KR20170050576A - Flow path switching valve and Water treatment apparatus having the same - Google Patents

Abstract

The present invention relates to a passage switching valve and a water treating device including the same capable of simplifying a structure by decreasing the number of components; and conveniently and accurately performing a passage switching operation. The passage switching valve comprises: a valve body which includes a plurality of inlets which are connected to different passages, and an outlet which discharges fluids from the inlets; a rotator which is rotated inside the valve body, and forms a connection passage to enable one of the inlets to be selectively connected to the outlet depending on a rotated position; and a valve cover which is connected to the valve body, and supports the rotator to be rotated. The connection passage is formed along the outer circumference of the rotator.

Description

[0001] The present invention relates to a flow path switching valve and a water treatment apparatus having the same,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flow path switching valve and a water treatment apparatus having the same and, more particularly, to a flow path switching valve for selectively connecting a flow path connected to a plurality of inlet ports by a rotation operation, .

A water treatment device such as a water purifier is designed to remove heavy metals and other harmful substances contained in raw water through processes such as sedimentation, filtration, sterilization, and adsorption of raw water such as tap water. Such water purifiers are used not only for general household and business use, It is widely used in the scientific industry and cleaning or medical use of ultra-precision electronic components.

Conventionally, the water purifier is provided with only a single cock valve so that the user can use the purified water by supplying only the purified water. In recent years, the water purifier is provided with a heater and a cooler so that the user can selectively use purified water, cold water and hot water.

In this way, it is necessary to implement a complicated flow path for supplying purified water, cold water, and hot water while increasing the range of water types available to the user in the water purifier. In order to realize such flow path, a plurality of tubes and fittings There is a problem of not only having to use but also increasing the leakage point. To solve this problem, there is a need for a device for selectively switching a plurality of different flow paths using a single valve.

Korean Unexamined Patent Publication No. 10-2012-0109715 is disclosed as such a conventional channel switching valve. The conventional channel switching valve is provided with three inlet portions and one outlet portion and is configured such that water in different states is discharged according to the selected angle when the rotary portion is rotated by 90 °, 180 °, and 270 ° .

However, according to this configuration, since the stepping motor is used to rotate the rotary part, the unit price is increased, and the sealing projection is provided around the opening to maintain the watertightness of the opening formed in the rotary part, There is a problem that the assemblability is poor.

In addition, when the user manually implements the channel switching, it is difficult to implement a structure that allows the user to recognize that the channel switching operation has been completed.

Also, in the case of rotation of the swivel portion, only one inflow portion should be located exactly in the corresponding opening, and if the two inflow portions are located so as to communicate partly to the corresponding opening by a malfunction, There is a problem that the water flows backward.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a flow path switching valve capable of simplifying a structure by reducing the number of components and simplifying and accurately performing a flow path switching operation.

It is another object of the present invention to provide a water treatment apparatus provided with a flow path switching valve which can precisely switch the flow path and prevent the flow of fluid between a plurality of inlet ports to prevent leakage due to the back flow of the fluid.

In order to achieve the above object, according to the present invention, there is provided a flow path switching valve comprising: a valve body having a plurality of inlet ports connected to different flow paths and a discharge port through which fluid introduced through the inlet port is discharged; A rotator rotatably installed in the valve body and forming a connection channel so that any one of the plurality of inlet ports selectively communicates with the outlet port according to a rotated position; And a valve cover fastened to the valve body and rotatably supporting the rotator, wherein the connection passage is formed along the outer circumference of the rotator.

The connection channel may include a connection hole corresponding to the plurality of inlet ports and a connection groove connecting the connection hole and the outlet port.

Wherein the plurality of inlet ports are formed on a rear surface of the valve body in a circumferential direction, the outlet port is formed on one side surface of the valve body, the connection hole is formed in a rear surface of the rotator, The connection groove may be formed to communicate with the outer surface of the rotator in the circumferential direction.

A locking protrusion may be formed on one side of the rotator and a first locking protrusion and a second locking protrusion may be formed on the valve body so that the locking protrusion may be engaged to restrict a bi-directional rotation radius of the rotator.

