1015F are respectively blocked by the second flow control body 21F of the second flow control element 20F of the flow controller; when the flow controller is in the seventh working position, The first channel 101F, the fourth channel 104F, the fifth channel 105F, the H-channel 1011F, the fourteenth channel 1014F, and the fifteenth channel 1015F are respectively controlled by the second flow of the current controller. The second flow control body 21F of the component 20F is blocked; when the flow controller is in the eighth working position, the second channel 102F, the fifth channel 105F, the H^-channel 1011F, the fourteenth channel 1014F and The fifteenth channel 1015F is respectively blocked by the second flow control body 21F of the second flow control element 20F of the flow control device, and the second thirteenth channel 1023F is first by the first flow control element 10F of the flow control device. The flow control body 11F is blocked.

As shown in FIG. 63A to FIG. 63B, the first channel 101F of the flow controller according to the seventh preferred embodiment of the present invention is respectively associated with the fourth channel 104F, the fifth channel 105F, and the sixth channel 106F. The ninth channel 109F, the tenth channel 1010F, the first H^-channel 1011F, the thirteenth channel 1013F, the fourteenth channel 1014F and the fifteenth channel 1015F are spaced apart from each other. a first flow control body 11F of the flow control element 10F; the second channel 102F and the fourth channel 104F, the fifth channel 105F, the sixth channel 106F, the ninth channel 109F, the tenth channel 1010F, The first flow control body 11F of the first flow control element 10F is spaced apart from the first flow control element 10F, and the first flow control element 10F is disposed at a distance from the first flow control element 10F, and the first fourteenth channel 1011F, the fourteenth channel 1014F, and the fifteenth channel 1014F are separated from each other. Four channels 104F and the ninth channel 109F, the tenth channel 1010F, the H^-channel 1011F, the thirteenth channel 1013F, the fourteenth channel 1014F and the fifteenth channel 1015F are spaced apart from each other in the first flow control body 11F of the first flow control element 10F; the fifth channel 105F is respectively The ninth channel 109F, the tenth channel 1010F, the H-th channel 1011F, the thirteenth channel 1013F, the fourteenth channel 1014F, and the fifteenth channel 1015F are spaced apart from each other. The first flow control body 11F of the flow element 10F; the sixth channel 106F and the ninth channel 109F, the tenth channel 1010F, the first H ^ - channel 1011F, the thirteenth channel 1013F, the fourteenth channel 1014F and the fifteenth channel 1015F are spaced apart from the first flow control body 11F of the first flow control element 10F; the ninth channel 109F and the tenth channel 1010F, the H^-channel 1011F, The thirteenth channel 1013F, the fourteenth channel 1014F and the fifteenth channel 1015F are spaced apart from each other in the first flow control body 11F of the first flow control element 10F; the tenth channel 1010F and the first The thirteen channel 1013F, the fourteenth channel 1014F and the fifteenth channel 1015F are spaced apart from each other at the first The first flow control body 11F of the flow control element 10F; the eleventh channel 1011F is respectively disposed at the first control of the thirteenth channel 1013F, the fourteenth channel 1014F and the fifteenth channel 1015F The first flow control body 11F of the flow element 10F; the eighteenth channel 1018F is respectively associated with the nineteenth channel 1019F, the twentieth channel 1020F, the second H^ channel 1021F, and the second thirteen channel 1023F Separatingly disposed in the second flow control body 21F of the second flow control element 20F; the nineteenth channel 1019F, the twentieth channel 1020F and the second H^ channel 1021F and the second thirteen channel respectively The 1023F is spaced apart from the second flow control body 21F of the second flow control element 20F. Preferably, the second channel 102F is in communication with the first channel 101F; the fifth channel 105F and the sixth channel 106F are respectively connected to the fourth channel 104F; the first H^-channel 1011F and the tenth channel The 1010F phase is connected; the fourteenth channel 1014F and the fifteenth channel 1015F are respectively in communication with the thirteenth channel 1013F.

As shown in FIG. 63C to FIG. 63D, the top end portion 111F of the first flow control body 21F of the first flow control element 10F of the flow control device includes a first central portion 1111F. a first intermediate portion 1112F extending outwardly from the first central portion 1111F, a first extending portion 1113F extending outward from the first intermediate portion 1112F and a first edge portion extending outward from the first extending portion 1113F 1114F, and the bottom end portion 211F of the second flow control body 21F of the second flow control element 20F includes a second central portion 2111F and a second intermediate portion 2112F extending outward from the second central portion 2111F. a second extending portion 2113F extending outward from the second intermediate portion 2112F and a second edge portion 2114F extending outward from the second extending portion 2113F, wherein the first pass The first 101F and the tenth channel 1010F are respectively disposed at the first edge portion 1114F of the top end portion 111F; the second channel 102F, the fifth channel 105F, the sixth channel 106F, the H^-channel 1011F, the first The fourteenth channel 1014F and the fifteenth channel 1015F are respectively disposed at the first extending portion 1113F of the top end portion 111F; the fourth channel 104F and the thirteenth channel 1013F are respectively disposed in the first middle of the top end portion 111F The ninth passage 109F is disposed at the first central portion 1111F of the top end portion 111F; the eighteenth passage 1018F is disposed at the second edge portion 2114F of the bottom end portion 211F; the nineteenth passage 1019F is provided at a second intermediate portion 2112F of the bottom end portion 211F; the second ten channel 1020F is disposed at the second central portion 2111F of the bottom end portion 211F; the second H^-channel 1021F and the second thirteen channel 1023F are respectively The second extension 2113F.

As shown in FIG. 63A to FIG. 63B, the first flow control surface 100F of the first flow control element 10F of the flow control device and the second control flow surface 200F of the second flow control element 20F are both circular, wherein The second channel 102F, the fifth channel 105F, the fifteenth channel 1015F, the H^-channel 1011F, the fourteenth channel 1014F and the sixth channel 106F of the flow controller are arranged clockwise in the first control in this order. The first flow control body 11F of the flow element 10F; the second thirteenth channel 1023F and the second eleventh channel 1021F of the flow control device are disposed clockwise in this order on the second flow control body of the second flow control element 20F 21F. Optionally, the second channel 102F, the fifth channel 105F, the fifteenth channel 1015F, the eleventh channel 1011F, the fourteenth channel 1014F, and the sixth channel 106F of the flow controller are disposed counterclockwise in this order. a first flow control body 11F of the first flow control element 10F; a second thirteenth channel 1023F and a second eleventh channel 1021F of the flow control device are disposed counterclockwise in this order to the second of the second flow control element 20F The flow body 21F is controlled. Preferably, the first channel 101F, the second channel 102F, the fourth channel 104F, the fifth channel 105F, the sixth channel 106F, the ninth channel 109F, the tenth channel 1010F, the H-th The channel 1011F, the thirteenth channel 1013F, the fourteenth channel 1014F, and the fifteenth channel 1015F are both radially disposed on the first control surface 100F of the first flow control element 10F, and the eighteenth channel 1018F, the nineteenth channel 1019F, the twentieth channel 1020F, the second H^-channel 1021F, and the twenty-third channel 1023F are respectively disposed in a radial direction on the second control element 20F. Flow surface 200F.

As shown in FIG. 63C to FIG. 63D, the first flow control surface 100F of the first flow control element 10F of the flow control device has a central portion 1000F indicated by a chain line in the figure, wherein the central portion 1000F is disposed at the center portion 1000F. The first central portion 1111F of the distal end portion 111F of the first flow control body 11F of the first flow control element 10F, and the portion other than the central portion 1000F of the first control flow surface 100F is clockwisely divided A first portion 1001F, a second portion 1002F, a third portion 1003F, a fourth portion 1004F, a fifth portion 1005F, a sixth portion 1006F, a seventh portion 1007F, and an eighth portion shown by chain lines. a portion 1008F; the second flow control surface 200F of the second flow control element 20F of the flow control device has a central region 2000F indicated by a chain line in the figure, wherein the central region 2000F is disposed at the second flow control element 20F a second central portion 2111F of the bottom end portion 211F of the second flow control body 21F, and a portion other than the central region 2000F of the second flow control surface 200F is clockwise equally divided into a first region indicated by a chain line 2001F, a second area 2002F, a third area 2003F, a fourth area 2004F, a fifth area 2005F, a sixth area 2006F, a seventh area 2007F and an eighth area 2008F; wherein the first channel 101F The first portion 1001F, the second portion 1002F, the third portion 1003F, and the fourth portion 1004F of the first control flow surface 100F extend downward; the second passage 102F is from the first control flow surface 100F Two parts 1002F The fourth channel 104F extends downward from the first portion 1001F, the second portion 1002F, the third portion 1003F, and the fourth portion 1004F of the first control flow surface 100F; the fifth channel 105F The third portion 1003F of the first flow control surface 100F extends downward; the sixth passage 106F extends downward from the first portion 1001F of the first control flow surface 100F; the ninth passage 109F is from the first control flow surface 100F The central portion 1000F extends downward; the tenth passage 1010F extends downward from the fifth portion 1005F, the sixth portion 1006F, the seventh portion 1007F, and the eighth portion 1008F of the first flow control surface 100F; The first H ^ - channel 1011F extends downward from the sixth portion 1006F of the first control flow surface 100F; the thirteenth channel 1013F is from the fifth portion 1005F of the first control flow surface 100F, the sixth portion 1006F, The seventh portion 1007F and the eighth portion 1008F extend downward; the fourteenth channel 1014F extends downward from the seventh portion 1007F of the first control flow surface 100F; the fifteenth channel 1015F is controlled from the first The fifth portion 1005F of the face 100F extends downward; the eighteenth pass 1018F extends upward from the third region 2003F and the fourth region 2004F of the second flow control surface 200F; the third passage 1019F from the third region 2003F of the second flow control surface 200F and the fourth region 2004F Extending upwardly; the twentieth channel 1020F extends upward from a central region 2000F of the second control flow surface 200F; the second H^-channel 1021F extends upward from an eighth region 2008F of the second control flow surface 200F; The twenty-third channel 1023F extends upward from the seventh region 2007F of the second flow control surface 200F.

As shown in FIG. 62B and FIG. 63D, the flow controller according to the seventh preferred embodiment of the present invention further includes a housing 30F, and a first flow control body of the first flow control element 10F of the flow controller. 11F Further comprising a lower end portion 112F extending downward from the top end portion 111F, wherein the outer casing 30F includes a casing body 31F, wherein the casing body 31F is from the lower end of the first flow control body 11F of the first flow control element 10F The portion 112F extends outwardly and upwardly and encloses a first receiving chamber 300F such that the outer casing body 31F is formed with an inner side wall 311F, an outer side wall 312F and an opening upward upper end opening 3001F, wherein the first receiving portion The chamber 300F is in communication with the conductive opening 10181F of the eighteenth passage 1018F, wherein the second flow control element 20F is adapted to be disposed on the first control chamber 300F downwardly and disposed on the first control flow surface 200F. The first control surface of the flow element 10F is 100F

It is to be noted that the outer casing 30F has a first opening 301F, a second opening 302F, a third opening 303F and a fourth opening 304F, wherein the first opening 301F is in communication with the first receiving chamber 300F. The second opening 302F is in communication with the ninth channel 109F of the flow control device; the third opening 303F is respectively connected to the tenth channel 1010F of the flow controller and the first H^-channel 1011F; the fourth opening 304F is respectively associated with The thirteenth channel 1013F of the flow controller, the fourteenth channel 1014F and the fifteenth channel 1015F are in communication. In other words, the ninth passage 109F extends downward from the first flow control surface 100F of the first flow control element 10F and outward from the lower end portion 112F of the first flow control body 11F of the first flow control element 10F. Extending to communicate with the second opening 302F; the tenth channel 1010F and the first H^-channel 1011F respectively extend downward from the first flow control surface 100F of the first flow control element 10F and from the first control flow The lower end portion 112F of the first flow control body 11F of the element 10F extends outwardly to communicate with the third opening 303F; the thirteenth channel 1013F, the fourteenth channel 1014F and the fifteenth channel 1015F are respectively The first flow control surface 100F of the first flow control element 10F extends downwardly and extends outwardly from the lower end portion 112F of the first flow control body 11F of the first flow control element 10F to communicate with the fourth opening 304F. Preferably, the lower end portion 112F of the first flow control body 11F of the first flow control element 10F is integrally formed with the inner side wall 311F of the outer casing body 31F of the outer casing 30F. More preferably, the first opening 301F, the second opening 302F, the third opening 303F and the fourth opening 304F of the outer casing 30F are respectively disposed on the outer casing body 31F of the outer casing 30F.

Optionally, the first opening 301F is in communication with the first receiving chamber 300F, and the second opening 302F is in communication with the ninth channel 109F of the flow controller; the third opening 303F and the tenth of the flow controller The passage 1010F is in communication; the fourth opening 304F is in communication with the thirteenth passage 1013F of the flow control, wherein the first H^-channel 1011F is in communication with the tenth passage 1010F; the fourteenth passage 1014F and the first The fifteen channel 1015F is in communication with the thirteenth channel 1013F, respectively. That is, the first H ^ a channel 1011F is in communication with the tenth channel 1010F; the fourteenth channel 1014F and the fifteenth channel 1015F are respectively connected to the thirteenth channel 1013F; the ninth channel 109F is from the first flow control component The first flow control surface 100F of the 10F extends downwardly and extends outward from the lower end portion 112F of the first flow control body 11F of the first flow control element 10F to communicate with the second opening 302F; the tenth passage 1010F Extending downward from the first flow control surface 100F of the first flow control element 10F and extending outward from the lower end portion 112F of the first flow control body 11F of the first flow control element 10F to be connected to the third opening 303F The thirteenth channel 1013F extends downward from the first flow control surface 100F of the first flow control element 10F and extends outward from the lower end portion 112F of the first flow control body 11F of the first flow control element 10F. It is in communication with the fourth opening 304F.

As shown in FIG. 62F and FIG. 63E, the flow controller further includes a wear-resistant member 40F disposed between the first flow control element 10F and the second flow control element 20F, wherein the wear-resistant element 40F has a wear-resistant body 41F, wherein the wear-resistant body 41F has a wear-resistant surface 410F adapted to be in contact with the second flow control surface 200F of the second flow control body 21F, wherein the wear-resistant surface 410F is wear-resistant, Therefore, the friction generated by the second flow control body 21F of the second flow control element 20F relative to the first flow control body 11F of the first flow control element 10F can be reduced to extend the service life of the flow control device. Further, the size and shape of the wear-resistant element 40F is designed and formed according to the first flow control surface 100F of the first flow control element 10F of the flow control device, wherein the wear-resistant element 40F has a first interface 401F, a first The second interface 402F, a fourth interface 404F, a fifth interface 405F, a sixth interface 406F, a ninth interface 409F, a tenth interface 4010F, a H-th interface 4011F, a thirteenth interface 4013F, a The fourteenth interface 4014F and a fifteenth interface 4015F, wherein the first interface 401F, the second interface 402F, the fourth interface 404F, the fifth interface 405F, the sixth interface 406F, the ninth interface 409F, The tenth interface 4010F, the H-th interface 4011F, the thirteenth interface 4013F, the fourteenth interface 4014F, and the fifteenth interface 4015F penetrate the wear-resistant body 41F of the wear-resistant component 40F up and down and sequentially The first channel 101F of the flow controller, the second channel 102F, the fourth channel 104F, the fifth channel 105F, the sixth channel 106F, the ninth channel 109F, the tenth channel 1010F, the Hth ^One channel 1011F, The thirteenth channel 1013F, the fourteenth channel 1014F and the fifteenth channel 1015F are one-to-one. That is, the first interface 401F, the second interface 402F, the fourth interface 404F, the fifth interface 405F, the sixth interface 406F, the ninth interface 409F, the tenth interface 4010F, the Hth ^ - interface 4011F, the thirteenth interface 4013F, the fourteenth interface The 4014F and the fifteenth interface 4015F are configured to enable the first interface 401F to communicate with the eighteenth channel 1018F of the flow controller and the first channel 101F when the current controller is in the first working position, the fourth The interface 404F can communicate with the nineteenth channel 1019F and the fourth channel 104F, the ninth interface 409F can communicate with the twentieth channel 1020F and the ninth channel 109F; when the current controller is in the second working position, the first The interface 401F can communicate with the eighteenth channel 1018F of the current controller and the first channel 101F, and the fourth interface 404F can communicate with the nineteenth channel 1019F and the fourth channel 104F, and the ninth interface 409F can communicate with the twentieth The channel 1020F and the ninth channel 109F, the fourteenth interface 4014F can communicate with the second H^-channel 1021F and the fourteenth channel 1014F, and the eleventh interface 4011F can communicate with the second thirteen channel 1023F and the first H ^ - channel 1011F; when the current controller is in the third working position, the first interface 401F can communicate with the eighteenth channel 1018F of the current controller and the first channel 101F, and the fourth interface 404F can communicate with the first Nineteen channel 1019F and fourth channel 104F, the ninth The port 409F can communicate with the twentieth channel 1020F and the ninth channel 109F, and the H-th interface 4011F can communicate with the second H^-channel 1021F and the H-th channel 101 IF, and the fifteenth interface 4015F can Connecting the twenty-third channel 1023F and the fifteenth channel 1015F; when the current controller is in the fourth working position, the first interface 401F can communicate with the eighteenth channel 1018F and the first channel 101F of the flow controller The tenth interface 4010F can communicate with the eighteenth channel 1018F and the tenth channel 1010F of the flow controller, and the fourth interface 404F can communicate with the nineteenth channel 1019F and the fourth channel 104F, and the thirteenth interface 4013F can Connecting the nineteenth channel 1019F and the thirteenth channel 1013F, the ninth interface 409F can communicate with the twentieth channel 1020F and the ninth channel 109F; when the current controller is in the fifth working position, the tenth interface 4010F The eighteenth channel 1018F and the tenth channel 1010F that can communicate with the flow controller, the thirteenth interface 4013F can communicate with the nineteenth channel 1019F and the thirteenth channel 1013F, and the ninth interface 409F can communicate with the twentieth Channel 1020F and ninth channel 109F; when the flow controller is In the sixth working position, the tenth interface 4010F can communicate with the eighteenth channel 1018F and the tenth channel 1010F of the flow controller, and the thirteenth interface 4013F can communicate with the nineteenth channel 1019F and the thirteenth channel 1013F, The ninth interface 409F can communicate with the twentieth channel 1020F and the ninth channel 109F, and the fifth interface 405F can communicate with the second H^-channel 1021F and the fifth channel 105F, and the second interface 402F can communicate with the first interface Twenty-three channels 1023F and the second channel 102F; when the current controller is in the seventh working position, the tenth interface 4010F can communicate with the eighteenth channel 1018F and the tenth channel 1010F of the flow controller, the tenth The three-port 4013F is capable of connecting the nineteenth channel 1019F and the thirteenth channel 1013F, the ninth interface 409F can communicate with the twentieth channel 1020F and the ninth channel 109F, and the second interface 402F can communicate with the second H^-channel 1021F and the second channel 102F, and the sixth interface 406F can communicate with The second channel 1023F and the sixth channel 106F; when the current controller is in the eighth working position, the first interface 401F can communicate with the eighteenth channel 1018F of the current controller and the first channel 101F, The tenth interface 4010F can communicate with the eighteenth channel 1018F and the tenth channel 1010F of the flow controller, and the fourth interface 404F can communicate with the nineteenth channel 1019F and the fourth channel 104F, and the thirteenth interface 4013F can communicate with the a nineteenth channel 1019F and a thirteenth channel 1013F, the ninth interface 409F being capable of communicating with the twentieth channel 1020F and the ninth channel 109F; preferably, when the current controller is in the first working position, the fourteenth The interface 4014F can communicate with the twenty-third channel 1023F and the fourteenth channel 1014F; when the current controller is in the fourth working position, the fifteenth interface 4015F can communicate with the second H^-channel 1021F and the first Fifteen channel 1015F; when the current controller is in the fifth work When the bit is in position, the fifth interface 405F can communicate with the second thirteenth channel 1023F and the fifth channel 105F; when the current controller is in the eighth working position, the sixth interface 406F can communicate with the second H^-channel 1021F and the sixth passage 106F; preferably, when the wear element 40F is disposed between the first flow control element 10F and the second flow control element 20F of the flow control device, the wear resistant element 40F does not occur. The rotation of the first flow control body 11F with respect to the first flow control element 10F. More preferably, the wear element 40F has a wear resistant surface 410F that has been smoothed to reduce its roughness.

As shown in FIG. 62B of the accompanying drawings, the flow controller further includes a flow guiding element 50F, wherein the flow guiding element 50F includes a guiding body 51F, wherein the guiding body 51F is surrounded by a first guiding channel 510F. The guide body 51F of the flow guiding element 50F extends upward from the second flow control body 21F of the second flow control element 20F, and the first flow guiding channel 510F of the flow guiding element 50F and the current regulating device Twenty-three channels 1023F are connected.

As shown in Figure 62B of the drawings, the flow controller further includes a drive member 60F extending upward from the second flow control body 21F of the second flow control member 20F and a sealing member 70F extending upward from the drive member 60F. The driving element 60F is adapted to drive the second flow control body 21F of the second flow control element 20F of the flow controller to rotate relative to the first flow control body 11F of the first flow control element 10F; wherein the sealing element 70F The inner side wall 311F of the outer casing 30F is adapted to seal the first accommodating chamber 300F, thereby preventing fluid in the first accommodating chamber 300F from flowing out from the upper end opening 3001F of the first accommodating chamber 300F. Preferably, the sealing element 70F and the driving element 60F The second contact flow body 21F is in contact with and is adapted to hold the drive element 60F in position to maintain the second flow control element 20F. Preferably, the drive element 60F of the flow control device is integrally formed with the flow guiding body 51F of the flow guiding element 50F.

As shown in FIG. 62H of the accompanying drawings, the flow controller according to the seventh preferred embodiment of the present invention further includes a flow blocking member 80F extending downward from the first flow control body 11F of the first flow control element 10F, and The outer casing body 31F of the outer casing 30F extends outwardly and downwardly from the lower end portion 112F of the first flow control body 11F of the first flow control element 10F, wherein the flow blocking member 80F forms a partition with the outer casing body 31F. The first flow guiding chamber 801F between the flow element 80F and the outer casing body 31F, and the flow blocking element 80F form a second flow guiding chamber 802F, wherein the first channel 101F and the second channel 102F of the flow controller are The first flow control surface 100F of the first flow control element 10F extends downwardly and communicates with the first flow guiding chamber 801F; the fourth channel 104F, the fifth channel 105F and the sixth channel 106F of the flow controller are The first flow control surface 100F of the first flow control element 10F extends downward and communicates with the second flow guiding chamber 802F, respectively.

Referring to Figure 65 of the drawings, the present invention also provides a water treatment system, wherein the water treatment system includes a flow controller of the present invention and a water treatment unit 90F, wherein the water treatment unit 90F includes a first water treatment component 91F and a second water treatment element 92F, wherein the first water treatment element 91F has a first communication opening 911F and a second communication opening 912F, the second water treatment element 92F having a third communication opening 921F and a first a fourth communication opening 922F, wherein the first communication opening 911F of the first water treatment component 91F is in communication with the first flow guiding chamber 801F of the flow controller; the second communication opening 912F of the first water treatment component 91F and The second flow guiding chamber 802F of the flow control device is in communication; the third communication opening 921F of the second water treatment component 92F is in communication with the third opening 303F of the flow controller; the second water treatment component 92F The fourth communication opening 922F is in communication with the fourth opening 304F of the flow controller.

Further, the first water treatment element 91F has a first water treatment portion 913F in which water to be treated flows from the first communication opening 911F of the first water treatment element 91F and from the first water treatment element 91F. When the second communication opening 912F flows out, or flows from the second communication opening 912F of the first water treatment element 91F and flows out from the first communication opening 911F of the first water treatment element 91F, the water to be treated is first The first water treatment portion 913F of the water treatment element 91F processes and obtains the treated water. Similarly, the second water treatment element 92F has a second water treatment portion 923F in which water to be treated flows from the third communication opening 921F of the second water treatment element 92F. And flowing out from the fourth communication opening 922F of the second water treatment element 92F, or from the fourth communication opening 922F of the second water treatment element 92F and from the third communication opening 921F of the second water treatment element 92F Upon exiting, the water to be treated is treated by the second water treatment portion 923F of the second water treatment element 92F and the treated water is obtained.

It is to be noted that the first water treatment portion 913F of the first water treatment element 91F and the second water treatment portion 923F of the second water treatment element 92F of the water treatment unit 90F are each made of at least one water treatment material. If it is made of one or more of quartz sand, activated carbon, resin, stereoelastic filler, honeycomb filler or filter, the treated water is treated to remove impurities in the water to be treated or components not desired by the user.

As shown in Figure 64A of the accompanying drawings, when the flow controller of the water treatment system is in the first working position, the water to be treated is adapted to flow into the first portion of the outer casing 30F through the first opening 301F of the outer casing 30F of the flow control device. The accommodating chamber 300F flows into the first passage 101F through the conduction opening 10181F of the eighteenth passage 1018F, and then the water to be treated passes through the first flow guiding chamber 801F and the first water treatment of the water treatment unit 90F of the water treatment system. The first communication opening 911F of the element 91F flows into the first water treatment element 91F and passes through the treatment of the first water treatment unit 913F provided in the first water treatment element 91F, thereby obtaining treated water, and the treated water is suitable Under the pressure, the second communication opening 912F of the first water treatment element 91F flows into the second flow guiding chamber 802F of the flow controller, and then flows into the fourth passage 104F of the flow controller, and then passes through the flow controller. The nineteenth passage 1019F flows into the twentieth channel 1020F of the flow controller, and then flows into the ninth passage 109F through the twentieth passage 1020F, and finally flows out through the second opening 302F of the outer casing 30F of the flow controller to For the user to use; as shown in Figure 64B of the accompanying drawings, When the flow control device of the water treatment system is in the second working position, the water to be treated is adapted to flow into the first accommodation chamber 300F of the outer casing 30F through the first opening 301F of the outer casing 30F of the flow control device and pass the eighteenth The conduction opening 10181F of the passage 1018F flows into the first passage 101F, and then the water to be treated flows in through the first flow guiding chamber 801F and the first communication opening 911F of the first water treatment element 91F of the water treatment unit 90F of the water treatment system. After the first water treatment element 91F is processed by the first water treatment unit 913F provided in the first water treatment element 91F, the treated water is obtained, and the treated water passes through the first water under a suitable pressure. The second communication opening 912F of the processing element 91F flows into the second flow guiding chamber 802F of the flow controller, then flows into the fourth passage 104F of the flow controller, and then flows into the control through the nineteenth passage 1019F of the flow controller. a twentieth channel 1020F of the flow device, and then flows into the ninth channel 109F and the second H^-channel 1021F via the twentieth channel 1020F, respectively The processed water flowing into the ninth passage 109F flows out through the second opening 302F of the outer casing 30F of the flow controller for the user to use, and the treated water flowing into the second eleventh passage 1021F flows into the flow control device. The fourteenth channel 1014F and the thirteenth channel 1013F then flow to the second water treatment element 92F via the fourth opening 304F of the outer casing 30F of the flow control, and pass through the fourth communication opening of the second water treatment element 92F. 922F flows into the second water treatment element 92F, so that the treated water can backwash the second water treatment part 923F of the second water treatment element 92F, and the waste liquid generated by the backwashing treatment is treated by the second water. The third communication opening 921F of the component 92F flows into the third opening 303F of the outer casing 30F of the flow controller, and then flows into the tenth passage 1010F and the eleventh passage 1011F of the flow controller, and finally passes through the second thirteen passage 1023F. And flowing out of the first flow guiding channel 510F of the flow guiding element 50F; as shown in FIG. 64C of the drawing, when the flow controller of the water treatment system is in the third working position, the water to be treated is adapted to pass through the flow controller The first opening 301F of the outer casing 30F flows into the outer The first accommodating chamber 300F of 30F flows into the first passage 101F through the conduction opening 10181F of the eighteenth passage 1018F, and then the water to be treated passes through the first flow guiding chamber 801F and the water treatment unit 90F of the water treatment system. The first communication opening 911F of the first water treatment element 91F flows into the first water treatment element 91F and passes through the treatment of the first water treatment unit 913F provided in the first water treatment element 91F, thereby obtaining treated water. The rear water flows into the second flow guiding chamber 802F of the flow controller through the second communication opening 912F of the first water treatment element 91F under a suitable pressure, and then flows into the fourth passage 104F of the flow controller, and then passes through the fourth passage 104F of the flow controller. The nineteenth channel 1019F of the flow controller flows into the twentieth channel 1020F of the flow controller, and then flows into the ninth channel 109F and the second H^-channel 1021F through the twentieth channel 1020F, respectively. The treated water of the ninth passage 109F flows out through the second opening 302F of the outer casing 30F of the flow controller for the user to use, and the treated water flowing into the second eleventh passage 1021F flows into the second portion of the flow control device. - channel 1011F and tenth channel 1010F, then The third opening 303F of the outer casing 30F of the flow controller flows to the second water treatment element 92F, and flows into the second water treatment element 92F via the third communication opening 921F of the second water treatment element 92F, thereby causing the treatment The back water can perform a positive rinsing treatment on the second water treatment portion 923F of the second water treatment element 92F, and the waste liquid generated in the rinsing process flows into the flow controller through the fourth communication opening 922F of the second water treatment element 92F. The fourth opening 304F of the outer casing 30F then flows into the thirteenth passage 1013F and the fifteenth passage 1015F of the flow control device, and finally through the second thirteenth passage 1023F and the first flow guiding passage 510F of the flow guiding member 50F. Flowing out; as shown in Figure 64D of the accompanying drawings, when the flow controller of the water treatment system is in the fourth working position, the water to be treated is adapted to pass the flow control The first opening 301F of the outer casing 30F flows into the first receiving chamber 300F of the outer casing 30F and flows into the first passage 101F and the tenth passage 1010F through the conducting opening 10181F of the eighteenth passage 1018F, respectively, into the first passage. The water to be treated of 101F flows into the first water treatment element 91F through the first flow guiding chamber 801F and the first communication opening 911F of the first water treatment element 91F of the water treatment unit 90F of the water treatment system, and is provided in the first After the treatment of the first water treatment portion 913F in the water treatment element 91F, the treated water is obtained, and the treated water flows into the control flow through the second communication opening 912F of the first water treatment element 91F under a suitable pressure. The second flow guiding chamber 802F of the device then flows into the fourth passage 104F of the flow controller, and then flows into the nineteenth passage 1019F of the flow controller; the water to be treated flowing into the tenth passage 1010F then passes through the outer casing 30F The third opening 303F and the third communication opening 921F of the second water treatment element 92F of the water treatment unit 90F of the water treatment system flow into the second water treatment element 92F and pass through the second water treatment element 92F. Second water treatment department 923F After the treatment, the treated water is obtained, and the treated water flows into the fourth opening 304F of the outer casing 30F through the fourth communication opening 922F of the second water treatment element 92F under a suitable pressure, and then flows into the flow controller. The thirteenth channel 1013F, and then flows into the nineteenth channel 1019F of the flow controller, merges with the treated water from the fourth channel 104F flowing into the nineteenth channel 1019F of the flow controller, and passes through the flow controller The twentieth channel 1020F flows into the ninth channel 109F and finally flows out through the second opening 302F of the outer casing 30F of the flow controller for use by the user; as shown in FIG. 64E of the drawing, when the water treatment system When the flow controller is in the fifth working position, the water to be treated is adapted to flow into the first receiving chamber 300F of the outer casing 30F through the first opening 301F of the outer casing 30F of the current control device and pass through the conducting opening of the eighteenth passage 1018F. 10181F flows into the tenth passage 1010F, and then the water to be treated flows into the second water treatment through the third opening 303F of the outer casing 30F and the third communication opening 921F of the second water treatment element 92F of the water treatment unit 90F of the water treatment system. Element 92F is disposed in the After the treatment of the second water treatment unit 923F in the second water treatment element 92F, the treated water is obtained, and the treated water flows into the outer casing 30F through the fourth communication opening 922F of the second water treatment element 92F under a suitable pressure. The fourth opening 304F then flows into the thirteenth channel 1013F of the flow controller, and then flows into the twentieth channel 1020F of the flow controller through the nineteenth channel 1019F of the flow controller, and then passes through the twentieth channel The passage 1020F flows into the ninth passage 109F and finally flows out through the second opening 302F of the outer casing 30F of the flow control for the user to use; as shown in Fig. 64F of the drawing, when the flow control device of the water treatment system is at In the sixth working position, the water to be treated is adapted to flow into the first receiving chamber 300F of the outer casing 30F through the first opening 301F of the outer casing 30F of the flow control device and pass the The conductive opening 10181F of the eighteenth channel 1018F flows into the tenth channel 1010F, and then the water to be treated passes through the third opening 303F of the outer casing 30F and the third water treatment element 92F of the water treatment unit 90F of the water treatment system. After the communication opening 921F flows into the second water treatment element 92F and passes through the treatment of the second water treatment unit 923F provided in the second water treatment element 92F, the treated water is obtained, and the treated water is subjected to a suitable pressure. The fourth communication opening 922F of the second water treatment element 92F flows into the fourth opening 304F of the outer casing 30F, then flows into the thirteenth passage 1013F of the flow controller, and then flows through the nineteenth passage 1019F of the flow controller. The twentieth channel 1020F of the flow controller flows into the ninth channel 109F and the second H^-channel 1021F through the twentieth channel 1020F, respectively, wherein the processed water flowing into the ninth channel 109F passes through the control The second opening 302F of the outer casing 30F of the flow device flows out for the user to use, and the treated water flowing into the second eleventh channel 1021F flows into the fifth channel 105F and the fourth channel 104F of the flow controller, and then passes through the first Two diversion chamber 802F and The second communication opening 912F of the first water treatment element 91F of the water treatment unit 90F of the water treatment system flows into the first water treatment element 91F, so that the treated water can be the first water to the first water treatment element 91F. The processing unit 913F performs a backwashing process, and the waste liquid generated by the backwashing process flows into the first flow guiding chamber 801F through the first communication opening 911F of the first water treatment element 91F, and then flows into the first channel 101F of the flow controller. And the second passage 102F finally flows out through the second thirteenth passage 1023F and the first flow guiding passage 510F of the flow guiding member 50F; as shown in FIG. 64G of the drawing, when the flow control device of the water treatment system is in the first At the seven working positions, the water to be treated is adapted to flow into the first accommodating chamber 300F of the outer casing 30F through the first opening 301F of the outer casing 30F of the flow controller and flow into the tenth through the conduction opening 10181F of the eighteenth passage 1018F. The passage 1010F, then the water to be treated flows into the second water treatment element 92F through the third opening 303F of the outer casing 30F and the third communication opening 921F of the second water treatment element 92F of the water treatment unit 90F of the water treatment system. For the second water treatment After the treatment of the second water treatment portion 923F in the element 92F, the treated water is obtained, and the treated water flows into the fourth portion of the outer casing 30F through the fourth communication opening 922F of the second water treatment element 92F under a suitable pressure. The opening 304F then flows into the thirteenth channel 1013F of the flow controller, and then flows into the twentieth channel 1020F of the flow controller through the nineteenth channel 1019F of the flow controller, and then passes through the twentieth channel 1020F respectively. Flowing into the ninth passage 109F and the second eleventh passage 1021F, wherein the treated water flowing into the ninth passage 109F flows out through the second opening 302F of the outer casing 30F of the flow controller for use by the user, flowing into the first The treated water of the twenty-one channel 1021F flows into the second channel 102F of the flow controller and the first channel 101F, and then passes through the first guide The flow chamber 801F and the first communication opening 911F of the first water treatment element 91F of the water treatment unit 90F of the water treatment system flow into the first water treatment element 91F, so that the treated water can be the first water treatment element 91F The first water treatment unit 913F performs a positive flushing process, and the waste liquid generated by the positive flushing process flows into the second flow guiding chamber 802F through the second communication opening 912F of the first water treatment component 91F, and then flows into the flow control device. The fourth channel 104F and the sixth channel 106F finally flow out through the second thirteenth channel 1023F and the first flow guiding channel 510F of the flow guiding element 50F; as shown in FIG. 64H of the drawing, when the water treatment system is controlled When the flow device is in the eighth working position, the water to be treated is adapted to flow into the first receiving chamber 300F of the outer casing 30F through the first opening 301F of the outer casing 30F of the flow control device and pass through the opening opening 10181F of the eighteenth passage 1018F. Flowing into the first passage 101F and the tenth passage 1010F, respectively, the water to be treated flowing into the first passage 101F passes through the first flow guiding chamber 801F and the first water treatment element 91F of the water treatment unit 90F of the water treatment system a communication opening 911F flows into the After the water treatment element 91F is processed by the first water treatment unit 913F provided in the first water treatment element 91F, the treated water is obtained, and the treated water passes through the first water treatment element under a suitable pressure. The second communication opening 912F of the 91F flows into the second flow guiding chamber 802F of the flow controller, then flows into the fourth passage 104F of the flow controller, and then flows into the nineteenth passage 1019F of the flow controller; The water to be treated of the passage 1010F then flows into the second water treatment element 92F through the third opening 303F of the outer casing 30F and the third communication opening 921F of the second water treatment element 92F of the water treatment unit 90F of the water treatment system. After the treatment of the second water treatment portion 923F in the second water treatment element 92F, the treated water is obtained, and the treated water flows under the appropriate pressure through the fourth communication opening 922F of the second water treatment element 92F. The fourth opening 304F of the outer casing 30F then flows into the thirteenth passage 1013F of the flow controller, and then flows into the nineteenth passage 1019F of the flow controller, and the flow from the fourth passage 104F into the flow controller. The 19th channel of the 19th 19F The water merges and flows into the ninth passage 109F through the twentieth channel 1020F of the flow controller, and finally flows out through the second opening 302F of the outer casing 30F of the flow controller for the user to use.

It is worth noting that the water treatment system of the present invention uses two water treatment elements, but only one flow control device is needed, so that one of the water treatment elements can be treated with water to be treated and the treated water can be continuously supplied to the user. Another water treatment element is regenerated, and the two water treatment elements can be switched to each other. At the same time, since the water treatment system of the present invention only needs to use one flow controller, the difficulty of automatic control of the water treatment system is greatly reduced.

So far, the object of the present invention can be fully and effectively completed, and the user can adjust the water of the present invention. Positioning the second flow control element 20 of the flow control device of the system relative to the first flow control element 10 such that the flow control device is in different working positions to adjust and control the working state of the water treatment system, Therefore, the user can realize the flow control of the water to be treated, the treated water and the wastewater generated by the backwashing of the water treatment system of the present invention through a flow controller of the present invention.

It will be understood that the water flow herein is merely illustrative of the invention and to assist those skilled in the art in understanding the invention, which refers to various fluids including, but not limited to, water flow; the water herein is for example only. The invention is described and assisted by those skilled in the art in that it refers to various liquid materials and various gaseous materials including, but not limited to, water, and thus the water and/or water streams referred to herein are for illustrative purposes only. The invention is illustrated without limiting the invention. At the same time, the flow controller of the present invention is suitable for flow control of various fluids including, but not limited to, water flow, and the water treatment system of the present invention can be used for the treatment of various fluids including, but not limited to, various streams of water.

Those skilled in the art will appreciate that the embodiments of the invention, which are illustrated in the drawings and described above, are merely illustrative and not limiting.

It can thus be seen that the object of the invention can be fully and efficiently accomplished. The embodiment for explaining the function and structural principle of the present invention has been fully described and described, and the present invention is not limited by the modifications based on the principles of the embodiments. Accordingly, the present invention includes all modifications that come within the scope and spirit of the appended claims.

Claims

claims

1. A flow controller, characterized in that it includes:

A first flow control element and a second flow control element rotatably provided on the first flow control element, wherein the first flow control element includes a first flow control body, and the first flow control body It includes a top end portion, wherein the top end portion forms a first flow control surface; the second flow control element includes a second flow control body, and the second flow control body has a bottom end portion and a first flow control surface. The bottom end portion extends upward and the high end portion forms a second flow control surface; wherein the second flow control surface of the second flow control element is adapted to be rotatably disposed on the first control surface. The first flow control surface of the flow element, wherein the flow control device has a first channel, a second channel, a third channel, a fourth channel, a fifth channel, a sixth channel, and a seventh channel , an eighth channel, a ninth channel, a tenth channel, an eleventh channel, a twelfth channel, a thirteenth channel, a fourteenth channel, a fifteenth channel, a sixteenth channel channel, a seventeenth channel, an eighteenth channel, a nineteenth channel, a twentieth channel, a twenty-first channel, a twenty-second channel and a twenty-third channel, wherein said The first channel, the second channel, the third channel, the fourth channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, the ninth channel, the tenth channel, the eleventh channel, the twelfth channel, the thirteenth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and The seventeenth channels are respectively provided in the first flow control body of the first flow control element and extend downward from the first flow control surface of the first flow control body of the first flow control element; the tenth channel Eight channels are provided at the bottom end of the second flow control body and extend upward and outward from the second flow control surface of the bottom end of the second flow control body to form a channel that is always in contact with the flow control device. conductive openings connected to the external space; the nineteenth channel, the twentieth channel, the twenty-first channel, the twenty-second channel and the twenty-third channel are respectively located at The bottom end of the second flow control body extends upward from the second flow control surface of the bottom end of the second flow control body, wherein the nineteenth channel and the twenty-first channel are respectively provided. outside the twentieth channel and connected to the twentieth channel respectively.

2. The flow controller according to claim 1, characterized in that, the nineteenth channel, the twentieth channel, the twenty-first channel and the twentieth channel of the flow controller Two channels respectively extend upward from the second flow control surface of the second flow control element to the high end of the second flow control element; The twenty-third channel extends upward from the second flow control surface of the second flow control element and penetrates the second flow control body of the second flow control element, wherein the nineteenth channel Connected to the twentieth channel; The twenty-first channel extends upward and inward from the second flow control surface of the second flow control element, thereby communicating with the twentieth channel.