Wherein when the rotator is rotated in one direction and the locking protrusion is caught by the first locking protrusion, the inlet port located at one side of the plurality of inlet ports communicates with the connection channel and the outlet port, and the rotator is rotated in the opposite direction, And when the second latching jaw is hooked, the inlet port located at the other of the plurality of inlet ports communicates with the connection channel and the outlet port.

The valve cover is formed with a protrusion on one side of the rotator, and the valve cover is engaged with the locking protrusion by the rotation of the rotator to be resiliently displaced and is restored to generate a contact sound, The first hook portion and the second hook portion may be formed.

A plurality of fastening protrusions may be formed on one of the valve body and the valve cover and a plurality of fastening rings may be formed on the other of the valve body and the valve cover so as to be engaged with the fastening protrusion.

A seal member for watertightness maintenance may be provided between the plurality of inlet ports and the rotator, and between the valve body and the rotator.

The water treatment apparatus of the present invention comprises: a first flow path connecting a cold water discharge pipe to which cold water is supplied and a first water pipe; A second flow path connecting the stationary export water pipe to which the purified water is supplied and the first water pipe; A flow path switching valve provided at an intersection of the cold export water pipe and the regular export water pipe for switching the flow path to supply either the cold water or the purified water to the first water pipe; And a first storage tank in which cold water supplied to the cold export water pipe is stored, wherein the flow path switching valve includes an operation section in which cold water or purified water is discharged through the first flow path or the second flow path, And a non-operating period in which both outflow of cold water and purified water through the flow path and the second flow path are blocked.

The first storage tank may be provided with a ball tower that mechanically blocks the inflow of water when the water level becomes a certain level.

The rotator may be rotated by manual operation of the user.

According to an aspect of the present invention, there is provided a flow path switching valve comprising: a valve body having a plurality of inlet ports and a single outlet port; a rotator formed along a circumferential surface of a connecting flow path for selectively connecting one of the plurality of inlet ports to the outlet port, And a valve cover rotatably supporting the rotator, so that the structure of the flow path switching valve can be simplified.

The valve cover is provided with a first hook portion and a second hook portion which generate elasticity displacement and restoration and contact sound due to interference with the engagement protrusion, It can be easily recognized that the switching of the flow path is completed, so that the switching of the flow path can be accurately performed.

Also, since the non-operation section in which the flow of the fluid is interrupted between the plurality of inlet and outlet ports is provided within the range of the rotation radius of the rotator, leakage of the fluid due to the reverse flow of fluid can be prevented by interrupting the flow of fluid between the plurality of inlet ports.

Further, by sealing the sealing member between the first inlet and the valve body, between the second inlet and the valve body, and between the valve body and the rotator, watertightness can be maintained so that leakage of water can be effectively blocked while minimizing the number of installation of the sealing member, The sealing member can be easily combined.

In addition, since the valve body and the valve cover are provided with the fastening protrusion and the fastening ring, the fastening structure between the valve body and the valve cover can be simplified.

According to the water treatment apparatus of the present invention, since the non-operation section in which the flow of the fluid is interrupted between the plurality of inlet and outlet ports within the rotation radius range of the rotator is provided, fluid inflow between the plurality of inlet ports is blocked, The water overflow phenomenon of the first storage tank can be prevented.