3. The flow controller according to claim 2, characterized in that, the flow controller has a first working position, a second working position, a third working position, a fourth working position, and a fifth working position. working position, a sixth working position, a seventh working position, an eighth working position, a ninth working position and a tenth working position, wherein when the flow controller is in the first working position, the control The eighteenth channel of the flow device is connected to the first channel, the nineteenth channel is connected to the fourth channel, the twentieth channel is connected to the ninth channel, the twenty-first channel is connected to the The sixteenth channel is connected to each other, the twenty-second channel is connected to the seventeenth channel and the fourteenth channel respectively, and the twenty-third channel is connected to the eleventh channel; when When the flow controller is in the second working position, the 18th channel of the flow controller is connected to the first channel, the 19th channel is connected to the fourth channel, and the 20th channel is connected to the 20th channel. Nine channels are connected, and the twenty-first channel is connected to the seventeenth channel; when the flow controller is in the third working position, the eighteenth channel of the flow controller is connected to the first channel. The nineteenth channel is connected to the fourth channel, the twentieth channel is connected to the ninth channel, the twenty-first channel is connected to the fourteenth channel, the twentieth channel is connected to The twelfth channel of the three channels is connected; when the flow controller is in the fourth working position, the eighteenth channel of the flow controller is connected to the first channel, and the nineteenth channel is connected to the fourth The channels are connected, the twentieth channel is connected with the ninth channel, the twenty-first channel is connected with the eleventh channel, the twenty-third channel is connected with the fifteenth channel ; When the flow controller is in the fifth working position, the eighteenth channel of the flow controller is connected to the first channel, the nineteenth channel is connected to the fourth channel, and the twentieth channel Connected to the ninth channel; when the flow controller is in the sixth working position, the eighteenth channel of the flow controller is connected to the tenth channel, and the nineteenth channel is connected to the thirteenth channel , the twentieth channel is connected to the ninth channel, the twenty-first channel is connected to the seventh channel, the twenty-second channel is connected to the fifth channel and the eighth channel respectively are connected, the twenty-third channel is connected to the second channel; when the flow controller is in the seventh working position, the eighteenth channel of the flow controller is connected to the tenth channel, so The nineteenth channel is connected to the thirteenth channel, the twentieth channel is connected to the ninth channel, the twenty-first channel is connected to the eighth channel; when the flow controller is in the At eight working positions, the flow controller's The eighteenth channel is connected to the tenth channel, the nineteenth channel is connected to the thirteenth channel, the twentieth channel is connected to the ninth channel, the twenty-first channel is connected to the fifth channel are connected, the twenty-third channel is connected to the third channel; when the flow controller is in the ninth working position, the eighteenth channel of the flow controller is connected to the tenth channel, so The nineteenth channel is connected to the thirteenth channel, the twentieth channel is connected to the ninth channel, the twenty-first channel is connected to the second channel, the twenty-third channel is connected to The sixth channel is connected; when the flow controller is in the tenth working position, the eighteenth channel of the flow controller is connected to the tenth channel, and the nineteenth channel is connected to the thirteenth channel The twentieth channel is connected to the ninth channel.

4. The flow controller according to claim 3, characterized in that when the flow controller is in the first working position, the second channel, the third channel, the fifth channel, the The sixth channel, the seventh channel, the eighth channel, the tenth channel, the twelfth channel, the thirteenth channel and the fifteenth channel are respectively controlled by the flow controller. The second flow control body of the second flow control element is blocked; when the flow controller is in the second working position, the second channel, the third channel, the fifth channel, the sixth channel, The seventh channel, the eighth channel, the tenth channel, the twelfth channel, the thirteenth channel, the fifteenth channel and the sixteenth channel are respectively controlled by the The second flow control body of the second flow control element of the flow controller is blocked, and the twenty-third channel is blocked by the first flow control body of the first flow control element of the flow controller; when the flow controller is in In the third working position, the second channel, the third channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, the tenth channel, the The thirteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel are respectively blocked by the second flow control body of the second flow control element of the flow controller; when the control When the flow device is in the fourth working position, the second channel, the third channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, and the tenth channel , the thirteenth channel, the fourteenth channel, the sixteenth channel and the seventeenth channel are respectively blocked by the second flow control body of the second flow control element of the flow controller; when When the flow controller is in the fifth working position, the second channel, the third channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, the The tenth channel, the eleventh channel, the thirteenth channel, the fourteenth channel, the sixteenth channel and the seventeenth channel are respectively controlled by the second flow control device of the flow controller. The second flow control body of the component is blocked, and the twenty-first channel and the twenty-third channel are respectively blocked by the first flow control body of the first flow control component of the flow control device; when the flow control When the controller is in the sixth working position, the first channel, the third channel, the The fourth channel, the sixth channel, the eleventh channel, the twelfth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel The channels are respectively blocked by the second flow control body of the second flow control element of the flow controller; when the flow controller is in the seventh working position, the first channel, the third channel, the third channel four channels, the sixth channel, the seventh channel, the eleventh channel, the twelfth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and The seventeenth channel is respectively blocked by the second flow control body of the second flow control element of the flow controller, and the twenty-third channel is blocked by the first control body of the first flow control element of the flow controller. The flow body is blocked; when the flow controller is in the eighth working position, the first channel, the fourth channel, the sixth channel, the seventh channel, the eighth channel, the third channel The eleventh channel, the twelfth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel are respectively controlled by the second flow controller of the flow controller. The second flow control body of the component is blocked; when the flow controller is in the ninth working position, the first channel, the fourth channel, the fifth channel, the seventh channel, the eighth channel The channel, the eleventh channel, the twelfth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel are respectively controlled by the flow controller The second flow control body of the second flow control element is blocked; when the flow controller is in the tenth working position, the first channel, the second channel, the fourth channel, and the fifth channel , the seventh channel, the eighth channel, the eleventh channel, the twelfth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the The seventeenth channel is respectively blocked by the second flow control body of the second flow control element of the flow controller, and the twenty-first channel and the twenty-third channel are respectively blocked by the first flow control element of the flow controller. The first flow control body of the flow control element is blocked.

5. The flow controller according to claim 4, wherein when the flow controller is in the second working position, the twenty-second channel is connected to the eleventh channel and the tenth channel respectively. The four channels are connected; when the flow controller is in the third working position, the twenty-second channel is connected with the eleventh channel; when the flow controller is in the fourth working position, the The twenty-second channel is connected to the twelfth channel; when the flow controller is in the fifth working position, the twenty-second channel is connected to the twelfth channel and the fifteenth channel respectively. connected; when the flow controller is in the seventh working position, the twenty-second channel is connected to the second channel and the fifth channel respectively; when the flow controller is in the eighth working position When the flow controller is in the ninth working position, the twenty-second channel is connected to the third channel; When the flow controller is in the ninth working position, the twenty-second channel is connected to the third channel; When the flow controller is in the tenth working position, the twenty-second channel is connected to the third channel and the third channel respectively. Six channels are connected.

6. The flow controller according to claim 5, wherein the first channel of the flow controller is connected to the fourth channel, the fifth channel, the sixth channel, and the seventh channel respectively. channel, the eighth channel, the ninth channel, the tenth channel, the eleventh channel, the twelfth channel, the thirteenth channel, the fourteenth channel, the The fifteenth channel, the sixteenth channel and the seventeenth channel are spaced apart from each other on the first flow control body of the first flow control element; the second channel and the fourth channel are respectively , the fifth channel, the sixth channel, the seventh channel, the eighth channel, the ninth channel, the tenth channel, the eleventh channel, the twelfth channel , the thirteenth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel are spaced apart from each other on the first flow control element. a flow control body; the third channel is respectively connected with the fourth channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, the ninth channel, the The tenth channel, the eleventh channel, the twelfth channel, the thirteenth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the tenth channel Seven channels are spaced apart from each other on the first flow control body of the first flow control element; the fourth channel is respectively connected with the seventh channel, the eighth channel, the ninth channel, and the third channel. The tenth channel, the eleventh channel, the twelfth channel, the thirteenth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel Channels are spaced apart from the first flow control body of the first flow control element; the fifth channel is respectively connected with the seventh channel, the eighth channel, the ninth channel, and the tenth channel. channel, the eleventh channel, the twelfth channel, the thirteenth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel The first flow control body is spaced apart from the first flow control element; the sixth channel is respectively connected with the seventh channel, the eighth channel, the ninth channel, and the tenth channel , the eleventh channel, the twelfth channel, the thirteenth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel. The first flow control body is spaced apart from the first flow control element; the seventh channel is respectively connected with the eighth channel, the ninth channel, the tenth channel, and the eleventh channel , the twelfth channel, the thirteenth channel, the fourteenth channel, the fifteenth channel and the seventeenth channel are spaced apart from each other on the first flow control element. A flow control body; the sixteenth channel is respectively connected with the eighth channel, the ninth channel, the tenth channel, the eleventh channel, the twelfth channel, and the thirteenth channel The channel, the fourteenth channel, the fifteenth channel and the seventeenth channel are spaced apart from each other. the first flow control body of the first flow control element; the eighth channel and the ninth channel, the tenth channel, the eleventh channel, the twelfth channel, the tenth channel respectively Three channels, the fourteenth channel and the fifteenth channel are spaced apart from each other on the first flow control body of the first flow control element; the seventeenth channel is respectively connected with the ninth channel, The tenth channel, the eleventh channel, the twelfth channel, the thirteenth channel, the fourteenth channel and the fifteenth channel are spaced apart from each other on the first channel. The first flow control body of the flow control element; the ninth channel and the tenth channel, the eleventh channel, the twelfth channel, the thirteenth channel, and the fourteenth channel respectively The first flow control body of the first flow control element is spaced apart from the fifteenth channel; the tenth channel is respectively connected with the thirteenth channel, the fourteenth channel and the first flow control body. The fifteenth channel is spaced apart from the first flow control body of the first flow control element; the eleventh channel is respectively connected with the thirteenth channel, the fourteenth channel and the tenth channel. Five channels are spaced apart from each other on the first flow control body of the first flow control element; the twelfth channel is respectively connected with the thirteenth channel, the fourteenth channel and the fifteenth channel. The first flow control body is spaced apart from the first flow control element; the eighteenth channel is respectively connected with the nineteenth channel, the twentieth channel, the twenty-first channel, The twenty-second channel and the twenty-third channel are spaced apart from each other on the second flow control body of the second flow control element; the twenty-second channel and the nineteenth channel are respectively , the twentieth channel and the twenty-first channel are spaced apart from each other on the second flow control body of the second flow control element; the twenty-third channel and the nineteenth channel are respectively , the twentieth channel and the twenty-first channel are spaced apart from each other on the second flow control body of the second flow control element; the twenty-second channel and the twenty-third channel The second flow control body is spaced apart from the second flow control element.

7. The flow controller according to claim 6, wherein the top end portion of the first flow control body of the first flow control element of the flow controller includes a first central portion, and a first center portion from the first flow control body. a first middle portion extending outwardly from the first central portion, a first extension portion extending outwardly from the first middle portion and a first edge portion extending outwardly from the first extension portion, and said The bottom end of the second flow control body of the second flow control element includes a second central part, a second middle part extending outwardly from the second central part, and a second middle part extending outwardly from the second middle part. a second extension part and a second edge part extending outward from the second extension part, wherein the first channel and the tenth channel are respectively provided at the first edge part of the top end part; the second channel, the third channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, the eleventh channel, the twelfth channel, the The fourteenth channel, the fifteenth channel, the sixteenth channel and the Seventeen channels are respectively provided in the first extension part of the top part; the fourth channel and the thirteenth channel are respectively provided in the first middle part of the top part; the ninth channel The first central part is provided at the top part; The eighteenth channel is provided at the second edge part of the bottom end part; The nineteenth channel is provided at the second middle part of the bottom end part part; the twentieth channel is provided at the second central part of the bottom end; the twenty-first channel, the twenty-second channel and the twenty-third channel are respectively located at the Two extensions.

8. The flow controller according to claim 7, characterized in that, the first flow control surface of the first flow control element and the second flow control surface of the second flow control element of the flow controller are both circular. , wherein the third channel, the second channel, the fifth channel, the eighth channel, the seventh channel, the fifteenth channel, the twelfth channel, the H-channel, the fourteenth channel, and the The seventeenth channel, the sixteenth channel and the sixth channel are arranged clockwise in this order on the first flow control body of the first flow control element; the twenty-third channel and the twenty-second channel of the flow control device The channel and the twenty-first channel are provided in the second flow control body of the second flow control element clockwise in this order.

9. The flow controller according to claim 8, characterized in that, the first channel, the second channel, the third channel, the fourth channel, the fifth channel, the third channel Six channels, the seventh channel, the eighth channel, the ninth channel, the tenth channel, the eleventh channel, the twelfth channel, the thirteenth channel, the The fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel are all radially provided on the first flow control surface of the first flow control element, and the tenth channel The eight channels, the nineteenth channel, the twentieth channel, the twenty-first channel, the twenty-second channel and the twenty-third channel are respectively located in the radial direction of the The second flow control surface of the second flow control element.

10. The flow controller according to claim 9, wherein the first flow control surface of the first flow control element of the flow controller has a central part, wherein the central part is provided on the first The first central part of the top end of the first flow control body of the flow control element, and the part other than the central part of the first flow control surface is divided clockwise into a first part, a second part, and a first part. three parts, a fourth part, a fifth part, a sixth part, a seventh part, an eighth part, a ninth part, a tenth part, an eleventh part, a twelfth part , a thirteenth part, a fourteenth part, a fifteenth part and a sixteenth part; the second flow control surface of the second flow control element of the flow control device has a central area, wherein the The central area is provided at the second center portion of the bottom end of the second flow control body of the second flow control element, and the second The part outside the central area of the flow control surface is equally divided clockwise into a first area, a second area, a third area, a fourth area, a fifth area, a sixth area, and a seventh area. , an eighth region, a ninth region, a tenth region, an eleventh region, a twelfth region, a thirteenth region, a fourteenth region, a fifteenth region and a sixteenth region area; wherein the first channel is formed from the first part, the second part, the third part, the fourth part, the fifth part and the sixth part of the first flow control surface. The second channel extends downward from the fifth part of the first flow control surface; the third channel extends downward from the third part of the first flow control surface; the third channel extends downward from the third part of the first flow control surface; Four channels are formed from the first part, the second part, the third part, the fourth part, the fifth part, the sixth part, the seventh part of the first flow control surface. part and the eighth part extend downward; the fifth channel extends downward from the sixth part of the first flow control surface; the sixth channel extends downward from the second part of the first flow control surface; Extend downward; The seventh channel extends downward from the eighth part of the first flow control surface; The eighth channel extends downward from the seventh part of the first flow control surface; The ninth channel Extending downward from the central part of the first flow control surface; the tenth channel extends from the ninth part, the tenth part, the eleventh part, and the first flow control surface. The twelfth part, the thirteenth part and the fourteenth part extend downward; the eleventh channel extends downward from the thirteenth part of the first flow control surface; the tenth The second channel extends downward from the eleventh part of the first flow control surface; the thirteenth channel extends downward from the ninth part, the tenth part, and the third part of the first flow control surface. The eleventh part, the twelfth part, the thirteenth part, the fourteenth part, the fifteenth part and the sixteenth part extend downward; the fourteenth channel extends from The fourteenth part of the first flow control surface extends downward; the fifteenth channel extends downward from the tenth part of the first flow control surface; the sixteenth channel extends from the first control surface The sixteenth part of the flow surface extends downward; the seventeenth channel extends downward from the fifteenth part of the first flow control surface; the eighteenth channel extends from all parts of the second flow control surface The fifth area, the sixth area, the seventh area and the eighth area extend upward; the nineteenth channel extends from the fifth area, the sixth area of the second flow control surface area, the seventh area and the eighth area extend upward; the twentieth channel extends upward from the central area of the second flow control surface; the twenty-first channel extends upward from the second flow control surface The 22nd channel extends upward from the 14th area and the 15th area of the second flow control surface; the 23rd channel extends upward from the 16th area of the second flow control surface; The thirteenth area of the second flow control surface extends upward.

11. The flow controller according to claim 10, characterized in that, the flow controller further has There is a first conductive channel and a second conductive channel, wherein the first conductive channel and the second conductive channel are respectively provided on the first flow control body of the first flow control element; wherein the The first conductive channel extends from the seventh channel to the sixteenth channel and connects the seventh channel and the sixteenth channel; the second conductive channel extends from the eighth channel Extend to the seventeenth channel and connect the eighth channel and the seventeenth channel.

12. The flow controller according to claim 11, wherein the first edge portion of the top end of the first flow control body of the first flow control element of the flow controller includes a first outer edge portion and a first conductive portion extending outward from the first outer edge portion; the second edge portion of the bottom end portion of the second flow control body of the second flow control element includes a second outer edge portion; an edge portion and a first sealing portion extending outward from the second outer edge portion, wherein the first channel and the tenth channel are respectively provided on the first side of the first flow control element of the flow control device. The first outer edge of the first edge of the top end of the flow control body; the eighteenth channel is provided on the second end of the bottom end of the second flow control body of the second flow control element The second outer edge portion of the edge portion; the first conductive channel is provided at the first conductive portion of the first edge portion of the top end portion of the first flow control body of the first flow control element of the flow control device. Extending downward from the first flow control surface of the first flow control body of the first flow control element; the second conductive channel is provided on the first flow control body of the first flow control element of the flow control device. The first conductive portion of the first edge portion of the top end extends downward from the first flow control surface of the first flow control body of the first flow control element; wherein when the second flow control element is relative to the first flow control element, When a flow control element rotates, the first sealing portion of the second edge portion of the bottom end of the second flow control body of the second flow control element can separate the first conductive channel and the The second conductive channels are respectively separated from the external space above the first flow control body of the first flow control element of the flow controller.

13. The flow controller according to claim 12, wherein the seventh channel and the sixteenth channel of the flow controller are respectively oriented from the first flow control surface of the first flow control element. Extend downward and extend outward and are respectively connected with the first conductive channel, so that the first conductive channel connects the seventh channel and the sixteenth channel; the eighth channel and The seventeenth channels respectively extend downward and outward from the first flow control surface of the first flow control element and are respectively connected with the second conduction channels, so that the second conduction channels will The eighth channel and the seventeenth channel are connected.

14. The flow controller according to claim 13, wherein the first conductive channel is connected to the second conductive channel, the first channel and the second conductive channel of the current controller respectively. channel, said The third channel, the fourth channel, the fifth channel, the sixth channel, the eighth channel, the ninth channel, the tenth channel, the eleventh channel, the The twelve channels, the thirteenth channel, the fourteenth channel, the fifteenth channel and the seventeenth channel are spaced apart from each other on the first flow control body of the first flow control element. ; The second conduction channel is connected to the first channel, the second channel, the third channel, the fourth channel, the fifth channel, and the sixth channel of the flow controller respectively. channel, the seventh channel, the ninth channel, the tenth channel, the eleventh channel, the twelfth channel, the thirteenth channel, the fourteenth channel, the The fifteenth channel and the sixteenth channel are spaced apart from each other and are provided on the first flow control body of the first flow control element.

15. The flow control device according to claim 1, further comprising a housing, and the first flow control body of the first flow control element of the flow control device further includes a first flow control body from the top end portion. a lower end extending downward, wherein the housing includes a housing body, wherein the housing body extends outwardly and upward from the lower end of the first flow control body of the first flow control element and surrounds a A first accommodation chamber, wherein the first accommodation chamber is connected with the conductive opening of the eighteenth channel.

16. The flow control device according to claim 14, further comprising a housing, and the first flow control body of the first flow control element of the flow control device further includes a first flow control body from the top end portion. a lower end extending downward, wherein the housing includes a housing body, wherein the housing body extends outwardly and upward from the lower end of the first flow control body of the first flow control element and surrounds a A first accommodation chamber, wherein the first accommodation chamber is connected with the conductive opening of the eighteenth channel.

17. The flow controller according to claim 15, wherein the housing has a first opening, a second opening, a third opening, a fourth opening, a fifth opening, and a sixth opening. , wherein the first accommodation chamber is connected with the first opening, and the ninth channel extends downward from the first flow control surface of the first flow control element and from the first flow control surface of the first flow control element. The lower end of the flow control body extends outward to communicate with the second opening; the tenth channel, the eleventh channel and the twelfth channel are respectively from the first flow control element. A flow control surface extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the third opening; the thirteenth channel, the fourteenth channel and The fifteenth channels respectively extend downward from the first flow control surface of the first flow control element and extend outward from the lower end of the first flow control body of the first flow control element to communicate with the first flow control element. The four openings are connected; the seventh channel extends downward from the first flow control surface of the first flow control element and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the fifth opening; the eighth channel extends downward from the first flow control surface of the first flow control element and from the lower end of the first flow control body of the first flow control element Extend outward to communicate with the sixth opening.

18. The flow controller according to claim 16, wherein the housing has a first opening, a second opening, a third opening, a fourth opening, a fifth opening, and a sixth opening. , wherein the first accommodation chamber is connected with the first opening, and the ninth channel extends downward from the first flow control surface of the first flow control element and from the first flow control surface of the first flow control element. The lower end of the flow control body extends outward to communicate with the second opening; the tenth channel, the eleventh channel and the twelfth channel are respectively from the first flow control element. A flow control surface extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the third opening; the thirteenth channel, the fourteenth channel and The fifteenth channels respectively extend downward from the first flow control surface of the first flow control element and extend outward from the lower end of the first flow control body of the first flow control element to communicate with the first flow control element. The four openings are connected; the seventh channel extends downward from the first flow control surface of the first flow control element and extends outward from the lower end of the first flow control body of the first flow control element to communicate with The fifth opening is connected; the eighth channel extends downward from the first flow control surface of the first flow control element and outwards from the lower end of the first flow control body of the first flow control element Extend to communicate with the sixth opening.

19. The flow control device according to claim 15, further comprising a wear-resistant element disposed between the first flow control element and the second flow control element, wherein the wear-resistant element has a Wear-resistant body and a second sealing part, wherein the second sealing part of the wear-resistant element can cover the first conductive channel and the second conductive channel of the flow controller, thereby sealing the third conductive channel. A conductive channel and the second conductive channel are separated from the first receiving chamber of the housing.

20. The flow control device according to claim 18, further comprising a wear-resistant element disposed between the first flow control element and the second flow control element, wherein the wear-resistant element has a Wear-resistant body and a second sealing part, wherein the second sealing part of the wear-resistant element can cover the first conductive channel and the second conductive channel of the flow controller, thereby sealing the third conductive channel. A conductive channel and the second conductive channel are separated from the first receiving chamber of the housing.