1 is a perspective view of a flow path switching valve of the present invention,
2 is an exploded perspective view of the flow path switching valve of the present invention,
FIG. 3 is a front view (a) of the flow path switching valve of the present invention, FIG. 3 (b)
4 is a front view (a), a side view (b) of the valve body,
FIG. 5 is a front view of the rotator, (b) a side view, (c) a rear view, (d)
Figure 6 shows (a) a perspective view, (b) cross-section,
7 is a perspective view showing the valve body and the rotator,
8 is a front view, (b) side view, (c) rear view, (d) plan view,
FIG. 9 is an operational state diagram showing a process of switching the flow path by rotation of the rotator,
10 is a front view of the valve body and the rotator showing the turning radius of the rotator, (b) a perspective view of the valve body,
11 is a view showing an operating section and a non-operating section of the flow path switching valve of the present invention,
12 is a view showing a configuration of a water treatment apparatus provided with a flow path switching valve of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 through 3, the flow path switching valve 100 of the present invention includes a plurality of inlet ports 112 and 113 connected to different flow paths, and an outlet port 114 through which the fluid introduced through the inlet ports 112 and 113 is discharged And a valve body 110 rotatably installed in the valve body 110 so that any one of the plurality of inlet ports 112 and 113 is selectively connected to the outlet port 114 in accordance with a rotated position, And a valve cover 130 coupled to the valve body 110 to rotatably support the rotator 120. The connection passage includes an outer circumference of the rotator 120, As shown in FIG.

4, the valve body 110 includes a cylindrical body 111 having a front surface opened and a space 111a in which a rotator 120 is received. The valve body 110 includes a first inlet 112, 2 inlet 113 protrudes from the rear surface of the main body 111 and extends in the front and rear direction and the outlet 114 protrudes from the side surface of the main body 111 and is formed to pass therethrough.

The first inlet 112 and the second inlet 113 have the same radius from the center of the main body 111 and are respectively connected to different flow paths. For example, cold water flows into the first inlet 112, And the purified water may be introduced into the second inlet 113. The inlet ports 112 and 113 are composed of a first inlet port 112 and a second inlet port 113, but they may have three or more ports.

A first sealing member seating portion 112a and a second sealing member seating portion 150 are formed around the first inlet 112 and the second inlet 113 so that the first sealing member 140 and the second sealing member 150 can be seated. And a member seating portion 113a are respectively formed.

The outflow port 114 provides a flow path through which the fluid flowing through the first inlet 112 and the fluid flowing through the second inlet 113 selectively flow out.

The front surface of the main body 111 is provided with a guide surface 115 guided by a locking protrusion 125 formed on the rotator 120 when the rotator 120 rotates, A first engaging protrusion 116 and a second engaging protrusion 117 for engaging the engaging protrusion 125 are formed.

A plurality of fastening protrusions 118 are formed on the outer surface of the main body 111 to fasten the valve cover 130 to the fastening ring 134 described later. The fastening protrusions 118 may be formed at three places on the outer surface of the main body 111 at intervals of 120 [deg.].

A fixing portion 119 is formed on an outer surface of the valve body 110 to mount the valve body 110 on a mating member inside the water treatment apparatus.

A first sealing member 140 is provided between the first inlet 112 and the rotator 120 and a second sealing member 150 is provided between the second inlet 113 and the rotator 120, A third sealing member 160 is disposed between the outer circumferential surface of the rotator 120 and the inner circumferential surface of the valve body 110. The first to third sealing members 140, 150, and 160 may be formed of elastic materials such as O-rings.

5 and 6, the rotator 120 includes a rotator body 121 rotatably received in an internal space 111a of the valve body 110, a front central portion 121a of the rotator body 121, And a shaft 122 extending forward from the shaft 122.

The rotator body 121 is formed with a connection passage communicating with the first inlet 112 or the second inlet 113 and the outlet 114 along the outer circumference. The connection channel is formed on the rear surface 121a of the rotator 120 in the forward and backward direction and is connected to the connection hole 123 corresponding to the first inlet 112 or the second inlet 113 according to the rotated position, And a connection groove 124 connecting between the connection hole 123 and the outlet 114.

The radius from the center of the rotator 120 to the connection hole 123 is the same as the radius from the center of the main body 111 to the first inlet 112 and the second inlet 113. Therefore, the connection hole 123 may be positioned to correspond to the first or second inlet 112 or 113 in the forward and backward directions, or may be located at a position corresponding to the first inlet 112 and the second inlet 113, 2 inlet 113 in the first embodiment.

The connection groove 124 communicates with the connection hole 123 and is formed in the circumferential direction around the outer surface of the rotator body 121. The outlet 114 protrudes from the outer surface of the valve body 110 And the inside of the outlet 114 and the connection groove 124 communicate with each other. Therefore, as shown in Fig. 6, the rotation of the rotator 120 When the connection hole 123 is positioned so as to correspond to either the first inlet 112 or the second inlet 113, the fluid that flows into the connection groove 124 through the connection hole 123, Flows to both sides in the circumferential direction on the basis of the position where the discharge port 123 is formed and then discharged through the outlet 114.

The engaging protrusion 125 protrudes radially outward from the front side of the rotator body 121 and extends in the circumferential direction around the outer surface of the rotor body 121 in front of the connection hole 124 And a third sealing member seating groove 126 for engagement of the third sealing member 160 is formed.

The shaft 122 includes a cylindrical portion 122b extending forward from the front center of the rotator body 121 and having a circular cross section corresponding to the shape of the through hole 131a of the valve cover 130, And extends forward at the portion 122b And a shaft end portion 122a protruding forward of the valve cover 130 through a through hole 131a formed at the center of the valve cover 130 to be described later.

The shaft end 122a has a rectangular cross section and is engaged with a grip handle (not shown) for rotating the user. The cylindrical portion 122b is inserted into the through hole 131a, It is possible to rotate smoothly.

7 shows a state in which the valve body 110 and the rotator 120 are coupled to each other. One end of the locking protrusion 125 formed on the rotator 120 is connected to the guide surface 115 formed on the valve body 110 And a first and a second locking protrusions 116 and 117 are formed on both sides of the guide surface 115. The first locking protrusion 116 and the second locking protrusion 117 are engaged with the rotator And serves as a stopper for limiting the bidirectional rotation radius of the motor 120. [

Accordingly, when the rotator 120 is rotated in one direction (counterclockwise) so that the locking protrusions 125 are engaged with the first locking protrusions 116, the connection holes 123 formed in the rotator 120 So that the first inlet 112 and the connection hole 123 communicate with the connection groove 124 and the outlet 114. The first inlet 112 and the first inlet 112 are arranged to correspond to each other. When the rotator 120 is rotated in the opposite direction (clockwise direction) so that the locking protrusion 125 is locked at the second locking protrusion 117, the connection hole 123 formed in the rotator 120 2 inlet 113 so that the second inlet 113 and the connection hole 123 communicate with the connection groove 124 and the outlet 114.

8 and 9, the valve cover 130 includes a cover body 131 for covering a front surface of the valve body 110 to which the rotator 120 is coupled, A second hook portion 133 and a plurality of fastening rings 134. The rotatable member 120 rotatably supports the rotator 120 and prevents axial movement thereof.

The cover body 131 includes a first cover body 131-1 having a through hole 131a through which the shaft 122 of the rotator 120 passes, And the outer side of the main body 111 of the valve body 110 when the valve body 110 and the valve cover 130 are coupled with each other is formed in a concentric structure having a diameter larger than that of the first cover body 131-1 And a second cover body 131-2 having a diameter that surrounds the second cover body 131-2.

The plurality of fastening rings 134 are formed at positions spaced apart from each other in the circumferential direction and are formed in the valve body 110 in a fastening protrusion insertion hole 134a formed by cutting the second cover body 131-2 into a square shape. When the fastening protrusion 118 is inserted, the fastening protrusion 134 is engaged with the fastening protrusion 118, and the second cover body 131-2, which is spaced apart from the fastening protrusion insertion hole 134a in both lateral directions, The cover body 131 is elastically displaced when the fastening protrusion 134 is engaged with the fastening protrusion 118 so that the valve body 131 is inserted into the valve body 131. [ The convenience of the operation is improved.

The first hook portion 132 and the second hook portion 133 are formed at predetermined angular intervals and are cut in a U shape from the first cover body 131-1 to the second cover body 131-2 And the remaining sides 132b and 133b are formed as unfixed fixed ends of the first cover body 131-1 so that when an external force acts in the forward and backward direction, And is resiliently displaced in a direction perpendicular to the rotation direction of the rotator 120, and is restored to its original position when the action of the external force is released.