21. The flow controller according to claim 20, wherein the size and shape of the wear-resistant element are designed and formed according to the first flow control surface of the first flow control element of the flow controller, wherein the The wear-resistant body of the wear-resistant element has a first interface, a second interface, a third interface, and a A fourth interface, a fifth interface, a sixth interface, a seventh interface, an eighth interface, a ninth interface, a tenth interface, an eleventh interface, a twelfth interface, a thirteenth interface interface, a fourteenth interface, a fifteenth interface, a sixteenth interface and a seventeenth interface, wherein the first interface, the second interface, the third interface and the fourth interface , the fifth interface, the sixth interface, the seventh interface, the eighth interface, the ninth interface, the tenth interface, the eleventh interface, the twelfth interface , the thirteenth interface, the fourteenth interface, the fifteenth interface, the sixteenth interface and the seventeenth interface penetrate the wear-resistant body of the wear-resistant element up and down and are connected with each other in sequence The first channel, the second channel, the third channel, the fourth channel, the fifth channel, the sixth channel, the seventh channel, the The eighth channel, the ninth channel, the tenth channel, the eleventh channel, the twelfth channel, the thirteenth channel, the fourteenth channel, the fifteenth channel , the sixteenth channel and the seventeenth channel correspond one to one.

22. The flow controller according to claim 21, wherein the wear-resistant element is integrally formed with the first flow control body of the first flow control element.

23. The flow controller according to claim 15, further comprising a flow isolation element extending downward from the first flow control body of the first flow control element, and the outer shell body of the outer shell extends downwardly from the first flow control body of the first flow control element. The lower end of the first flow control body of the first flow control element extends downward, wherein the flow isolation element and the housing body form a first gap between the flow isolation element and the housing body. The flow guide chamber, and the flow isolation element form a second flow guide chamber, wherein the first channel, the second channel and the third channel of the flow controller are separated from the first flow control surface of the first flow control element. Extend downward and communicate with the first flow guide chamber respectively; The fourth channel, the fifth channel and the sixth channel of the flow control device extend downward from the first flow control surface of the first flow control element and respectively Communicated with the second diversion chamber.

24. The flow controller according to claim 22, further comprising a flow isolation element extending downward from the first flow control body of the first flow control element, and the outer shell body of the outer shell extends downwardly from the first flow control body of the first flow control element. The lower end of the first flow control body of the first flow control element extends downward, wherein the flow isolation element and the housing body form a first gap between the flow isolation element and the housing body. The flow guide chamber, and the flow isolation element form a second flow guide chamber, wherein the first channel, the second channel and the third channel of the flow controller are separated from the first flow control surface of the first flow control element. Extend downward and communicate with the first flow guide chamber respectively; The fourth channel, the fifth channel and the sixth channel of the flow control device extend downward from the first flow control surface of the first flow control element and respectively Communicated with the second diversion chamber.

25. The flow controller according to claim 24, further comprising a flow guide element, wherein the flow guide element includes a flow guide body, wherein the flow guide body is surrounded by a first flow guide channel, wherein the flow-guiding body of the flow-guiding element extends upward from the second flow-controlling body of the second flow-controlling element, and the first flow-guiding channel of the flow-guiding element is connected with the third flow-guiding device of the flow controller. Twenty-three channels are connected.

26. The flow controller according to claim 25, further comprising a driving element extending upward from the second flow control body of the second flow control element and a seal extending upward from the driving element. element, wherein the driving element is adapted to drive the second flow control body of the second flow control element of the flow controller to rotate relative to the first flow control body of the first flow control element; wherein the sealing element is adapted to is disposed in the housing and seals the first containing chamber.

27. The flow control device according to claim 10, further comprising a housing, and the first flow control body of the first flow control element of the flow control device further includes a first flow control body from the top end portion. a lower end extending downward, wherein the housing includes a housing body, wherein the housing body extends outwardly and upward from the lower end of the first flow control body of the first flow control element and surrounds a a first accommodation chamber, wherein the first accommodation chamber is connected with the conductive opening of the eighteenth channel, wherein the housing has a first opening, a second opening, a third opening, and a fourth opening , a fifth opening and a sixth opening, wherein the first accommodation chamber is connected with the first opening, and the ninth channel extends downward from the first flow control surface of the first flow control element and from The lower end of the first flow control body of the first flow control element extends outward to communicate with the second opening; the seventh channel extends downward from the first flow control surface of the first flow control element Extends and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the fifth opening; the eighth channel extends from the first control body of the first flow control element. The flow surface extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the sixth opening, wherein the eleventh channel of the flow control device and The twelfth channel is connected with the tenth channel respectively; wherein at least one of the tenth channel, the eleventh channel and the twelfth channel is connected from the first flow control element of the first flow control element. A flow control surface extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the third opening; the fourteenth part of the flow control device channel and the fifteenth channel are respectively connected with the thirteenth channel; wherein at least one of the thirteenth channel, the fourteenth channel and the fifteenth channel is from the first control The first flow control surface of the flow element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to connect with the third flow control surface. The four openings are connected.

28. The flow controller according to claim 27, further comprising a flow isolation element extending downward from the first flow control body of the first flow control element, and the outer shell body of the outer shell extends downwardly from the first flow control body of the first flow control element. The lower end of the first flow control body of the first flow control element extends downward, wherein the flow isolation element and the housing body form a first gap between the flow isolation element and the housing body. The flow guide chamber and the flow isolation element form a second flow guide chamber, wherein the second channel and the third channel of the flow controller are respectively connected with the first channel, wherein the third channel At least one of a channel, the second channel and the third channel extends downward from the first flow control surface of the first flow control element and is connected with the first flow guide chamber; the flow control The fifth channel and the sixth channel of the device are respectively connected with the fourth channel, wherein at least one of the fourth channel, the fifth channel and the sixth channel is from the first The first flow control surface of the flow control element extends downward and is connected with the second flow guide chamber.

29. The flow control device according to claim 10, further comprising a housing, and the first flow control body of the first flow control element of the flow control device further includes a first flow control body from the top end portion. a lower end extending downward, wherein the housing includes a housing body, wherein the housing body extends outwardly and upward from the lower end of the first flow control body of the first flow control element and surrounds a A first accommodation chamber, wherein the first accommodation chamber is connected with the conductive opening of the eighteenth channel.

30. The flow controller according to claim 15, wherein the housing has a first opening, a second opening, a third opening, a fourth opening, a fifth opening, and a sixth opening. , a seventh opening and an eighth opening, wherein the first accommodation chamber is connected with the first opening, and the ninth channel extends downward from the first flow control surface of the first flow control element and from The lower end of the first flow control body of the first flow control element extends outward to communicate with the second opening; the tenth channel, the eleventh channel and the twelfth channel respectively Extends downward from the first flow control surface of the first flow control element and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the third opening; The thirteenth channel, the fourteenth channel and the fifteenth channel respectively extend downward from the first flow control surface of the first flow control element and from the lower end of the first flow control body of the first flow control element. The end extends outward to communicate with the fourth opening; the seventh channel extends downward from the first flow control surface of the first flow control element and extends downward from the first flow control surface of the first flow control element. The lower end of the body extends outward to communicate with the fifth opening; the eighth channel extends downward from the first flow control surface of the first flow control element and from the third flow control surface of the first flow control element. One control flow The lower end of the body extends outward to communicate with the sixth opening; the sixteenth channel extends downward from the first flow control surface of the first flow control element and from the first flow control element. The lower end of the first flow control body extends outward to communicate with the seventh opening; the seventeenth channel extends downward from the first flow control surface of the first flow control element and extends from the first The lower end of the first flow control body of the flow control element extends outward to communicate with the eighth opening.

31. The flow controller according to claim 29, wherein the housing has a first opening, a second opening, a third opening, a fourth opening, a fifth opening, and a sixth opening. , a seventh opening and an eighth opening, wherein the first accommodation chamber is connected with the first opening, and the ninth channel extends downward from the first flow control surface of the first flow control element and from The lower end of the first flow control body of the first flow control element extends outward to communicate with the second opening; the tenth channel, the eleventh channel and the twelfth channel respectively Extends downward from the first flow control surface of the first flow control element and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the third opening; The thirteenth channel, the fourteenth channel and the fifteenth channel respectively extend downward from the first flow control surface of the first flow control element and from the lower end of the first flow control body of the first flow control element. The end extends outward to communicate with the fourth opening; the seventh channel extends downward from the first flow control surface of the first flow control element and extends downward from the first flow control surface of the first flow control element. The lower end of the body extends outward to communicate with the fifth opening; the eighth channel extends downward from the first flow control surface of the first flow control element and from the third flow control surface of the first flow control element. The lower end of a flow control body extends outward to communicate with the sixth opening; the sixteenth channel extends downward from the first flow control surface of the first flow control element and extends from the first flow control element. The lower end of the first flow control body of the flow element extends outward to communicate with the seventh opening; the seventeenth channel extends downward from the first flow control surface of the first flow control element and from the The lower end of the first flow control body of the first flow control element extends outward to communicate with the eighth opening.

32. The flow control device according to claim 30, further comprising a wear-resistant element disposed between the first flow control element and the second flow control element, wherein the wear-resistant element has a Wear-resistant body, wherein the wear-resistant body has a wear-resistant surface suitable for contact with the second flow control surface of the second flow control body, and wherein the wear-resistant surface undergoes wear-resistant treatment.

33. The flow control device according to claim 31, further comprising a wear-resistant element disposed between the first flow control element and the second flow control element, wherein the wear-resistant element has a a wear-resistant body, wherein the wear-resistant body has a second flow control body adapted to engage with the second flow control body; A wear-resistant surface in contact with the flow control surface, wherein the wear-resistant surface has undergone wear-resistant treatment.

34. The flow controller according to claim 33, wherein the size and shape of the wear-resistant element are designed and formed according to the first flow control surface of the first flow control element of the flow controller, wherein the The wear-resistant body of the wear-resistant element has a first interface, a second interface, a third interface, a fourth interface, a fifth interface, a sixth interface, a seventh interface, an eighth interface, and a A ninth interface, a tenth interface, an eleventh interface, a twelfth interface, a thirteenth interface, a fourteenth interface, a fifteenth interface, a sixteenth interface and a seventeenth interface , wherein the first interface, the second interface, the third interface, the fourth interface, the fifth interface, the sixth interface, the seventh interface, the eighth interface, The ninth interface, the tenth interface, the eleventh interface, the twelfth interface, the thirteenth interface, the fourteenth interface, the fifteenth interface, the The sixteenth interface and the seventeenth interface penetrate the wear-resistant body of the wear-resistant element up and down and are connected with the first channel, the second channel, the third channel, and the flow controller in sequence. The fourth channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, the ninth channel, the tenth channel, the eleventh channel, the The twelfth channel, the thirteenth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel correspond one to one.

35. The flow controller according to claim 34, wherein the wear-resistant element is integrally formed with the first flow control body of the first flow control element.

36. The flow controller according to claim 31, further comprising a flow isolation element extending downward from the first flow control body of the first flow control element, and the outer shell body of the outer shell extends downwardly from the first flow control body of the first flow control element. The lower end of the first flow control body of the first flow control element extends downward, wherein the flow isolation element and the housing body form a first gap between the flow isolation element and the housing body. The flow guide chamber, and the flow isolation element form a second flow guide chamber, wherein the first channel, the second channel and the third channel of the flow controller are separated from the first flow control surface of the first flow control element. Extend downward and communicate with the first flow guide chamber respectively; The fourth channel, the fifth channel and the sixth channel of the flow control device extend downward from the first flow control surface of the first flow control element and respectively Communicated with the second diversion chamber.

37. The flow controller according to claim 35, further comprising a flow isolation element extending downward from the first flow control body of the first flow control element, and the outer shell body of the outer shell extends downwardly from the first flow control body of the first flow control element. The lower end of the first flow control body of the first flow control element extends downward, wherein the flow isolation element and the housing body form a first gap between the flow isolation element and the housing body. guide The flow chamber, and the flow-blocking element form a second flow-guiding chamber, wherein the first channel, the second channel and the third channel of the flow-control device are downward from the first flow-control surface of the first flow-control element. Extend and are respectively connected with the first flow guide chamber; the fourth channel, the fifth channel and the sixth channel of the flow control device extend downward from the first flow control surface of the first flow control element and are respectively connected with The second diversion chambers are connected.

38 The flow controller according to claim 37, further comprising a flow guide element, wherein the flow guide element includes a flow guide body, wherein the flow guide body is surrounded by a first flow guide channel , wherein the flow guide body of the flow guide element extends upward from the second flow control body of the second flow control element, and the first flow guide channel of the flow guide element is connected with the second flow control body of the flow controller. Thirteen channels are connected.

39. The flow controller according to claim 38, further comprising a driving element extending upward from the second flow control body of the second flow control element and a seal extending upward from the driving element. element, wherein the driving element is adapted to drive the second flow control body of the second flow control element of the flow controller to rotate relative to the first flow control body of the first flow control element; wherein the sealing element is adapted to is disposed in the housing and seals the first containing chamber.

40. The flow control device according to claim 10, further comprising a housing, and the first flow control body of the first flow control element of the flow control device further includes a first flow control body from the top end portion. a lower end extending downward, wherein the housing includes a housing body, wherein the housing body extends outwardly and upward from the lower end of the first flow control body of the first flow control element and surrounds a a first accommodation chamber, wherein the first accommodation chamber is connected with the conductive opening of the eighteenth channel, wherein the housing has a first opening, a second opening, a third opening, and a fourth opening , a fifth opening, a sixth opening, a seventh opening and an eighth opening, wherein the first accommodation chamber is connected with the first opening, and the ninth channel is from the first flow control element The first flow control surface extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the second opening; the seventh channel extends from the first The first flow control surface of the flow control element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the fifth opening; the eighth channel extends from the The first flow control surface of the first flow control element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the sixth opening; the tenth Six channels extend downward from the first flow control surface of the first flow control element and extend outward from the lower end of the first flow control body of the first flow control element to communicate with the seventh opening; The seventeenth channel extends downward from the first flow control surface of the first flow control element and extends from the The lower end of the first flow control body of the first flow control element extends outward to communicate with the eighth opening, wherein the eleventh channel and the twelfth channel of the flow control device are respectively connected with The tenth channel is connected; wherein at least one of the tenth channel, the eleventh channel and the twelfth channel extends downward from the first flow control surface of the first flow control element and from The lower end of the first flow control body of the first flow control element extends outward to communicate with the third opening; the fourteenth channel and the fifteenth channel of the flow control device are respectively connected with the thirteenth channel; wherein at least one of the thirteenth channel, the fourteenth channel and the fifteenth channel is from the first flow control surface of the first flow control element. Extend downwardly and extend outward from the lower end of the first flow control body of the first flow control element to communicate with the fourth opening.

41. The flow controller according to claim 40, further comprising a flow isolation element extending downward from the first flow control body of the first flow control element, and the outer shell body of the outer shell extends downwardly from the first flow control body of the first flow control element. The lower end of the first flow control body of the first flow control element extends downward, wherein the flow isolation element and the housing body form a first gap between the flow isolation element and the housing body. The flow guide chamber and the flow isolation element form a second flow guide chamber, wherein the second channel and the third channel of the flow controller are respectively connected with the first channel, wherein the third channel At least one of a channel, the second channel and the third channel extends downward from the first flow control surface of the first flow control element and is connected with the first flow guide chamber; the flow control The fifth channel and the sixth channel of the device are respectively connected with the fourth channel, wherein at least one of the fourth channel, the fifth channel and the sixth channel is from the first The first flow control surface of the flow control element extends downward and is connected with the second flow guide chamber.

42. A water treatment system, characterized by including:

a flow controller; and

A water treatment unit, wherein the water treatment unit is provided at the flow controller, and the water flow can flow between the water treatment unit and the flow controller under the control and guidance of the flow controller,

wherein the flow control device includes a first flow control element, a second flow control element and a housing, wherein the first flow control element includes a first flow control body, and the first flow control body includes a top end part, wherein the top end part forms a first flow control surface; the second flow control element includes a second flow control body, the second flow control body has a bottom end part and a bottom end part. The upper end portion extends upward, and the bottom end portion forms a second flow control surface; wherein the second flow control surface of the second flow control element is adapted to be rotatably disposed on the first flow control element. The first control flow surface, in which The flow controller has a first channel, a second channel, a third channel, a fourth channel, a fifth channel, a sixth channel, a seventh channel, an eighth channel, and a ninth channel. A tenth channel, an eleventh channel, a twelfth channel, a thirteenth channel, a fourteenth channel, a fifteenth channel, a sixteenth channel, a seventeenth channel, a tenth channel Eight channels, a nineteenth channel, a twentieth channel, a twenty-first channel, a twenty-second channel and a twenty-third channel, wherein the first channel, the second channel, the The third channel, the fourth channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, the ninth channel, the tenth channel, the The eleventh channel, the twelfth channel, the thirteenth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel are respectively located in the The first flow control body of the first flow control element extends downward from the first flow control surface of the first flow control body of the first flow control element; the nineteenth channel, the twentieth channel, the The twenty-first channel, the twenty-second channel and the twenty-third channel are respectively provided at the bottom end of the second flow control body and from the bottom end of the second flow control body. The second flow control surface extends upward, wherein the nineteenth channel and the twenty-first channel are respectively located outside the twentieth channel and connected to the twentieth channel respectively, wherein the control channel The first flow control body of the first flow control element of the flow device further includes a lower end extending downward from the top end, wherein the housing includes a housing body, wherein the housing body extends from the first The lower end of the first flow control body of a flow control element extends outward and upward and surrounds a first containing chamber, wherein the eighteenth channel is provided at the bottom end of the second flow control body and The second flow control surface extends upward and outward from the bottom end of the second flow control body and forms a conductive opening that is always connected to the first accommodation chamber, wherein the housing has a first opening, a second opening, a third opening, a fourth opening, a fifth opening, and a sixth opening, wherein the first accommodation chamber is connected with the first opening, and the ninth passage is from the The first flow control surface of the first flow control element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the second opening; the tenth The channel, the eleventh channel and the twelfth channel extend downward from the first flow control surface of the first flow control element and are all connected with the third opening; the thirteenth channel, The fourteenth channel and the fifteenth channel extend downward from the first flow control surface of the first flow control element and are both connected to the fourth opening; the seventh channel extends downward from the first flow control element The first flow control surface extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the fifth opening; the eighth channel extends from the first The first flow control surface of the flow control element Extend downward and extend outward from the lower end of the first flow control body of the first flow control element to communicate with the sixth opening, wherein the first part of the housing of the flow control device The opening is connected to an external water source; the third opening, the fourth opening, the fifth opening and the sixth opening of the housing of the flow controller are respectively connected to the water treatment unit.

43. The water treatment system according to claim 42, wherein the flow controller further has a first conductive channel and a second conductive channel, wherein the first conductive channel and the second conductive channel Two conductive channels are respectively provided on the first flow control body of the first flow control element; wherein the first conductive channel extends from the seventh channel to the sixteenth channel and connects the seventh channel is connected to the sixteenth channel; the second conductive channel extends from the eighth channel to the seventeenth channel and connects the eighth channel to the seventeenth channel, wherein the The first edge portion of the top end of the first flow control body of the first flow control element of the flow control device includes a first outer edge portion and a first conductive portion extending outward from the first outer edge portion. ; The second edge portion of the bottom end portion of the second flow control body of the second flow control element includes a second outer edge portion and a first edge portion extending outward from the second outer edge portion. The sealing part, wherein the first channel and the tenth channel are respectively provided at the first outer edge of the first edge of the top end of the first flow control body of the first flow control element of the flow control device; The eighteenth channel is provided at the second outer edge of the second edge of the bottom end of the second flow control body of the second flow control element; the first conductive channel is provided at The first conductive portion of the first edge portion of the top end portion of the first flow control body of the first flow control element of the flow control device is connected from the first control portion of the first flow control body of the first flow control element. The flow surface extends downward; the second conductive channel is provided at the first conductive portion of the first edge portion of the top end of the first flow control body of the first flow control element of the flow controller and extends from the first conductive channel The first flow control surface of the first flow control body of a flow control element extends downward; wherein when the second flow control element rotates relative to the first flow control element, the third flow control surface of the second flow control element The first sealing portion of the second edge portion of the bottom end of the second flow control body can separate the first conduction channel and the second conduction channel from the first flow control element of the flow control device. The first flow control body is separated by an external space above it.

44. The water treatment system according to claim 43, wherein the flow controller further includes a flow isolation element extending downward from the first flow control body of the first flow control element, and the The shell body of the shell extends downward from the lower end of the first flow control body of the first flow control element, wherein the flow isolation element and the shell body form a gap between the flow isolation element and the shell body. between the first flow guiding chamber, and the flow dividing element to form a second flow guiding chamber, wherein the flow control The second channel and the third channel of the device are respectively connected with the first channel, wherein at least one of the first channel, the second channel and the third channel is from the first channel. The first flow control surface of the flow control element extends downward and is connected with the first flow guide chamber; the fifth channel and the sixth channel of the flow control device are respectively connected with the fourth channel, At least one of the fourth channel, the fifth channel and the sixth channel extends downward from the first flow control surface of the first flow control element and is connected with the second flow guide chamber.

45. The water treatment system according to claim 44, wherein the water treatment unit includes a first water treatment element, a second water treatment element and a first ejector, wherein the first water treatment element The element has a first communication opening and a second communication opening, the second water treatment element has a third communication opening and a fourth communication opening, the first ejector has a fifth communication opening and a sixth communication opening. Communication opening, wherein the first communication opening of the first water treatment element is connected with the first flow guide chamber of the flow controller; the second communication opening of the first water treatment element is connected with the first communication opening of the first water treatment element respectively. The second diversion chamber of the flow controller is connected; the third communication opening of the second water treatment element is connected with the third opening of the flow controller; the third communication opening of the second water treatment element is connected The fourth communication opening is connected to the fourth opening of the flow controller; the fifth communication opening of the first jet is connected to the fifth opening of the flow controller; the first jet The sixth communication openings of the device are respectively connected with the sixth openings of the flow controller.