The first hook portion 132 and the second hook portion 133 are formed between the first and second stopping protrusions 116 and 117 formed on the valve body 110, The first hook portion 132 is formed at a position near the first hooking jaw 116 and the second hook portion 133 is formed at a position near the second hooking jaw 117 . That is, the first hook portion 132 is provided at a position spaced apart from the first hook portion 116 by a distance that the hook protrusion 125 of the rotator 120 can be received, And the second locking protrusion 133 is provided at a position spaced apart from the second locking protrusion 117 by a distance at which the locking protrusion 125 can be received.

The rear end portions of the first hook portion 132 and the second hook portion 133 are further projected rearward than the front end portion of the locking projection 125 when the rotator 120 is coupled to the valve cover 130, The first hook portion 132 and the rear end portion of the second hook portion 133 partially overlap with the front end portion of the engagement protrusion 125 in the forward and backward directions.

9, by the rotation of the rotator 120 at the position shown in (a), the locking projection 125 is engaged with the first hook portion 132 or the second hook portion 133, The first hook portion 132 or the second hook portion 133 is elastically deformed toward the front (upward in the drawing) by the engagement protrusion 125 when the first hook portion 132 or the second hook portion 133 passes the position shown in FIG. And when the rotator 120 further rotates as shown in (c), it is restored to its original position and contacts the guide surface 115 of the valve body 110 to generate a contact sound. Accordingly, the user can easily recognize that the changeover of the flow path is completed by the rotation of the rotator 120 in one direction or the opposite direction. When the second inlet 113 and the outlet 114 are in communication with each other, The passage switching is performed so that the first inlet 112 and the outlet 114 communicate with each other after the locking protrusion 125 passes through the non-operating section as shown in FIG. 9 (a).

At this time, the stopper 125 stops between the first hook portion 132 and the first stopping jaws 116 to restrict the rotation in one direction by the first stopping jaws 116, So that the outlet 114 is communicated.

Conversely, the flow path in which the first inlet 112 and the outlet 114 communicate with each other by the rotation of the rotator 120 in the opposite direction (clockwise) is connected to the second inlet 113 through the outlet 114, The second hook portion 133 is resiliently displaced by rotation of the locking protrusion 125 and is restored to generate a contact sound. At this time, the locking protrusion 125 is restricted in rotation in the opposite direction by the second locking protrusion 117, and stops between the second hook portion 133 and the second locking protrusion 117 so that the second inlet 113 And the outlet 114 are communicated with each other.

10 shows a rotation radius? In which the engagement protrusions 125 of the rotator 120 are rotatable in both directions by the first and second stopping protrusions 116 and 117 formed in the valve body 110 have.

11, the bi-directional rotation radius? Of the rotator 120 is set such that the engaging projection 125 is located between the first hook portion 132 and the first engaging jaw 116, When the first inlet 112 and the second inlet 113 are located between the first inlet 133 and the second inlet 117 and the outlet 114 is in fluid communication with the first inlet 112 and the second inlet 113, And the hook portion 125 is located in a region between the first hook portion 132 and the second hook portion 133. The first and second hooks 112 and 113 and the hooks 133, (? 2) in which the fluid communication between the fluid chamber (114) is interrupted.

Where θ2 is the center when the connection hole 123 is at the closest position not overlapping the first inlet 112 and the center when the connection hole 123 is the closest to the second inlet 113 And B represents a maximum area in which the connection hole 123 can move within the non-operating range? 2.

When the connection hole 123 of the rotator 120 is positioned within the nonoperating interval? 2, the first inlet 112 and the second inlet 113 are spaced apart from each other by the rear surface 121a of the rotator 120, The fluid communication with the clogged connection groove 124 is blocked.

The first inlet 112 and the second inlet 113 are prevented from communicating with each other by providing the nonoperating section? 2 in which the flow of the fluid is blocked within the range of the rotation radius? Of the rotator 120 It is possible to prevent leakage due to the back flow of the fluid.

Hereinafter, the configuration and operation of the water treatment apparatus having the flow path switching valve 100 configured as described above will be described with reference to FIGS. 10 to 12. FIG.

The water treatment apparatus of the present invention includes a first flow path P1 for connecting a cold water discharge pipe 56 to which cold water is supplied and a first water discharge pipe 61, a stationary water discharge pipe 52 to which purified water is supplied, And a second water flow pipe (P2) for connecting the water outlet pipe (61) to the cold water discharge pipe (56) And a first storage tank (20) for storing cold water supplied to the cold export water pipe (56), wherein the flow path switching valve (100) 1) through which the cold water or the purified water is discharged through the first flow path P1 or the second flow path P2 and the cold section through the first flow path P1 and the second flow path P2, And a non-operating interval [theta] 2 in which all the constants are shut off.

The first storage tank 20 is provided with a filter unit 10 for filtering the raw water flowing into the first storage tank 20 and a purified water supply pipe 51 for supplying the purified water passing through the filter unit 10 to the first storage tank 20, Lt; / RTI >

A cooling coil 21 for cooling stored water is provided around the outer surface of the first storage tank 20 and a ball tower 22 for limiting the water level of water flowing into the first storage tank 20 do. The water level of the first storage tank 20 is limited by mechanically shutting off the inflow of water when the water flowing into the first storage tank 20 reaches a certain level by using buoyancy.

The flow path switching valve 100 has a function of switching the flow path so that the cold water of the first storage tank 20 can be discharged or the purified water passing through the filter unit 10 can be directly flown. The flow path switching valve 100 is provided with a cold export water pipe 56 for discharging cold water from the first storage tank 20, a regular export water pipe 52 branched from the purified water supply pipe 51, To the user is connected to the first water supply pipe (61).

The second storage tank 30 is connected to the first storage tank 20 by a first connection pipe 53 so that the water of the first storage tank 20 is supplied to the second storage tank 20 through the first connection pipe 53, And then flows into the storage tank 30.

The first storage tank 20 and the second storage tank 30 are positioned adjacent to each other and the bottoms of the first storage tank 20 and the second storage tank 30 are provided at the same height, The bottom surface of the tank 30 may be provided at a lower position than the bottom surface of the first storage tank 20. [ As a result, the essence of the second storage tank 30 can smoothly flow into the third storage tank 40.

An air vent (not shown) is formed in the upper portion of the first storage tank 20 and the second storage tank 30 to communicate with the atmosphere.

The atmospheric pressure acts on the upper space of the first storage tank 20 and the second storage tank 30 due to the air vent, The purified water in the first storage tank 20 flows into the second storage tank 30 through the first connection pipe 53 so that the water levels of the first storage tank 20 and the second storage tank 30 are kept the same The water level of the second storage tank 30 can be limited by the ball tow 22 provided in the first storage tank 20 so that a separate structure for limiting the water level of the second storage tank 30 is unnecessarily do.

The second storage tank 30 is connected to the third storage tank 40 by the second connection pipe 54 and the purified water of the second storage tank 30 is connected to the third storage tank 40 through the second connection pipe 54. [ And then flows into the storage tank 40.

The third storage tank 40 is disposed at a lower position than the first storage tank 20 and the second storage tank 30 and has a heater 41 for heating purified water stored therein.

The second connection pipe 54 is connected to the lower part of the second storage tank 30 and the second water pipe 62 for connecting hot water is connected to the upper part of the third storage tank 40. Therefore, the purified water in the second storage tank 30 flows through the lower portion of the third storage tank 40, and hot water heated by the heater 41 in the third storage tank 40 flows through the upper portion of the second water- (62).

The outflow through the first water pipe (61) and the second water pipe (62) can be made by mechanical or electromagnetic means. In the case of a mechanical type, purified water, cold water, and hot water flow out without a separate valve operation when a user pushes an outflow coke (not shown) of the first water pipe 61 and the second water pipe 62, The operation signal of the outgoing cock is sensed and the solenoid valve provided on the channel operates to allow the water to flow out.