46. The water treatment system according to claim 45, wherein the first water treatment element includes a first water treatment part, and the second water treatment element has a second water treatment part, wherein when The water to be treated flows in from the first communication opening of the first water treatment element and flows out from the second communication opening of the first water treatment element, or from the second communication opening of the first water treatment element When the opening flows into and flows out from the first communication opening of the first water treatment element, the water to be treated is treated by the first water treatment part of the first water treatment element and treated water is obtained; when the water to be treated is Water flows in from the third communication opening of the second water treatment element and flows out from the fourth communication opening of the second water treatment element, or flows in from the fourth communication opening of the second water treatment element. When flowing out from the third communication opening of the second water treatment element, the water to be treated is treated by the second water treatment part of the second water treatment element and treated water is obtained.

47. The water treatment system according to claim 46, wherein the water treatment unit further includes a liquid distribution tank, wherein when the first injector injects water into the flow controller, When the sixth opening of the housing is opened, the regeneration solution in the liquid distribution tank is sucked into the outside of the flow controller. The sixth opening of the shell, and the regeneration solution can flow to the second water treatment element or the first water treatment element of the water treatment unit under the control and guidance of the flow controller, so that the second water treatment element The second water treatment section of the water treatment element or the first water treatment section of the first water treatment element is regenerated.

48. The water treatment system according to claim 42, wherein the housing of the flow controller further has a seventh opening and an eighth opening, wherein the sixteenth channel extends from the first The first flow control surface of the flow control element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the seventh opening, and the seventeenth channel Extend downward from the first flow control surface of the first flow control element and extend outward from the lower end of the first flow control body of the first flow control element to communicate with the eighth opening, wherein The seventh opening and the eighth opening of the housing of the flow controller are respectively connected with the water treatment unit.

49. The water treatment system according to claim 48, characterized in that, the flow controller further includes a flow isolation element extending downward from the first flow control body of the first flow control element, and the The shell body of the shell extends downward from the lower end of the first flow control body of the first flow control element, wherein the flow isolation element and the shell body form a gap between the flow isolation element and the shell body. The first flow guide chamber between the first flow guide chamber and the flow isolation element forms a second flow guide chamber, wherein the second channel and the third channel of the flow controller are respectively connected with the first channel. , wherein at least one of the first channel, the second channel and the third channel extends downward from the first flow control surface of the first flow control element and is connected with the first flow guide chamber ; The fifth channel and the sixth channel of the flow controller are respectively connected with the fourth channel, wherein at least one of the fourth channel, the fifth channel and the sixth channel Extends downward from the first flow control surface of the first flow control element and communicates with the second flow guide chamber.

50. The water treatment system according to claim 49, wherein the water treatment unit includes a first water treatment element, a second water treatment element, a first ejector and a second ejector, wherein The first water treatment element has a first communication opening and a second communication opening, the second water treatment element has a third communication opening and a fourth communication opening, and the first ejector has a fifth communication opening. a communication opening and a sixth communication opening, the second ejector has a seventh communication opening and an eighth communication opening, wherein the first communication opening of the first water treatment element and the flow controller The first flow diversion chamber is connected; the second communication opening of the first water treatment element is connected with the second flow diversion chamber of the flow controller; the third communication of the second water treatment element The opening is connected with the third opening of the flow controller; the second water treatment element The fourth communication opening is connected to the fourth opening of the flow controller; the fifth communication opening of the first ejector is connected to the fifth opening of the flow controller; the The sixth communication opening of the first ejector is connected to the sixth opening of the flow controller; the seventh communication opening of the second ejector is connected to the seventh communication opening of the flow controller. The openings are connected; the eighth communication opening of the second ejector is connected with the eighth opening of the flow controller.

51. A flow controller, characterized in that it includes:

A first flow control element and a second flow control element rotatably provided on the first flow control element, wherein the first flow control element includes a first flow control body, and the first flow control body It includes a top end portion, wherein the top end portion forms a first flow control surface; the second flow control element includes a second flow control body, and the second flow control body has a bottom end portion and a first flow control surface. The bottom end portion extends upward and the high end portion forms a second flow control surface; wherein the second flow control surface of the second flow control element is adapted to be rotatably disposed on the first control surface. The first flow control surface of the flow element, wherein the flow control device has a first channel, a second channel, a fourth channel, a fifth channel, a sixth channel, a seventh channel, and an eighth channel , a ninth channel, a tenth channel, an eleventh channel, a thirteenth channel, a fourteenth channel, a fifteenth channel, a sixteenth channel, a seventeenth channel, a tenth channel Eight channels, a nineteenth channel, a twentieth channel, a twenty-first channel, a twenty-second channel and a twenty-third channel, wherein the first channel, the second channel, the The fourth channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, the ninth channel, the tenth channel, the eleventh channel, the The thirteenth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel are respectively provided on the first flow control body of the first flow control element and are automatically The first flow control surface of the first flow control body of the first flow control element extends downward; the eighteenth channel is provided at the bottom end of the second flow control body and extends from the second flow control body The second flow control surface at the bottom end extends upward and outward and forms a conductive opening that is always connected to the external space of the flow controller; the nineteenth channel, the twentieth channel, The twenty-first channel, the twenty-second channel and the twenty-third channel are respectively provided at the bottom end of the second flow control body and extend from the bottom end of the second flow control body. The second flow control surface extends upward, wherein the nineteenth channel and the twenty-first channel are respectively located outside the twentieth channel and connected with the twentieth channel respectively.

52. The flow controller according to claim 51, characterized in that, the third part of the flow controller The nineteenth channel, the twentieth channel, the twenty-first channel and the twenty-second channel respectively extend upward from the second flow control surface of the second flow control element to the second flow control element. The high end part of the element; the twenty-third channel extends upward from the second flow control surface of the second flow control element and penetrates the second flow control body of the second flow control element, wherein the nineteenth The channel is connected to the twentieth channel; the twenty-first channel extends upward and inward from the second flow control surface of the second flow control element, thereby being connected to the twentieth channel.

53. The flow controller according to claim 52, characterized in that, the flow controller has a first working position, a second working position, a third working position, a fourth working position, and a fifth working position. working position, a sixth working position, a seventh working position, an eighth working position, a ninth working position and a tenth working position, wherein when the flow controller is in the first working position, the control The eighteenth channel of the flow controller is connected to the first channel, the nineteenth channel is connected to the fourth channel, and the twentieth channel is connected to the ninth channel; when the flow controller is in the second operation position, the eighteenth channel of the flow controller is connected to the first channel, the nineteenth channel is connected to the fourth channel, the twentieth channel is connected to the ninth channel, and the second channel is connected to the first channel. The eleventh channel is connected to the fourteenth channel, and the twenty-third channel is connected to the eleventh channel. When the flow controller is in the third working position, the third channel of the flow controller is connected to the eleventh channel. The eighteenth channel is connected to the first channel, the nineteenth channel is connected to the fourth channel, the twentieth channel is connected to the ninth channel, the twenty-first channel is connected to the sixteenth channel are connected, the twenty-second channel is connected to the eleventh channel and the seventeenth channel respectively, and the twenty-third channel is connected to the fifteenth channel; when the flow control When the controller is in the fourth working position, the eighteenth channel of the flow controller is connected to the first channel, the nineteenth channel is connected to the fourth channel, and the twentieth channel is connected to the ninth channel , the twenty-first channel is connected to the seventeenth channel; when the flow controller is in the fifth working position, the eighteenth channel of the flow controller is connected to the first channel, and the The nineteenth channel is connected to the fourth channel, the twentieth channel is connected to the ninth channel, the twenty-first channel is connected to the eleventh channel, and the twenty-third channel is connected to all The fifteenth channel is connected; when the flow controller is in the sixth working position, the eighteenth channel of the flow controller is connected to the tenth channel, and the nineteenth channel is connected to the thirteenth channel The twentieth channel is connected to the ninth channel; when the flow controller is in the seventh working position, the eighteenth channel of the flow controller is connected to the tenth channel, and the nineteenth channel is connected to the ninth channel. The channel is connected to the thirteenth channel, the twentieth channel is connected to the ninth channel, the twenty-first channel is connected to the fifth channel, the twenty-third channel is connected to the second channel The channels are connected; when When the flow controller is in the eighth working position, the eighteenth channel of the flow controller is connected to the tenth channel, the nineteenth channel is connected to the thirteenth channel, and the twentieth channel is connected to The ninth channel is connected to, the twenty-first channel is connected to the seventh channel, the 22nd channel is connected to the second channel and the eighth channel respectively, and the twentieth channel is connected to the seventh channel. Three channels are connected to the sixth channel; when the flow controller is in the ninth working position, the eighteenth channel of the flow controller is connected to the tenth channel, and the nineteenth channel is connected to the tenth channel. Three channels are connected, the twentieth channel is connected with the ninth channel, the twenty-first channel is connected with the eighth channel; when the flow controller is in the tenth working position, the control The eighteenth channel of the flow device is connected to the tenth channel, the nineteenth channel is connected to the thirteenth channel, the twentieth channel is connected to the ninth channel, and the twenty-first channel is connected to all The second channel is connected, and the twenty-third channel is connected with the sixth channel.

54. The flow controller according to claim 53, characterized in that when the flow controller is in the first working position, the second channel, the fifth channel, the seventh channel, the The eighth channel, the tenth channel, the eleventh channel, the thirteenth channel and the fifteenth channel are respectively blocked by the second flow control body of the second flow control element of the flow controller ; When the flow controller is in the second working position, the second channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, the tenth channel, The thirteenth channel and the fifteenth channel are respectively blocked by the second flow control body of the second flow control element of the flow controller; when the flow controller is in the third working position, the third The second channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, the tenth channel, the thirteenth channel and the fourteenth channel are respectively described The second flow control body of the second flow control element of the flow controller is blocked; when the flow controller is in the fourth working position, the second channel, the fifth channel, the sixth channel, the The seventh channel, the eighth channel, the tenth channel, the thirteenth channel, the fourteenth channel and the sixteenth channel are respectively controlled by the second flow control element of the flow control device. The second flow control body is blocked; when the flow controller is in the fifth working position, the second channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, The tenth channel, the thirteenth channel, the fourteenth channel, the sixteenth channel and the seventeenth channel are respectively controlled by the second flow control element of the flow control device. The flow body is blocked; when the flow controller is in the sixth working position, the first channel, the second channel, the fourth channel, the sixth channel, the eleventh channel, the The fourteenth channel, the sixteenth channel and the seventeenth channel are respectively blocked by the second flow control body of the second flow control element of the flow controller; when the flow controller is in the seventh working position When, the first channel, the fourth channel, The sixth channel, the eleventh channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel are respectively controlled by the second channel of the flow controller. The second flow control body of the flow control element is blocked; when the flow controller is in the eighth working position, the first channel, the fourth channel, the fifth channel, the eleventh channel, the The fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel are respectively blocked by the second flow control body of the second flow control element of the flow control device; when the When the flow controller is in the ninth working position, the first channel, the fourth channel, the fifth channel, the seventh channel, the eleventh channel, the fourteenth channel, the The fifteenth channel, the sixteenth channel and the seventeenth channel are respectively blocked by the second flow control body of the second flow control element of the flow controller; when the flow controller is in the tenth working position When, the first channel, the fourth channel, the fifth channel, the seventh channel, the eighth channel, the eleventh channel, the fourteenth channel, the tenth channel The five channels, the sixteenth channel and the seventeenth channel are respectively blocked by the second flow control body of the second flow control element of the flow control device.

55. The flow controller according to claim 54, wherein when the flow controller is in the first working position, the twenty-first channel is connected to the sixth channel, and the second Twelve channels are connected to the fourteenth channel and the sixteenth channel respectively, and the twenty-third channel is connected to the seventeenth channel; when the flow controller is in the second working position , the twenty-second channel is connected to the sixteenth channel and the seventeenth channel respectively; when the flow controller is in the fourth working position, the twenty-second channel is connected to the The eleventh channel is connected to the fifteenth channel, and the twenty-third channel is connected to the fifteenth channel; when the flow controller is in the fifth working position, the twenty-second channel The channel is connected to the fifteenth channel; when the flow controller is in the sixth working position, the twenty-first channel is connected to the fifteenth channel, and the twenty-second channel is connected to the The fifth channel is connected to the seventh channel, and the twenty-third channel is connected to the eighth channel; when the flow controller is in the seventh working position, the twenty-second channel are respectively connected to the seventh channel and the eighth channel; when the flow controller is in the ninth working position, the 22nd channel is connected to the second channel and the sixth channel respectively. The twenty-third channel is connected to the sixth channel; when the flow controller is in the tenth working position, the twenty-second channel is connected to the sixth channel.

56. The flow controller according to claim 55, wherein the first channel of the flow controller is connected to the fourth channel, the fifth channel, the sixth channel, and the seventh channel respectively. channel, the eighth channel, the ninth channel, the tenth channel, the eleventh channel, the thirteenth channel The channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel are spaced apart from each other on the first flow control body of the first flow control element; The second channel is respectively connected with the fourth channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, the ninth channel, the tenth channel, the The eleventh channel, the thirteenth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel are spaced apart from each other in the first control The first flow control body of the flow element; the fourth channel is connected to the seventh channel, the eighth channel, the ninth channel, the tenth channel, the eleventh channel, and the third channel respectively. The thirteenth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel are spaced apart from each other on the first flow control body of the first flow control element. ; The fifth channel is respectively connected with the seventh channel, the eighth channel, the ninth channel, the tenth channel, the eleventh channel, the thirteenth channel, and the tenth channel The four channels, the fifteenth channel, the sixteenth channel and the seventeenth channel are spaced apart from each other on the first flow control body of the first flow control element; the sixth channel is respectively The seventh channel, the eighth channel, the ninth channel, the tenth channel, the eleventh channel, the thirteenth channel, the fourteenth channel, the fifteenth channel The channel, the sixteenth channel and the seventeenth channel are spaced apart from each other on the first flow control body of the first flow control element; the seventh channel is respectively connected with the eighth channel and the seventeenth channel. The ninth channel, the tenth channel, the eleventh channel, the thirteenth channel, the fourteenth channel, the fifteenth channel and the seventeenth channel are spaced apart from each other. the first flow control body of the first flow control element; the sixteenth channel is connected to the eighth channel, the ninth channel, the tenth channel, the eleventh channel, and the third channel respectively. The thirteenth channel, the fourteenth channel, the fifteenth channel and the seventeenth channel are spaced apart from each other on the first flow control body of the first flow control element; the eighth channel is respectively The first channel is located apart from the ninth channel, the tenth channel, the eleventh channel, the thirteenth channel, the fourteenth channel and the fifteenth channel. The first flow control body of the flow control element; the seventeenth channel and the ninth channel, the tenth channel, the eleventh channel, the thirteenth channel, and the fourteenth channel respectively The first flow control body of the first flow control element is spaced apart from the fifteenth channel; the ninth channel is respectively connected with the tenth channel, the eleventh channel, and the first flow control body. Thirteen channels, the fourteenth channel and the fifteenth channel are spaced apart from each other on the first flow control body of the first flow control element; the tenth channel and the thirteenth channel are respectively , the fourteenth channel and the fifteenth channel are spaced apart from each other on the first flow control body of the first flow control element; the eleventh channel is respectively connected with the thirteenth channel and the first flow control body. The fourteenth channel is the same as the fifteenth channel The first flow control body is spaced apart from the first flow control element; the eighteenth channel is respectively connected with the nineteenth channel, the twentieth channel, the twenty-first channel, and the first flow control body. The 22nd channel and the 23rd channel are spaced apart from each other on the second flow control body of the second flow control element; the 22nd channel is respectively connected with the 19th channel and the 23rd channel. The twentieth channel and the twenty-first channel are spaced apart from each other on the second flow control body of the second flow control element; the twenty-third channel is respectively connected with the nineteenth channel and the second flow control body. The twentieth channel and the twenty-first channel are spaced apart from each other on the second flow control body of the second flow control element; the twenty-second channel is in phase with the twenty-third channel. The second flow control body is spaced apart from the second flow control element.

57. The flow controller according to claim 56, wherein the top end portion of the first flow control body of the first flow control element of the flow controller includes a first central portion, and a first center portion from the first flow control body. a first middle portion extending outwardly from the first central portion, a first extension portion extending outwardly from the first middle portion and a first edge portion extending outwardly from the first extension portion, and said The bottom end of the second flow control body of the second flow control element includes a second central part, a second middle part extending outwardly from the second central part, and a second middle part extending outwardly from the second middle part. a second extension part and a second edge part extending outward from the second extension part, wherein the first channel and the tenth channel are respectively provided at the first edge part of the top end part; The second channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, the eleventh channel, the fourteenth channel, the fifteenth channel, the The sixteenth channel and the seventeenth channel are respectively provided at the first extension portion of the top end portion; the fourth channel and the thirteenth channel are respectively provided at the first extension portion of the top end portion. a middle part; the ninth channel is provided at the first central part of the top end part; the eighteenth channel is provided at the second edge part of the bottom end part; the nineteenth channel is provided at The second middle part of the bottom end part; The twentieth channel is provided in the second central part of the bottom end part; The twenty-first channel, the twenty-second channel and the second Thirteen channels are respectively provided in the second extension part.

58. The flow controller according to claim 57, characterized in that, the first flow control surface of the first flow control element and the second flow control surface of the second flow control element of the flow controller are both circular. , wherein the second channel, the eighth channel, the seventh channel, the fifth channel, the fifteenth channel, the eleventh channel, the seventeenth channel, the sixteenth channel, the fourteenth channel and the Six channels are provided in the first flow control body of the first flow control element clockwise in this order; the twenty-third channel, the twenty-second channel and the twenty-first channel of the flow control device are in this order. The second flow control body is arranged clockwise on the second flow control element.

59. The flow controller according to claim 58, characterized in that, the first channel, the second channel, the fourth channel, the fifth channel, the sixth channel, the third channel The seventh channel, the eighth channel, the ninth channel, the tenth channel, the eleventh channel, the thirteenth channel, the fourteenth channel, the fifteenth channel, all The sixteenth channel and the seventeenth channel are both radially disposed on the first flow control surface of the first flow control element, and the eighteenth channel, the nineteenth channel, and the The twenty channels, the twenty-first channel, the twenty-second channel and the twenty-third channel are respectively radially provided on the second flow control surface of the second flow control element.

60. The flow controller according to claim 59, wherein the first flow control surface of the first flow control element of the flow controller has a central part, wherein the central part is provided on the first The first central part of the top end of the first flow control body of the flow control element, and the part other than the central part of the first flow control surface is equally divided clockwise into a first part, a second part, and a third part. three parts, a fourth part, a fifth part, a sixth part, a seventh part, an eighth part, a ninth part, a tenth part, an eleventh part, a twelfth part , a thirteenth part and a fourteenth part; the second flow control surface of the second flow control element of the flow controller has a central area, wherein the central area is located on the second flow control element The second central part of the bottom end of the second flow control body, and the part outside the central area of the second flow control surface is equally divided clockwise into a first area, a second area, and a third area , a fourth region, a fifth region, a sixth region, a seventh region, an eighth region, a ninth region, a tenth region, an eleventh region, a twelfth region, a first Thirteen areas and a fourteenth area; wherein the first channel is formed from the first part, the second part, the third part, the fourth part, the first flow control surface The fifth part and the sixth part extend downward; the second channel extends downward from the fourth part of the first flow control surface; the fourth channel extends from the fourth part of the first flow control surface The first part, the second part, the third part, the fourth part, the fifth part, the sixth part and the seventh part extend downward; the fifth channel extends downward from the The seventh part of the first flow control surface extends downward; the sixth channel extends downward from the first part, the second part and the third part of the first flow control surface; the third Seven channels extend downward from the sixth part of the first flow control surface; the eighth channel extends downward from the fifth part of the first flow control surface; the ninth channel extends downward from the first control surface. The central part of the flow surface extends downward; the tenth channel extends from the eighth part, the ninth part, the tenth part, the eleventh part, and the first flow control surface. The twelfth part and the thirteenth part extend downward; The eleventh channel extends downward from the eleventh part of the first flow control surface; the thirteenth channel extends downward from the eighth part, the ninth part, and the first flow control surface. The tenth part, the eleventh part, the twelfth part, the thirteenth part and the fourteenth part extend downward; the fourteenth channel extends from the first flow control The fourteenth part of the surface extends downward; the fifteenth channel extends downward from the eighth part, the ninth part and the tenth part of the first flow control surface; the tenth The six channels extend downward from the thirteenth part of the first flow control surface; the seventeenth channel extends downward from the twelfth part of the first flow control surface; the eighteenth channel extends downward from the The fifth area, the sixth area, and the seventh area of the second flow control surface extend upward; the nineteenth channel extends from the fifth area, the second flow control surface, and the seventh area of the second flow control surface. The sixth region and the seventh region extend upward; the twentieth channel extends upward from the central region of the second flow control surface; the twenty-first channel extends upward from the first channel of the second flow control surface; area extends upward; the twenty-second channel extends upward from the thirteenth area and the fourteenth area of the second flow control surface; the twenty-third channel extends upward from the second flow control surface The twelfth area of the surface extends upward.

61. The flow controller according to claim 60, wherein the flow controller further has a first conductive channel and a second conductive channel, wherein the first conductive channel and the second conductive channel Two conductive channels are respectively provided on the first flow control body of the first flow control element; wherein the first conductive channel extends from the seventh channel to the sixteenth channel and connects the seventh channel is connected with the sixteenth channel; the second conductive channel extends from the eighth channel to the seventeenth channel and connects the eighth channel with the seventeenth channel.

62. The flow controller according to claim 61, wherein the first edge portion of the top end of the first flow control body of the first flow control element of the flow controller includes a first outer edge portion and a first conductive portion extending outward from the first outer edge portion; the second edge portion of the bottom end portion of the second flow control body of the second flow control element includes a second outer edge portion; an edge portion and a first sealing portion extending outward from the second outer edge portion, wherein the first channel and the tenth channel are respectively provided on the first side of the first flow control element of the flow control device. The first outer edge of the first edge of the top end of the flow control body; the eighteenth channel is provided on the second end of the bottom end of the second flow control body of the second flow control element The second outer edge portion of the edge portion; the first conductive channel is provided at the first conductive portion of the first edge portion of the top end portion of the first flow control body of the first flow control element of the flow control device. Extending downward from the first flow control surface of the first flow control element; the second conductive channel is provided at the first edge of the top end of the first flow control body of the first flow control element of the flow controller The first conductive part of the part and from the first control The first flow control surface of the flow control element extends downward, wherein when the second flow control element rotates relative to the first flow control element, the bottom of the second flow control body of the second flow control element The first sealing portion of the second edge portion of the end can separate the first conductive channel and the second conductive channel from the upper and outer parts of the first flow control body of the first flow control element of the flow control device. space separated.

63. The flow controller according to claim 62, wherein the seventh channel and the sixteenth channel of the flow controller are respectively oriented from the first flow control surface of the first flow control element. Extend downward and extend outward and are respectively connected with the first conductive channel, so that the first conductive channel connects the seventh channel and the sixteenth channel; the eighth channel and The seventeenth channels respectively extend downward and outward from the first flow control surface of the first flow control element and are respectively connected with the second conduction channels, so that the second conduction channels will The eighth channel and the seventeenth channel are connected.

64. The flow controller according to claim 63, wherein the first conductive channel is connected to the second conductive channel, the first channel and the second conductive channel of the current controller respectively. channel, the fourth channel, the fifth channel, the sixth channel, the eighth channel, the ninth channel, the tenth channel, the eleventh channel, the thirteenth channel The channel, the fourteenth channel, the fifteenth channel and the seventeenth channel are spaced apart from each other on the first flow control body of the first flow control element; the second conduction channels are respectively With the first channel, the second channel, the fourth channel, the fifth channel, the sixth channel, the seventh channel, the ninth channel, the The tenth channel, the eleventh channel, the thirteenth channel, the fourteenth channel, the fifteenth channel and the sixteenth channel are spaced apart from each other in the first control The first flow control body of the flow element.

65. The flow controller according to claim 51, characterized in that: the flow controller further includes a housing, and the first flow control body of the first flow control element of the flow controller further includes a and a lower end extending downwardly from the top end, wherein the housing includes a housing body, wherein the housing body extends outwardly and upward from the lower end of the first flow control body of the first flow control element. And is surrounded by a first accommodation chamber, wherein the first accommodation chamber is connected with the conductive opening of the eighteenth channel.

66. The flow controller according to claim 64, characterized in that: the flow controller further includes a housing, and the first flow control body of the first flow control element of the flow controller further includes a a lower end portion extending downwardly from the top portion, wherein the housing includes a housing body, The housing body extends outwardly and upward from the lower end of the first flow control body of the first flow control element and surrounds a first accommodation chamber, wherein the first accommodation chamber and the tenth The conductive openings of the eight channels are connected.

67. The flow controller according to claim 65, wherein the housing has a first opening, a second opening, a third opening, a fourth opening, a fifth opening and a sixth opening. , wherein the first accommodation chamber is connected with the first opening, and the ninth channel extends downward from the first flow control surface of the first flow control element and from the first flow control surface of the first flow control element. The lower end of the flow control body extends outward to communicate with the second opening; the tenth channel and the eleventh channel respectively extend downward from the first flow control surface of the first flow control element and Extend outward from the lower end of the first flow control body of the first flow control element to communicate with the third opening; the thirteenth channel, the fourteenth channel and the fifteenth channel respectively Extend downward from the first flow control surface of the first flow control element and extend outward from the lower end of the first flow control body of the first flow control element to communicate with the fourth opening; The seventh channel extends downward from the first flow control surface of the first flow control element and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the fifth opening. ; The eighth channel extends downward from the first flow control surface of the first flow control element and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the sixth The openings are connected.

68. The flow controller according to claim 66, wherein the housing has a first opening, a second opening, a third opening, a fourth opening, a fifth opening and a sixth opening. , wherein the first accommodation chamber is connected with the first opening, and the ninth channel extends downward from the first flow control surface of the first flow control element and from the first flow control surface of the first flow control element. The lower end of the flow control body extends outward to communicate with the second opening; the tenth channel and the eleventh channel respectively extend downward from the first flow control surface of the first flow control element and Extend outward from the lower end of the first flow control body of the first flow control element to communicate with the third opening; the thirteenth channel, the fourteenth channel and the fifteenth channel respectively Extend downward from the first flow control surface of the first flow control element and extend outward from the lower end of the first flow control body of the first flow control element to communicate with the fourth opening; The seventh channel extends downward from the first flow control surface of the first flow control element and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the fifth opening. ; The eighth channel extends downward from the first flow control surface of the first flow control element and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the sixth The openings are connected.

69. The flow controller according to claim 65, further comprising a a wear-resistant element between the first flow control element and the second flow control element, wherein the wear-resistant element has a wear-resistant body and a second sealing portion, wherein the second sealing portion of the wear-resistant element can Cover the first conductive channel and the second conductive channel of the flow controller, thereby connecting the first conductive channel and the second conductive channel with the first accommodation chamber of the housing. separated.

70. The flow control device according to claim 68, further comprising a wear-resistant element disposed between the first flow control element and the second flow control element, wherein the wear-resistant element has a Wear-resistant body and a second sealing part, wherein the second sealing part of the wear-resistant element can cover the first conductive channel and the second conductive channel of the flow controller, thereby sealing the third conductive channel. A conductive channel and the second conductive channel are separated from the first receiving chamber of the housing.

71. The flow controller according to claim 70, wherein the size and shape of the wear-resistant element are designed and formed according to the first flow control surface of the first flow control element of the flow controller, wherein the The wear-resistant element has a first interface, a second interface, a fourth interface, a fifth interface, a sixth interface, a seventh interface, an eighth interface, a ninth interface, a tenth interface, an eleventh interface, a thirteenth interface, a fourteenth interface, a fifteenth interface, a sixteenth interface and a seventeenth interface, wherein the first interface, the second interface, The fourth interface, the fifth interface, the sixth interface, the seventh interface, the eighth interface, the ninth interface, the tenth interface, the eleventh interface, the The thirteenth interface, the fourteenth interface, the fifteenth interface, the sixteenth interface and the seventeenth interface penetrate the wear-resistant body of the wear-resistant element up and down and are connected with the control unit in sequence. The first channel, the second channel, the fourth channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, and the ninth channel of the flow device , the tenth channel, the eleventh channel, the thirteenth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel one by one correspond.

72. The flow controller according to claim 71, wherein the wear-resistant element is integrally formed with the first flow control body of the first flow control element.

73. The flow controller according to claim 65, further comprising a flow isolation element extending downward from the first flow control body of the first flow control element, and the housing body of the housing extends from The lower end of the first flow control body of the first flow control element extends outward and downward, wherein the flow isolation element and the housing body form a gap between the flow isolation element and the housing body. The first flow guide chamber, and the flow isolation element form a second flow guide chamber, wherein the first flow guide chamber of the flow controller The channel and the second channel extend downward from the first flow control surface of the first flow control element and are respectively connected with the first flow guide chamber; the fourth channel, the fifth channel and the sixth channel of the flow control device The channels extend downward from the first flow control surface of the first flow control element and are respectively connected with the second flow guide chambers.

74. The flow controller according to claim 72, further comprising a flow isolation element extending downward from the first flow control body of the first flow control element, and the housing body of the housing extends from The lower end of the first flow control body of the first flow control element extends outward and downward, wherein the flow isolation element and the housing body form a gap between the flow isolation element and the housing body. The first flow guide chamber, and the flow isolation element form a second flow guide chamber, wherein the first channel and the second channel of the flow controller are downward from the first flow control surface of the first flow control element Extend and are respectively connected with the first flow guide chamber; the fourth channel, the fifth channel and the sixth channel of the flow control device extend downward from the first flow control surface of the first flow control element and are respectively connected with The second diversion chambers are connected.

75. The flow controller according to claim 74, further comprising a flow guide element, wherein the flow guide element includes a flow guide body, wherein the flow guide body is surrounded by a first flow guide channel, wherein the flow-guiding body of the flow-guiding element extends upward from the second flow-controlling body of the second flow-controlling element, and the first flow-guiding channel of the flow-guiding element is connected with the third flow-guiding device of the flow controller. Twenty-three channels are connected.

76. The flow controller according to claim 75, further comprising a driving element extending upward from the second flow control body of the second flow control element and a seal extending upward from the driving element. element, wherein the driving element is adapted to drive the second flow control body of the second flow control element of the flow controller to rotate relative to the first flow control body of the first flow control element; wherein the sealing element is adapted to is disposed in the housing and seals the first containing chamber.

77. The flow control device according to claim 60, further comprising a housing, and the first flow control body of the first flow control element of the flow control device further includes a first flow control body from the top end portion. a lower end extending downward, wherein the housing includes a housing body, wherein the housing body extends outwardly and upward from the lower end of the first flow control body of the first flow control element and surrounds a a first accommodation chamber, wherein the first accommodation chamber is connected with the conductive opening of the eighteenth channel, wherein the housing has a first opening, a second opening, a third opening, and a fourth opening , a fifth opening and a sixth opening, wherein the first accommodation chamber is connected with the first opening, and the ninth channel extends downward from the first flow control surface of the first flow control element and from The lower end of the first flow control body of the first flow control element extends outward to communicate with the second opening; The seventh channel extends downward from the first flow control surface of the first flow control element and extends outward from the lower end of the first flow control body of the first flow control element to connect with the fifth opening. connected; the eighth channel extends downward from the first flow control surface of the first flow control element and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the The sixth opening is connected, wherein the eleventh channel of the flow controller is connected with the tenth channel; wherein at least one of the tenth channel and the eleventh channel is connected from the first The first flow control surface of the flow control element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the third opening; The fourteenth channel and the fifteenth channel are respectively connected with the thirteenth channel; wherein at least one of the thirteenth channel, the fourteenth channel and the fifteenth channel is automatically The first flow control surface of the first flow control element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the fourth opening.

78. The flow controller according to claim 77, further comprising a flow isolation element extending downward from the first flow control body of the first flow control element, and the outer shell body of the outer shell extends downwardly from the first flow control body of the first flow control element. The lower end of the first flow control body of the first flow control element extends downward, wherein the flow isolation element and the housing body form a first gap between the flow isolation element and the housing body. A flow guide chamber, and the flow isolation element form a second flow guide chamber, wherein the second channel of the flow controller is connected with the first channel, wherein the first channel and the second At least one of the channels extends downward from the first flow control surface of the first flow control element and is connected with the first flow guide chamber; the fifth channel and the sixth channel of the flow control device are respectively connected with the fourth channel, wherein at least one of the fourth channel, the fifth channel and the sixth channel extends downward from the first flow control surface of the first flow control element and is connected with The second diversion chambers are connected.

79. The flow control device according to claim 60, further comprising a housing, and the first flow control body of the first flow control element of the flow control device further includes a first flow control body from the top end portion. a lower end extending downward, wherein the housing includes a housing body, wherein the housing body extends outwardly and upward from the lower end of the first flow control body of the first flow control element and surrounds a A first accommodation chamber, wherein the first accommodation chamber is connected with the conductive opening of the eighteenth channel.

80. The flow controller according to claim 65, wherein the housing has a first opening, a second opening, a third opening, a fourth opening, a fifth opening, and a sixth opening. , a seventh opening and an eighth opening, wherein the first accommodation chamber is connected with the first opening, and the ninth channel extends downward from the first flow control surface of the first flow control element and Extend outward from the lower end of the first flow control body of the first flow control element to communicate with the second opening; the tenth channel and the eleventh channel respectively extend from the first control body The first flow control surface of the flow element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the third opening; the thirteenth channel, The fourteenth channel and the fifteenth channel respectively extend downward from the first flow control surface of the first flow control element and extend outward from the lower end of the first flow control body of the first flow control element. Communicated with the fourth opening; the seventh channel extends downward from the first flow control surface of the first flow control element and extends from the lower end of the first flow control body of the first flow control element to Extending outward to communicate with the fifth opening; the eighth channel extends downward from the first flow control surface of the first flow control element and from the lower end of the first flow control body of the first flow control element. The end extends outward to communicate with the sixth opening; the sixteenth channel extends downward from the first flow control surface of the first flow control element and extends from the first flow control surface of the first flow control element. The lower end of the flow body extends outward to communicate with the seventh opening; the seventeenth channel extends downward from the first flow control surface of the first flow control element and extends from the first flow control element The lower end of the first flow control body extends outward to communicate with the eighth opening.

81. The flow controller according to claim 79, wherein the housing has a first opening, a second opening, a third opening, a fourth opening, a fifth opening, and a sixth opening. , a seventh opening and an eighth opening, wherein the first accommodation chamber is connected with the first opening, and the ninth channel extends downward from the first flow control surface of the first flow control element and from The lower end of the first flow control body of the first flow control element extends outward to communicate with the second opening; the tenth channel and the eleventh channel respectively extend from the first flow control body The first flow control surface of the element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the third opening; the thirteenth channel, the tenth channel The four channels and the fifteenth channel respectively extend downward from the first flow control surface of the first flow control element and extend outward from the lower end of the first flow control body of the first flow control element to connect with The fourth opening is connected; the seventh channel extends downward from the first flow control surface of the first flow control element and outwards from the lower end of the first flow control body of the first flow control element Extend to communicate with the fifth opening; the eighth channel extends downward from the first flow control surface of the first flow control element and from the lower end of the first flow control body of the first flow control element The sixteenth channel extends outward from the first flow control surface of the first flow control element and extends downward from the first flow control surface of the first flow control element. The lower end of the body extends outward to communicate with the seventh opening; the seventeenth channel extends from the first flow control surface of the first flow control element Extend downward and extend outward from the lower end of the first flow control body of the first flow control element to communicate with the eighth opening.

82. The flow control device according to claim 80, further comprising a wear-resistant element disposed between the first flow control element and the second flow control element, wherein the wear-resistant element has a Wear-resistant body, wherein the wear-resistant body has a wear-resistant surface suitable for contact with the second flow control surface of the second flow control body, and wherein the wear-resistant surface undergoes wear-resistant treatment.

83. The flow control device according to claim 81, further comprising a wear-resistant element disposed between the first flow control element and the second flow control element, wherein the wear-resistant element has a Wear-resistant body, wherein the wear-resistant body has a wear-resistant surface suitable for contact with the second flow control surface of the second flow control body, and wherein the wear-resistant surface undergoes wear-resistant treatment.

84. The flow controller according to claim 83, wherein the size and shape of the wear-resistant element are designed and formed according to the first flow control surface of the first flow control element of the flow controller, wherein the The wear-resistant element has a first interface, a second interface, a fourth interface, a fifth interface, a sixth interface, a seventh interface, an eighth interface, a ninth interface, a tenth interface, an eleventh interface, a thirteenth interface, a fourteenth interface, a fifteenth interface, a sixteenth interface and a seventeenth interface, wherein the first interface, the second interface, The fourth interface, the fifth interface, the sixth interface, the seventh interface, the eighth interface, the ninth interface, the tenth interface, the eleventh interface, the The thirteenth interface, the fourteenth interface, the fifteenth interface, the sixteenth interface and the seventeenth interface penetrate the wear-resistant body of the wear-resistant element up and down and are connected with the control unit in sequence. The first channel, the second channel, the fourth channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, and the ninth channel of the flow device , the tenth channel, the eleventh channel, the thirteenth channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel one by one correspond.

85. The flow controller according to claim 84, wherein the wear-resistant element is integrally formed with the first flow control body of the first flow control element.

86. The flow controller according to claim 81, further comprising a flow isolation element extending downward from the first flow control body of the first flow control element, and the housing body of the housing extends from The lower end of the first flow control body of the first flow control element extends outward and downward, wherein the flow isolation element and the housing body form a gap between the flow isolation element and the housing body. of A first flow guide chamber, and the flow isolation element form a second flow guide chamber, wherein the first channel and the second channel of the flow controller extend downward from the first flow control surface of the first flow control element and are respectively connected with the first flow guide chamber; the fourth channel, the fifth channel and the sixth channel of the flow control device extend downward from the first flow control surface of the first flow control element and are respectively connected with the first flow control chamber. The second diversion chamber is connected.

87. The flow controller according to claim 85, further comprising a flow isolation element extending downward from the first flow control body of the first flow control element, and the housing body of the housing extends from The lower end of the first flow control body of the first flow control element extends outward and downward, wherein the flow isolation element and the housing body form a gap between the flow isolation element and the housing body. The first flow guide chamber, and the flow isolation element form a second flow guide chamber, wherein the first channel and the second channel of the flow controller are downward from the first flow control surface of the first flow control element Extend and are respectively connected with the first flow guide chamber; the fourth channel, the fifth channel and the sixth channel of the flow control device extend downward from the first flow control surface of the first flow control element and are respectively connected with The second diversion chambers are connected.

88 The flow controller according to claim 87, further comprising a flow guide element, wherein the flow guide element includes a flow guide body, wherein the flow guide body is surrounded by a first flow guide channel , wherein the flow guide body of the flow guide element extends upward from the second flow control body of the second flow control element, and the first flow guide channel of the flow guide element is connected with the second flow control body of the flow controller. Thirteen channels are connected.

89. The flow controller according to claim 88, further comprising a driving element extending upward from the second flow control body of the second flow control element and a seal extending upward from the driving element. element, wherein the driving element is adapted to drive the second flow control body of the second flow control element of the flow controller to rotate relative to the first flow control body of the first flow control element; wherein the sealing element is adapted to is disposed in the housing and seals the first containing chamber.

90. The flow control device according to claim 60, further comprising a housing, and the first flow control body of the first flow control element of the flow control device further includes a first flow control body from the top end portion. a lower end extending downward, wherein the housing includes a housing body, wherein the housing body extends outwardly and upward from the lower end of the first flow control body of the first flow control element and surrounds a a first accommodation chamber, wherein the first accommodation chamber is connected with the conductive opening of the eighteenth channel, wherein the housing has a first opening, a second opening, a third opening, and a fourth opening , a fifth opening, a sixth opening, a seventh opening and an eighth opening, wherein the first accommodation chamber is connected with the first opening, and the ninth channel is from the first flow control element The first flow control surface extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the second opening; the seventh channel extends from the first The first flow control surface of the flow control element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the fifth opening; the eighth channel extends from the The first flow control surface of the first flow control element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the sixth opening; the tenth Six channels extend downward from the first flow control surface of the first flow control element and extend outward from the lower end of the first flow control body of the first flow control element to communicate with the seventh opening; The seventeenth channel extends downward from the first flow control surface of the first flow control element and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the eighth The openings are connected, wherein the eleventh channel of the flow controller is connected with the tenth channel; wherein at least one of the tenth channel and the eleventh channel is connected to the first flow control device. The first flow control surface of the element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the third opening; The fourteenth channel and the fifteenth channel are respectively connected with the thirteenth channel; wherein at least one of the thirteenth channel, the fourteenth channel and the fifteenth channel is from the The first flow control surface of the first flow control element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the fourth opening.

91. The flow controller according to claim 90, further comprising a flow isolation element extending downward from the first flow control body of the first flow control element, and the outer shell body of the outer shell extends downwardly from the first flow control body of the first flow control element. The lower end of the first flow control body of the first flow control element extends downward, wherein the flow isolation element and the housing body form a first gap between the flow isolation element and the housing body. A flow guide chamber, and the flow isolation element form a second flow guide chamber, wherein the second channel of the flow controller is connected with the first channel, wherein the first channel and the second At least one of the channels extends downward from the first flow control surface of the first flow control element and is connected with the first flow guide chamber; the fifth channel and the sixth channel of the flow control device are respectively connected with the fourth channel, wherein at least one of the fourth channel, the fifth channel and the sixth channel extends downward from the first flow control surface of the first flow control element and is connected with The second diversion chambers are connected.

92. A water treatment system, characterized by including:

a flow controller; and

A water treatment unit, wherein the water treatment unit is provided at the flow controller, and the water flow can flow between the water treatment unit and the flow controller under the control and guidance of the flow controller, wherein the flow control device includes a first flow control element, a second flow control element and a housing, wherein the first flow control element includes a first flow control body, and the first flow control body includes a top end part, wherein the top end part forms a first flow control surface; the second flow control element includes a second flow control body, the second flow control body has a bottom end part and a bottom end part. The upper end portion extends upward, and the bottom end portion forms a second flow control surface; wherein the second flow control surface of the second flow control element is adapted to be rotatably disposed on the first flow control element. a first flow control surface, wherein the flow control device has a first channel, a second channel, a fourth channel, a fifth channel, a sixth channel, a seventh channel, an eighth channel, and a third channel. Nine channels, a tenth channel, an eleventh channel, a thirteenth channel, a fourteenth channel, a fifteenth channel, a sixteenth channel, a seventeenth channel, an eighteenth channel, A nineteenth channel, a twentieth channel, a twenty-first channel, a twenty-second channel and a twenty-third channel, wherein the first channel, the second channel, the fourth channel channel, the fifth channel, the sixth channel, the seventh channel, the eighth channel, the ninth channel, the tenth channel, the eleventh channel, the thirteenth channel The channel, the fourteenth channel, the fifteenth channel, the sixteenth channel and the seventeenth channel are respectively provided in the first flow control body of the first flow control element and are connected from the first flow control element. The first flow control surface of the first flow control body of a flow control element extends downward; the nineteenth channel, the twentieth channel, the twenty-first channel, the twenty-second channel and all The twenty-third channels are respectively provided at the bottom end of the second flow control body and extend upward from the second flow control surface of the bottom end of the second flow control body, wherein the nineteenth channel and The twenty-first passages are respectively provided outside the twentieth passages and are respectively connected with the twentieth passages, wherein the first flow control body of the first flow control element of the flow controller further comprising a lower end extending downward from the top end, wherein the housing includes a housing body, wherein the housing body extends outward from the low end of the first flow control body of the first flow control element and extends upward and surrounds a first containing chamber, wherein the eighteenth channel is provided at the bottom end of the second flow control body and extends from the second control channel at the bottom end of the second flow control body. The flow surface extends upward and outward and forms a conductive opening that is always connected to the first accommodation chamber, wherein the housing has a first opening, a second opening, a third opening, and a fourth opening. , a fifth opening and a sixth opening, wherein the first accommodation chamber is connected with the first opening, and the ninth channel extends downward from the first flow control surface of the first flow control element and from The lower end of the first flow control body of the first flow control element extends outward to communicate with the second opening; the tenth channel and the eleventh channel extend from the first flow control element The first flow control surface extends downward and is connected with the third opening; the thirteenth channel, the fourteenth channel and the fifteenth channel are formed from the first flow control surface of the first flow control element The seventh channel extends downward from the first flow control surface of the first flow control element and extends downward from the first flow control body of the first flow control element. The lower end of the first flow control element extends outward to communicate with the fifth opening; the eighth channel extends downward from the first flow control surface of the first flow control element and extends from the first flow control surface of the first flow control element. The lower end of the flow control body extends outward to communicate with the sixth opening, wherein the first opening of the housing of the flow control device is connected with an external water source; The third opening, the fourth opening, the fifth opening and the sixth opening of the housing are respectively connected with the water treatment unit.

93. The water treatment system according to claim 92, wherein the flow controller further has a first conductive channel and a second conductive channel, wherein the first conductive channel and the second conductive channel Two conductive channels are respectively provided on the first flow control body of the first flow control element; wherein the first conductive channel extends from the seventh channel to the sixteenth channel and connects the seventh channel is connected to the sixteenth channel; the second conductive channel extends from the eighth channel to the seventeenth channel and connects the eighth channel to the seventeenth channel, wherein the The first edge portion of the top end of the first flow control body of the first flow control element of the flow control device includes a first outer edge portion and a first conductive portion extending outward from the first outer edge portion. ; The second edge portion of the bottom end portion of the second flow control body of the second flow control element includes a second outer edge portion and a first edge portion extending outward from the second outer edge portion. The sealing part, wherein the first channel and the tenth channel are respectively provided at the first outer edge of the first edge of the top end of the first flow control body of the first flow control element of the flow control device; The eighteenth channel is provided at the second outer edge of the second edge of the bottom end of the second flow control body of the second flow control element; the first conductive channel is provided at The first conductive portion of the first edge portion of the top end portion of the first flow control body of the first flow control element of the flow control device is connected from the first control portion of the first flow control body of the first flow control element. The flow surface extends downward; the second conductive channel is provided at the first conductive portion of the first edge portion of the top end of the first flow control body of the first flow control element of the flow controller and extends from the first conductive channel to the first conductive channel. The first flow control surface of the first flow control body of a flow control element extends downward; wherein when the second flow control element rotates relative to the first flow control element, the third flow control surface of the second flow control element The first sealing portion of the second edge portion of the bottom end of the second flow control body can separate the first conduction channel and the second conduction channel from the first flow control element of the flow control device. The first flow control body is separated by an external space above it.

94. The water treatment system according to claim 93, wherein the flow controller further includes a flow isolation element extending downward from the first flow control body of the first flow control element, and the The shell body of the shell extends downward from the lower end of the first flow control body of the first flow control element, wherein the flow isolation element and the shell body form a gap between the flow isolation element and the shell body. The first flow guide chamber between the first flow guide chamber and the flow isolation element forms a second flow guide chamber, wherein the second channel of the flow controller is connected with the first channel, wherein the first channel and at least one of the second channels extends downward from the first flow control surface of the first flow control element and is connected with the first flow guide chamber; the fifth channel of the flow control device and The sixth channel is connected to the fourth channel respectively, wherein at least one of the fourth channel, the fifth channel and the sixth channel is controlled by the first flow control element of the first flow control element. The surface extends downward and is connected with the second diversion chamber.

95. The water treatment system according to claim 94, wherein the water treatment unit includes a first water treatment element, a second water treatment element and a first ejector, wherein the first water treatment element The element has a first communication opening and a second communication opening, the second water treatment element has a third communication opening and a fourth communication opening, the first ejector has a fifth communication opening and a sixth communication opening. A communication opening, wherein the first communication opening of the first water treatment element and the first flow guide chamber of the flow control device; the second communication opening of the first water treatment element and the flow control device The second flow diversion chamber of the device is connected; the third communication opening of the second water treatment element is connected with the third opening of the flow controller; the fourth communication of the second water treatment element The opening is connected to the fourth opening of the flow controller; the fifth communication opening of the first ejector is connected to the fifth opening of the flow controller; all the openings of the first ejector are connected The sixth communication opening is connected with the sixth opening of the flow controller.

96. The water treatment system according to claim 95, wherein the first water treatment element includes a first water treatment part, and the second water treatment element has a second water treatment part, wherein when The water to be treated flows in from the first communication opening of the first water treatment element and flows out from the second communication opening of the first water treatment element, or from the second communication opening of the first water treatment element When the opening flows into and flows out from the first communication opening of the first water treatment element, the water to be treated is treated by the first water treatment part of the first water treatment element and treated water is obtained; when the water to be treated is Water flows in from the third communication opening of the second water treatment element and flows out from the fourth communication opening of the second water treatment element, or flows in from the fourth communication opening of the second water treatment element. and flows out from the third communication opening of the second water treatment element, the water to be treated is The second water treatment part of the treatment element treats and obtains treated water.

97. The water treatment system according to claim 96, wherein the water treatment unit further includes a liquid distribution tank, wherein when the first injector injects water into the flow controller, When the sixth opening of the housing is opened, the regeneration solution in the dosing box is sucked into the sixth opening of the housing of the flow controller, and the regeneration solution can flow to the flow controller under the control and guidance of the flow controller. The second water treatment element or the first water treatment element of the water treatment unit, so that the second water treatment part of the second water treatment element or the first water treatment part of the first water treatment element obtains regeneration.

98. The water treatment system according to claim 92, wherein the housing of the flow controller further has a seventh opening and an eighth opening, wherein the sixteenth channel extends from the first The first flow control surface of the flow control element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the seventh opening, and the seventeenth channel Extend downward from the first flow control surface of the first flow control element and extend outward from the lower end of the first flow control body of the first flow control element to communicate with the eighth opening, wherein The seventh opening and the eighth opening of the housing of the flow controller are respectively connected with the water treatment unit.

99. The water treatment system according to claim 98, wherein the flow controller further includes a flow isolation element extending downward from the first flow control body of the first flow control element, and the The shell body of the shell extends downward from the lower end of the first flow control body of the first flow control element, wherein the flow isolation element and the shell body form a gap between the flow isolation element and the shell body. The first flow guide chamber between the first flow guide chamber and the flow isolation element forms a second flow guide chamber, wherein the second channel of the flow controller is connected with the first channel, wherein the first channel and at least one of the second channels extends downward from the first flow control surface of the first flow control element and is connected with the first flow guide chamber; the fifth channel of the flow control device and The sixth channel is connected to the fourth channel respectively, wherein at least one of the fourth channel, the fifth channel and the sixth channel is controlled by the first flow control element of the first flow control element. The surface extends downward and is connected with the second diversion chamber.

100. The water treatment system according to claim 99, wherein the water treatment unit includes a first water treatment element, a second water treatment element, a first ejector and a second ejector, wherein The first water treatment element has a first communication opening and a second communication opening, the second water treatment element has a third communication opening and a fourth communication opening, and the first ejector has a fifth communication opening. a communication opening and a sixth communication opening, the second ejector has a seventh communication opening and an eighth communication opening, wherein all of the first water treatment element The first communication opening is connected to the first flow guide chamber of the flow controller; the second communication opening of the first water treatment element is connected to the second flow guide chamber of the flow controller; The third communication opening of the second water treatment element is connected with the third opening of the flow controller; the fourth communication opening of the second water treatment element is connected with the fourth opening of the flow controller are connected; the fifth communication opening of the first ejector is connected with the fifth opening of the flow controller; the sixth communication opening of the first ejector is connected with the flow controller The sixth opening of the second ejector is connected to the seventh communication opening of the second ejector and the seventh opening of the flow controller; The eighth communication opening of the second ejector is connected to Communicated with the eighth opening of the flow controller.

101. A flow controller, characterized in that it includes:

A first flow control element and a second flow control element rotatably provided on the first flow control element, wherein the first flow control element includes a first flow control body, and the first flow control body It includes a top end portion, wherein the top end portion forms a first flow control surface; the second flow control element includes a second flow control body, and the second flow control body has a bottom end portion and a first flow control surface. The bottom end portion extends upward and the high end portion forms a second flow control surface; wherein the second flow control surface of the second flow control element is adapted to be rotatably disposed on the first control surface. The first flow control surface of the flow element, wherein the flow control device has a first channel, a second channel, a fourth channel, a fifth channel, a sixth channel, a ninth channel, and a tenth channel , an eleventh channel, a thirteenth channel, a fourteenth channel, a fifteenth channel, an eighteenth channel, a nineteenth channel, a twentieth channel, a twenty-first channel and A twenty-third channel, wherein the first channel, the second channel, the fourth channel, the fifth channel, the sixth channel, the ninth channel, the tenth channel, The eleventh channel, the thirteenth channel, the fourteenth channel and the fifteenth channel are respectively provided on the first flow control body of the first flow control element and are connected from the first control body. The first flow control surface of the first flow control body of the flow element extends downward; the eighteenth channel is provided at the bottom end of the second flow control body and extends from the bottom end of the second flow control body. The second flow control surface extends upward and outward and forms a conductive opening that is always connected to the external space; the nineteenth channel, the twentieth channel, the twenty-first channel and the second Twenty-three channels are respectively provided at the bottom end of the second flow control body and extend upward from the second flow control surface of the bottom end of the second flow control body, wherein the nineteenth channel and the The twenty-first passages are respectively provided outside the twentieth passages and connected with the twentieth passages respectively.

102. The flow controller according to claim 101, characterized in that: the flow controller The nineteenth channel, the twentieth channel and the twenty-first channel respectively extend upward from the second flow control surface of the second flow control element to the high end of the second flow control element; The twenty-third channel extends upward from the second flow control surface of the second flow control element and penetrates the second flow control body of the second flow control element, wherein the nineteenth channel and the twentieth The channels are connected; the twenty-first channel extends upward and inward from the second flow control surface of the second flow control element, thereby being connected with the twentieth channel.

103. The flow controller according to claim 102, characterized in that, the flow controller has a first working position, a second working position, a third working position, a fourth working position, and a fifth working position. working position, a sixth working position, a seventh working position and an eighth working position, wherein when the flow controller is in the first working position, the eighteenth channel of the flow controller is connected to the first channel The nineteenth channel is connected to the fourth channel, the twentieth channel is connected to the ninth channel; when the flow controller is in the second working position, the eighteenth channel of the flow controller The channel is connected to the first channel, the nineteenth channel is connected to the fourth channel, the twentieth channel is connected to the ninth channel, the twenty-first channel is connected to the fourteenth channel, so The twenty-third channel is connected to the eleventh channel; when the flow controller is in the third working position, the eighteenth channel of the flow controller is connected to the first channel, and the nineteenth channel Connected to the fourth channel, the twentieth channel connected to the ninth channel, the twenty-first channel connected to the eleventh channel, the twenty-third channel connected to the fifteenth channel; When the flow controller is in the fourth working position, the eighteenth channel of the flow controller is connected to the first channel and the tenth channel respectively, and the nineteenth channel is connected to the fourth channel and the thirteenth channel respectively. The channels are connected, and the twentieth channel is connected with the ninth channel; when the flow controller is in the fifth working position, the eighteenth channel of the flow controller is connected with the tenth channel, and the The nineteenth channel is connected to the thirteenth channel, and the twentieth channel is connected to the ninth channel; when the flow controller is in the sixth working position, the eighteenth channel of the flow controller is connected to the tenth channel. The channels are connected, the nineteenth channel is connected with the thirteenth channel, the twentieth channel is connected with the ninth channel, the twenty-first channel is connected with the fifth channel, the twentieth channel is connected with the fifth channel, and the twentieth channel is connected with the fifth channel. The third channel is connected to the second channel; when the flow controller is in the seventh working position, the eighteenth channel of the flow controller is connected to the tenth channel, and the nineteenth channel is connected to the thirteenth channel are connected, the twentieth channel is connected to the ninth channel, the twenty-first channel is connected to the second channel, the twenty-third channel is connected to the sixth channel; when the flow controller When in the eighth working position, the eighteenth channel of the flow controller is connected to the first channel and the tenth channel respectively, and the nineteenth channel is connected to the fourth channel and the thirteenth channel respectively. No. The twentieth channel is connected to the ninth channel.

104. The flow controller according to claim 103, characterized in that when the flow controller is in the first working position, the second channel, the fifth channel, the sixth channel, the The tenth channel, the eleventh channel, the thirteenth channel and the fifteenth channel are respectively blocked by the second flow control body of the second flow control element of the flow controller, and the twentieth One channel is blocked by the first flow control body of the first flow control element of the flow controller; when the flow controller is in the second working position, the second channel, the fifth channel, the third The six channels, the tenth channel, the thirteenth channel and the fifteenth channel are respectively blocked by the second flow control body of the second flow control element of the flow controller; when the flow controller is in In the third working position, the second channel, the fifth channel, the sixth channel, the tenth channel, the thirteenth channel and the fourteenth channel are controlled by the flow controller respectively. The second flow control body of the second flow control element is blocked; when the flow controller is in the fourth working position, the second channel, the fifth channel, the sixth channel, the eleventh channel The channel and the fourteenth channel are respectively blocked by the second flow control body of the second flow control element of the flow controller, and the twenty-third channel is blocked by the third flow control element of the first flow control element of the flow controller. A flow control body is blocked; when the flow control device is in the fifth working position, the first channel, the second channel, the fourth channel, the sixth channel, the eleventh channel, The fourteenth channel and the fifteenth channel are respectively blocked by the second flow control body of the second flow control element of the flow controller, and the twenty-first channel is blocked by the first flow control element of the flow controller. The first flow control body of the flow control element is blocked; when the flow controller is in the sixth working position, the first channel, the fourth channel, the sixth channel, the eleventh channel, the The fourteenth channel and the fifteenth channel are respectively blocked by the second flow control body of the second flow control element of the flow controller; when the flow controller is in the seventh working position, the first The channel, the fourth channel, the fifth channel, the eleventh channel, the fourteenth channel and the fifteenth channel are respectively controlled by the second flow control element of the flow control device. The flow control body is blocked; when the flow controller is in the eighth working position, the second channel, the fifth channel, the eleventh channel, the fourteenth channel and the fifteenth channel They are respectively blocked by the second flow control body of the second flow control element of the flow controller, and the twenty-third channel is blocked by the first flow control body of the first flow control element of the flow controller.

105. The flow controller according to claim 104, wherein when the flow controller is in the first working position, the twenty-third channel is connected to the fourteenth channel; when the flow controller is in the first working position, the twenty-third channel is connected to the fourteenth channel; When the flow controller is in the fourth working position, the twenty-first channel is connected to the fifteenth channel; when the flow controller When the flow controller is in the fifth working position, the twenty-third channel is connected to the fifth channel; when the flow controller is in the eighth working position, the twenty-first channel is connected to the sixth channel. The channels are connected.

106. The flow controller according to claim 105, wherein the first channel of the flow controller is connected to the fourth channel, the fifth channel, the sixth channel, and the ninth channel respectively. The channel, the tenth channel, the eleventh channel, the thirteenth channel, the fourteenth channel and the fifteenth channel are spaced apart from each other on the first flow control element. A flow control body; the second channel is connected to the fourth channel, the fifth channel, the sixth channel, the ninth channel, the tenth channel, the eleventh channel, and the The thirteenth channel, the fourteenth channel and the fifteenth channel are spaced apart from each other on the first flow control body of the first flow control element; the fourth channel and the ninth channel are respectively The channel, the tenth channel, the eleventh channel, the thirteenth channel, the fourteenth channel and the fifteenth channel are spaced apart from each other on the first flow control element. a flow control body; the fifth channel and the ninth channel, the tenth channel, the eleventh channel, the thirteenth channel, the fourteenth channel and the fifteenth channel respectively Channels are spaced apart from the first flow control body of the first flow control element; the sixth channel is respectively connected with the ninth channel, the tenth channel, the eleventh channel, and the third channel. The thirteenth channel, the fourteenth channel and the fifteenth channel are spaced apart from each other on the first flow control body of the first flow control element; the ninth channel is respectively connected with the tenth channel, The eleventh channel, the thirteenth channel, the fourteenth channel and the fifteenth channel are spaced apart from each other on the first flow control body of the first flow control element; The ten channels are respectively separated from the thirteenth channel, the fourteenth channel and the fifteenth channel and are provided on the first flow control body of the first flow control element; the eleventh channel The first flow control body of the first flow control element is respectively separated from the thirteenth channel, the fourteenth channel and the fifteenth channel; the eighteenth channel is respectively separated from the The nineteenth channel, the twentieth channel, the twenty-first channel and the twenty-third channel are spaced apart from each other on the second flow control body of the second flow control element; The nineteenth channel, the twentieth channel, and the twenty-first channel are respectively provided in the second flow control body of the second flow control element and are spaced apart from the twenty-third channel.

107. The flow controller according to claim 106, wherein the top end portion of the first flow control body of the first flow control element of the flow controller includes a first central portion, and a first center portion from the first flow control body. a first intermediate portion extending outwardly from the first central portion, a first extension portion extending outwardly from the first intermediate portion and a first edge portion extending outwardly from the first extension portion, and said The bottom end of the second flow control body of the second flow control element includes a second center portion, and a second flow control element extending outward from the second center portion. an extended second middle portion, a second extension portion extending outwardly from the second middle portion and a second edge portion extending outwardly from the second extension portion, wherein the first channel and the tenth Channels are respectively provided at the first edge portion of the top portion; the second channel, the fifth channel, the sixth channel, the eleventh channel, the fourteenth channel and the The fifteenth channel is respectively provided at the first extension portion of the top end portion; the fourth channel and the thirteenth channel are respectively provided at the first middle portion of the top end portion; the ninth channel The channel is provided at the first central portion of the top end portion; the eighteenth channel is provided at the second edge portion of the bottom end portion; the nineteenth channel is provided at the second edge portion of the bottom end portion; The middle part; the twentieth channel is provided in the second central part of the bottom end part; the twenty-first channel and the twenty-third channel are respectively provided in the second extension part.

108. The flow controller according to claim 107, characterized in that, the first flow control surface of the first flow control element and the second flow control surface of the second flow control element of the flow controller are both circular. , wherein the second channel, the fifth channel, the fifteenth channel, the eleventh channel, the fourteenth channel and the sixth channel of the flow controller are arranged clockwise in this order on the first flow control element. The first flow control body; the twenty-third channel and the twenty-first channel of the flow control device are arranged clockwise in this order on the second flow control body of the second flow control element.

109. The flow controller according to claim 108, characterized in that: the first channel, the second channel, the fourth channel, the fifth channel, the sixth channel, the third channel The nine channels, the tenth channel, the eleventh channel, the thirteenth channel, the fourteenth channel and the fifteenth channel are all arranged radially on the first flow control element. The first flow control surface, and the eighteenth channel, the nineteenth channel, the twentieth channel, the twenty-first channel and the twenty-third channel are respectively located radially on The second flow control surface of the second flow control element.

110. The flow controller according to claim 109, wherein the first flow control surface of the first flow control element of the flow controller has a central portion, wherein the central portion is provided on the first The first central part of the top end of the first flow control body of the flow control element, and the part other than the central part of the first flow control surface is divided clockwise into a first part, a second part, and a first part. three parts, a fourth part, a fifth part, a sixth part, a seventh part and an eighth part; the second flow control surface of the second flow control element of the flow controller has a central area, Wherein the central area is provided at the second central part of the bottom end of the second flow control body of the second flow control element, and the part outside the central area of the second flow control surface is equally divided clockwise. For a first area, a second area, a third area, a fourth area, a fifth area, and a sixth area domain, a seventh region and an eighth region; wherein the first channel extends from the first part, the second part, the third part and the fourth part of the first flow control surface to Extend downward; The second channel extends downward from the second part of the first flow control surface; The fourth channel extends downward from the first part, the second part, and all of the first flow control surface. The third part and the fourth part extend downward; the fifth channel extends downward from the third part of the first flow control surface; the sixth channel extends downward from all parts of the first flow control surface. The first part extends downward; the ninth channel extends downward from the central part of the first flow control surface; the tenth channel extends from the fifth part of the first flow control surface, the third Six parts, the seventh part and the eighth part extend downward; the eleventh channel extends downward from the sixth part of the first flow control surface; the thirteenth channel extends downward from the first flow control surface; The fifth part, the sixth part, the seventh part and the eighth part of a flow control surface extend downward; the fourteenth channel extends from the seventh part of the first flow control surface Extend downward; The fifteenth channel extends downward from the fifth part of the first flow control surface; The eighteenth channel extends from the third area of the second flow control surface and the The fourth area extends upward; the nineteenth channel extends upward from the third area and the fourth area of the second flow control surface; the twentieth channel extends from the second flow control surface The central area extends upward; the twenty-first channel extends upward from the eighth area of the second flow control surface; the twenty-third channel extends upward from the seventh area of the second flow control surface.

111. The flow control device according to claim 101, further comprising a housing, and the first flow control body of the first flow control element of the flow control device further includes a first flow control body from the top end portion. a lower end extending downward, wherein the housing includes a housing body, wherein the housing body extends outwardly and upward from the lower end of the first flow control body of the first flow control element and surrounds a A first accommodation chamber, wherein the first accommodation chamber is connected with the conductive opening of the eighteenth channel.

112. The flow control device according to claim 110, further comprising a housing, and the first flow control body of the first flow control element of the flow control device further includes a first flow control body from the top end portion. a lower end extending downward, wherein the housing includes a housing body, wherein the housing body extends outwardly and upward from the lower end of the first flow control body of the first flow control element and surrounds a A first accommodation chamber, wherein the first accommodation chamber is connected with the conductive opening of the eighteenth channel.

113. The flow controller according to claim 111, wherein the housing has a first opening, a second opening, a third opening and a fourth opening, wherein the first container The holding chamber is connected to the first opening, and the ninth channel extends downward from the first flow control surface of the first flow control element and from the lower end of the first flow control body of the first flow control element. extends outward to communicate with the second opening; the tenth channel and the eleventh channel respectively extend downward from the first flow control surface of the first flow control element and extend from the first control surface The lower end of the first flow control body of the flow element extends outward to communicate with the third opening; the thirteenth channel, the fourteenth channel and the fifteenth channel are respectively from the A first flow control surface of a flow control element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the fourth opening.

114. The flow controller according to claim 112, wherein the housing has a first opening, a second opening, a third opening and a fourth opening, wherein the first accommodation chamber and the The first openings are connected, and the ninth channel extends downward from the first flow control surface of the first flow control element and extends outward from the lower end of the first flow control body of the first flow control element. to communicate with the second opening; the tenth channel and the eleventh channel respectively extend downward from the first flow control surface of the first flow control element and extend downward from the first flow control surface of the first flow control element. The lower end of a flow control body extends outward to communicate with the third opening; the thirteenth channel, the fourteenth channel and the fifteenth channel respectively extend from the first flow control element The first flow control surface extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the fourth opening.

115. The flow controller according to claim 111, wherein the flow controller further includes a wear-resistant element disposed between the first flow control element and the second flow control element, wherein the The wear-resistant element has a wear-resistant body, wherein the size and shape of the wear-resistant element are designed and formed according to the first flow control surface of the first flow control element of the flow controller, wherein the wear-resistant element has a third A first interface, a second interface, a fourth interface, a fifth interface, a sixth interface, a ninth interface, a tenth interface, an eleventh interface, a thirteenth interface, a fourteenth interface and a fifteenth interface, wherein the first interface, the second interface, the fourth interface, the fifth interface, the sixth interface, the ninth interface, the tenth interface, The eleventh interface, the thirteenth interface, the fourteenth interface and the fifteenth interface penetrate up and down the wear-resistant body of the wear-resistant element and are connected with the first channel, the said the second channel, the fourth channel, the fifth channel, the sixth channel, the ninth channel, the tenth channel, the eleventh channel, the thirteenth channel, the The fourteenth channel corresponds to the fifteenth channel one-to-one.

116. The flow controller according to claim 114, wherein the flow controller further includes a wear-resistant element disposed between the first flow control element and the second flow control element, wherein the The wear-resistant element has a wear-resistant body, wherein the size and shape of the wear-resistant element are designed and formed according to the first flow control surface of the first flow control element of the flow controller, wherein the wear-resistant element has a third A first interface, a second interface, a fourth interface, a fifth interface, a sixth interface, a ninth interface, a tenth interface, an eleventh interface, a thirteenth interface, a fourteenth interface and a fifteenth interface, wherein the first interface, the second interface, the fourth interface, the fifth interface, the sixth interface, the ninth interface, the tenth interface, The eleventh interface, the thirteenth interface, the fourteenth interface and the fifteenth interface penetrate up and down the wear-resistant body of the wear-resistant element and are sequentially connected with the flow controller. The first channel, the second channel, the fourth channel, the fifth channel, the sixth channel, the ninth channel, the tenth channel, the eleventh channel, the The thirteenth channel, the fourteenth channel and the fifteenth channel correspond one to one.

117. The flow controller according to claim 116, wherein the wear-resistant element is integrally formed with the first flow control body of the first flow control element.

118. The flow controller according to claim 111, further comprising a flow isolation element extending downward from the first flow control body of the first flow control element, and the housing body of the housing extends from The lower end of the first flow control body of the first flow control element extends outward and downward, wherein the flow isolation element and the housing body form a gap between the flow isolation element and the housing body. The first flow guide chamber, and the flow isolation element form a second flow guide chamber, wherein the first channel and the second channel of the flow controller are downward from the first flow control surface of the first flow control element Extend and are respectively connected with the first flow guide chamber; the fourth channel, the fifth channel and the sixth channel of the flow control device extend downward from the first flow control surface of the first flow control element and are respectively connected with The second diversion chambers are connected.

119. The flow controller according to claim 117, further comprising a flow isolation element extending downward from the first flow control body of the first flow control element, and the housing body of the housing extends from The lower end of the first flow control body of the first flow control element extends outward and downward, wherein the flow isolation element and the housing body form a gap between the flow isolation element and the housing body. The first flow guide chamber, and the flow isolation element form a second flow guide chamber, wherein the first channel and the second channel of the flow controller are downward from the first flow control surface of the first flow control element Extend and are respectively connected with the first flow guide chamber; the fourth channel, the fifth channel and the sixth channel of the flow control device extend downward from the first flow control surface of the first flow control element and are respectively connected with The second diversion chambers are connected.

120. The flow controller according to claim 119, further comprising a guide Flow element, wherein the flow guide element includes a flow guide body, wherein the flow guide body is surrounded by a first flow guide channel, and wherein the flow guide body of the flow guide element is formed from the second flow control body. The second flow control body of the element extends upward, and the first flow guide channel of the flow guide element is connected with the twenty-third channel of the flow controller.

121. The flow controller according to claim 120, further comprising a driving element extending upward from the second flow control body of the second flow control element and a seal extending upward from the driving element. element, wherein the driving element is adapted to drive the second flow control body of the second flow control element of the flow controller to rotate relative to the first flow control body of the first flow control element; wherein the sealing element is adapted to is disposed in the housing and seals the first containing chamber.

122. The flow control device according to claim 102, further comprising a housing, and the first flow control body of the first flow control element of the flow control device further includes a first flow control body from the top end portion. a lower end extending downward, wherein the housing includes a housing body, wherein the housing body extends outwardly and upward from the lower end of the first flow control body of the first flow control element and surrounds a A first accommodation chamber, wherein the first accommodation chamber is connected with the conductive opening of the eighteenth channel, wherein the housing has a first opening, a second opening, a third opening and a fourth opening , wherein the first accommodation chamber is connected with the first opening, and the ninth channel extends downward from the first flow control surface of the first flow control element and from the first flow control surface of the first flow control element. The lower end of the flow control body extends outward to communicate with the second opening; wherein the eleventh channel of the flow control device is connected with the tenth channel; wherein the tenth channel and the At least one of the eleventh channels extends downward from the first flow control surface of the first flow control element and extends outward from the lower end of the first flow control body of the first flow control element to communicate with The third opening is connected; the fourteenth channel and the fifteenth channel of the flow controller are respectively connected with the thirteenth channel; wherein the thirteenth channel, the tenth channel At least one of the four channels and the fifteenth channel extends downward from the first flow control surface of the first flow control element and outwards from the lower end of the first flow control body of the first flow control element. Extend to communicate with the fourth opening.

123. The flow control device according to claim 110, further comprising a housing, and the first flow control body of the first flow control element of the flow control device further includes a first flow control body from the top end portion. a lower end extending downward, wherein the housing includes a housing body, wherein the housing body extends outwardly and upward from the lower end of the first flow control body of the first flow control element and surrounds a a first accommodation chamber, wherein the first accommodation chamber is connected to the conductive opening of the eighteenth channel through, wherein the housing has a first opening, a second opening, a third opening and a fourth opening, wherein the first accommodation chamber is connected with the first opening, and the ninth passage is from the The first flow control surface of the first flow control element extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the second opening; The eleventh channel of the flow device is connected with the tenth channel; wherein at least one of the tenth channel and the eleventh channel is downward from the first flow control surface of the first flow control element. Extend and extend outward from the lower end of the first flow control body of the first flow control element to communicate with the third opening; the fourteenth channel of the flow control device and the fourth Fifteen channels are respectively connected with the thirteenth channel; wherein at least one of the thirteenth channel, the fourteenth channel and the fifteenth channel is connected from the first channel of the first flow control element. The flow control surface extends downward and extends outward from the lower end of the first flow control body of the first flow control element to communicate with the fourth opening.

124. The flow controller according to claim 123, further comprising a flow isolation element extending downward from the first flow control body of the first flow control element, and the outer shell body of the outer shell extends downwardly from the first flow control body of the first flow control element. The lower end of the first flow control body of the first flow control element extends downward, wherein the flow isolation element and the housing body form a first gap between the flow isolation element and the housing body. A flow guide chamber, and the flow isolation element form a second flow guide chamber, wherein the second channel of the flow controller is connected with the first channel, wherein the first channel and the second At least one of the channels extends downward from the first flow control surface of the first flow control element and is connected with the first flow guide chamber; the fifth channel and the sixth channel of the flow control device are respectively connected with the fourth channel, wherein at least one of the fourth channel, the fifth channel and the sixth channel extends downward from the first flow control surface of the first flow control element and is connected with The second diversion chambers are connected.

125. The flow control device according to claim 124, further comprising a wear-resistant element disposed between the first flow control element and the second flow control element, wherein the wear-resistant element has a Wear-resistant body, wherein the size and shape of the wear-resistant element are designed and formed according to the first flow control surface of the first flow control element of the flow controller, wherein the wear-resistant element has a first interface, a first Two interfaces, a fourth interface, a fifth interface, a sixth interface, a ninth interface, a tenth interface, an eleventh interface, a thirteenth interface, a fourteenth interface and a fifteenth interface Interface, wherein the first interface, the second interface, the fourth interface, the fifth interface, the sixth interface, the ninth interface, the tenth interface, the eleventh interface The interface, the thirteenth interface, the fourteenth interface and the fifteenth interface pass through the wear-resistant element up and down. The wear-resistant body is connected to the first channel, the second channel, the fourth channel, the fifth channel, the sixth channel, the ninth channel, and the flow controller in sequence. The tenth channel, the eleventh channel, the thirteenth channel, the fourteenth channel and the fifteenth channel correspond one to one.

126. The flow controller according to claim 125, wherein the wear-resistant element is integrally formed with the first flow control body of the first flow control element.

127. The flow controller according to claim 126, further comprising a flow guide element, wherein the flow guide element includes a flow guide body, wherein the flow guide body is surrounded by a first flow guide channel, wherein the flow-guiding body of the flow-guiding element extends upward from the second flow-controlling body of the second flow-controlling element, and the first flow-guiding channel of the flow-guiding element is connected with the third flow-guiding device of the flow controller. Twenty-three channels are connected.

128. The flow controller according to claim 127, further comprising a driving element extending upward from the second flow control body of the second flow control element and a seal extending upward from the driving element. element, wherein the driving element is adapted to drive the second flow control body of the second flow control element of the flow controller to rotate relative to the first flow control body of the first flow control element; wherein the sealing element is adapted to is disposed in the housing and seals the first containing chamber.

129. A water treatment system, characterized by including:

a flow controller; and

wherein the flow control device includes a first flow control element, a second flow control element and a housing, wherein the first flow control element includes a first flow control body, and the first flow control body includes a top end part, wherein the top end part forms a first flow control surface; the second flow control element includes a second flow control body, the second flow control body has a bottom end part and a bottom end part. The upper end portion extends upward, and the bottom end portion forms a second flow control surface; wherein the second flow control surface of the second flow control element is adapted to be rotatably disposed on the first flow control element. a first flow control surface, wherein the flow control device has a first channel, a second channel, a fourth channel, a fifth channel, a sixth channel, a ninth channel, a tenth channel, a first An eleventh channel, a thirteenth channel, a fourteenth channel, a fifteenth channel, an eighteenth channel, a nineteenth channel, a twentieth channel, a twenty-first channel and a second Thirteen channels, wherein the first channel, the second channel, the fourth channel, the fifth channel, the sixth channel, The ninth channel, the tenth channel, the eleventh channel, the thirteenth channel, the fourteenth channel and the fifteenth channel are respectively provided on the first flow control element. The first flow control body extends downward from the first flow control surface of the first flow control body of the first flow control element; the nineteenth channel, the twentieth channel, and the twenty-first channel and the twenty-third channel are respectively provided at the bottom end of the second flow control body and extend upward from the second flow control surface of the bottom end of the second flow control body, wherein the nineteenth The channel and the twenty-first channel are respectively provided outside the twentieth channel and are respectively connected with the twentieth channel, wherein the first control element of the first flow control element of the flow controller The flow body further includes a lower end extending downward from the top end, wherein the housing includes a housing body, wherein the housing body extends from the lower end of the first flow control body of the first flow control element. Extending outward and upward and surrounding a first containing chamber, the eighteenth channel is provided at the bottom end of the second flow control body and starts from the third channel at the bottom end of the second flow control body. The second flow control surface extends upward and outward and forms a conductive opening that is always connected to the first containing chamber, wherein the housing has a first opening, a second opening, a third opening and a third opening. Four openings, wherein the first accommodation chamber is connected with the first opening, and the ninth channel extends downward from the first flow control surface of the first flow control element and from the first flow control element. The lower end of the first flow control body extends outward to communicate with the second opening; the tenth channel and the eleventh channel extend downward from the first flow control surface of the first flow control element and are all connected with the third opening; the thirteenth channel, the fourteenth channel and the fifteenth channel extend downward from the first flow control surface of the first flow control element and are all connected with the The fourth opening is connected, wherein the first opening of the housing of the flow controller is connected with an external water source; the third opening and the fourth opening of the housing of the flow controller are respectively Connected to the water treatment unit.

130. The water treatment system according to claim 129, wherein the flow controller further includes a flow isolation element extending downward from the first flow control body of the first flow control element, and the The shell body of the shell extends downward from the lower end of the first flow control body of the first flow control element, wherein the flow isolation element and the shell body form a gap between the flow isolation element and the shell body. The first flow guide chamber between the first flow guide chamber and the flow isolation element forms a second flow guide chamber, wherein the second channel of the flow controller is connected with the first channel, wherein the first channel and at least one of the second channels extends downward from the first flow control surface of the first flow control element and is connected with the first flow guide chamber; the fifth channel of the flow control device and The sixth channel is respectively connected with the fourth channel, wherein at least one of the fourth channel, the fifth channel and the sixth channel is One extends downward from the first flow control surface of the first flow control element and is connected with the second flow guide chamber.

131. The water treatment system of claim 130, wherein the water treatment unit includes a first water treatment element and a second water treatment element, wherein the first water treatment element has a first communication opening and a second communication opening, the second water treatment element has a third communication opening and a fourth communication opening, wherein the first communication opening of the first water treatment element and the flow controller The first flow diversion chamber is connected; the second communication opening of the first water treatment element is connected with the second flow diversion chamber of the flow controller; the third communication of the second water treatment element The opening is connected to the third opening of the flow controller; and the fourth communication opening of the second water treatment element is connected to the fourth opening of the flow controller.

132. The water treatment system according to claim 131, wherein the first water treatment element includes a first water treatment part, and the second water treatment element has a second water treatment part, wherein when The water to be treated flows in from the first communication opening of the first water treatment element and flows out from the second communication opening of the first water treatment element, or from the second communication opening of the first water treatment element When the opening flows into and flows out from the first communication opening of the first water treatment element, the water to be treated is treated by the first water treatment part of the first water treatment element and treated water is obtained; when the water to be treated is Water flows in from the third communication opening of the second water treatment element and flows out from the fourth communication opening of the second water treatment element, or flows in from the fourth communication opening of the second water treatment element. When flowing out from the third communication opening of the second water treatment element, the water to be treated is treated by the second water treatment part of the second water treatment element and treated water is obtained.

133. A multifunctional control valve for continuous water supply, including a valve body, a cover, a fixed valve plate and a movable valve plate that are placed in the valve body and adopt end-face rotation sealing. The movable valve plate is connected to the valve stem, and the control valve is It is provided with a water inlet, a water outlet, a sewage outlet, a first interface of the No. 1 filter element, a second interface of the No. 1 filter element, a first interface of the No. 2 filter element and a second interface of the No. 2 filter element. The characteristic is that the fixed valve piece is provided with : the first through hole, the second through hole, the third through hole and the fourth through hole pass through the internal flow channel of the control valve, the first through hole is connected to the first interface of the No. 1 filter element, the third through hole The second through hole is connected to the second interface of the No. 1 filter element, the third through hole is connected to the first interface of the No. 2 filter element, and the fourth through hole is connected to the second interface of the No. 2 filter element. ; The moving valve piece is provided with a water inlet channel, an outlet channel and a sewage flow channel. Through the internal flow channel of the control valve, the water inlet channel is connected to the water inlet, and the water outlet channel is connected to the outlet. The water inlet is connected, and the sewage discharge flow channel is connected with the sewage discharge outlet.

134. The continuous water supply multifunctional control valve according to claim 133, characterized in that: the first through hole and the third through hole of the fixed valve plate are provided on the outer ring and the middle ring of the fixed valve plate, so The second through hole and the fourth through hole of the fixed valve plate are provided on the middle ring and the inner ring of the fixed valve plate.

135. The continuous water supply multifunctional control valve according to claim 134, characterized in that: the water inlet channel of the movable valve plate is arranged on the outer ring of the movable valve plate; the water outlet channel of the movable valve plate It is arranged on the center, the inner ring and the middle ring of the moving valve plate; the sewage flow channel of the moving valve plate is arranged on the middle ring of the moving valve plate.

136. The continuous water supply multifunctional control valve according to claim 135, characterized in that: the center of the fixed valve plate is further provided with a ninth through hole, and the water outlet channel of the movable valve plate is a water outlet blind hole. , the water outlet blind hole is connected to the water outlet through the ninth through hole.

137. The continuous water supply multi-function control valve according to claim 136, characterized in that: the water outlet blind hole includes a bottom seal, side walls extending upward along the bottom seal and a beam located between the side walls, the beam is provided at the top of the side wall.

138. The continuous water supply multifunctional control valve according to claim 137, characterized in that: the sewage flow channel is a sewage through hole, the sewage outlet is provided on the cover, and the sewage through hole passes through the valve stem in sequence. The first drain through hole and the second drain through hole on the cover are connected to the drain outlet on the cover.

139. The continuous water supply multi-function control valve according to claim 137, characterized in that: the sewage flow channel is a sewage through hole, the sewage outlet is provided on the valve body, and the sewage through hole passes through the valve stem in turn. The first drain through hole and the second drain through hole on the cover are connected to the drain outlet on the valve body.

140. The continuous water supply multifunctional control valve according to any one of claims 133 to 139, characterized in that: the control valve is also provided with an ejector and a salt suction port, and the control valve is also provided with a The ejector outlet and the ejector inlet are connected to the ejector; the fixed valve plate is also provided with an ejector outlet flow channel and an ejector inlet flow channel. Through the internal flow channel of the control valve, the ejector outlet The flow channel is connected with the outlet of the ejector, and the flow channel with the inlet of the ejector is connected with the inlet of the ejector; the moving valve piece is also provided with a blind hole for communication.

141. The continuous water supply multifunctional control valve according to claim 140, characterized in that: the ejector outlet flow channel of the fixed valve plate includes a fifth through hole and a sixth through hole, passing through the internal flow channel of the control valve, The fifth through hole and the sixth through hole are connected with each other and with the ejector outlet; the ejector inlet channel of the fixed valve plate includes a seventh through hole and an eighth through hole, passing through the interior of the control valve flow channel, the seventh through hole and the eighth through hole are connected with each other and with the injector inlet; the fifth through hole The hole, the sixth through hole, the seventh through hole and the eighth through hole are provided on the middle ring of the fixed valve plate; the blind conduction hole of the moving valve plate is provided on the middle ring of the moving valve plate.

142. The continuous water supply multifunctional control valve according to any one of claims 133 to 139, characterized in that: the control valve is also provided with a No. 1 ejector, a No. 2 ejector, a No. 1 salt suction port and a No. 2 ejector. Salt suction port, the control valve is also provided with a No. 1 ejector outlet and a No. 1 ejector inlet that are connected to the No. 1 ejector, and is also provided with a No. 2 ejector outlet and a No. 2 ejector that are connected to the No. 2 ejector. No. 2 ejector inlet; the fixed valve plate is also provided with a fifth through hole, a sixth through hole, a seventh through hole and an eighth through hole, passing through the internal flow channel of the control valve, the fifth through hole The seventh through hole is connected with the outlet of the first injector, the sixth through hole is connected with the outlet of the second injector, and the eighth through hole is connected with the outlet of the second injector. The hole is connected with the inlet of the No. 2 ejector; the moving valve plate is also provided with a blind conduction hole; the fifth through hole, the sixth through hole, the seventh through hole and the eighth through hole are provided in the on the middle ring of the fixed valve plate; and the conduction blind hole of the movable valve plate is arranged on the middle ring of the movable valve plate.