A drain pipe 57 for draining water from the first storage tank 20, the second storage tank 30 and the third storage tank 40 is connected to the lower portion of the third storage tank 40.

The upper portion of the third storage tank 40 and the upper portion of the second storage tank 30 are connected by an air vent pipe 55 so that the pressure of the third storage tank 40 is supplied through the air vent pipe 55 And then discharged to the second storage tank 30.

The operation of the flow path switching valve 100 in the water treatment apparatus of the present invention constructed as above will be described.

When the connection hole 123 is located in the operation section? 1 in which fluid communication is made between any one of the first inlet 112 and the second inlet 113 and the outlet 114, Cold water or purified water is discharged through the first flow path P1 or the second flow path P2 and fluid communication between the first inlet 112 and the second inlet 113 and the outlet 114 is blocked When the connection hole 123 is positioned in the nonoperating section? 2, both outflow of purified water and cold water through the first flow path P1 and the second flow path P2 are blocked.

If the user does not operate the passage switching valve 100 in the nonoperating period? 2, the user may connect the connecting hole 123 of the rotator 120 to the first inlet 112 and the second inlet The first inlet 112 and the second inlet 113 are communicated with each other so that the first inlet 112 and the second inlet 113 communicate with each other without being positioned to communicate with any one of the first inlet 112 and the second inlet 113. [

When the flow path switching valve that does not include the nonoperating period? 2 is applied to the water treatment apparatus, the purified water filtered by the filter unit 10 flows into the second inlet / And flows back to the first storage tank 20 through the connection hole 113, the connection hole 123, the first inlet 112, and the cold export water pipe 56.

The first storage tank 20 is provided with a ball tower 22 for controlling the water level and the ball tower 22 is connected to the upper portion of the first storage tank 20 when the first storage tank 20 reaches a certain water level The purified water flowing through the purified water supply pipe 51 can be mechanically blocked but the purified water can not be blocked from flowing from the bottom through the cold water discharge pipe 56 of the first storage tank 20, The water in the first storage tank 20 may overflow due to the purified water flowing back to the first storage tank 20.

When the user operates the handle connected to the rotator 120 so that the connection hole 123 is connected to the first inlet 112 in the case where the non-operation interval? 2 is provided in the passage switching valve 100 as in the present invention, The water does not flow back into the first storage tank 20 even if the water is placed in the non-operation section? 2 without being positioned at the position corresponding to the second water inlet 113, Leakage can be prevented.

This action is effective in a mechanical watering type water treatment apparatus. That is, when the solenoid valve for taking out the cold water and the purified water is provided in the cold export water pipe 56 and the constant export water pipe 52 in the water treatment apparatus of the electronic watering system, the handle of the rotator 120 is operated to connect the connection hole 123 Even when the first inlet 112 and the second inlet 113 are communicated with each other, the operation of the cold water side solenoid valve and the purified water side solenoid valve is controlled to prevent the purified water from flowing back to the first storage tank 20 .

As described above, according to the present invention, the flow path switching valve 100 having the nonoperating period? 2 is applied to the water treatment apparatus of the mechanical watering type, so that the configuration of the apparatus for switching the flow path is simplified, And the water overflow phenomenon due to the back flow of water is prevented, so that the water treatment apparatus can be stably operated.

As described above, the present invention is not limited to the above-described embodiments, and various changes and modifications may be made without departing from the scope of the present invention as defined in the appended claims. And such modifications are within the scope of the present invention.

10: filter unit 20: first storage tank
21: cooling coil 22:
30: Second storage tank 40: Third storage tank
41: heater 51: purified water supply pipe
52: Jeollanam-do Export Channel 53: First Connector
54: Second connector 55: Air vent tube
56: Cold export water pipe 57: Water pipe
61: first water outlet pipe 62: second water outlet pipe
100: flow path switching valve 110: valve body
111: main body 112: first inlet
113: second inlet 114: outlet
115: guide surface 116: first stopping jaw
117: second engaging jaw 118: fastening projection
120: rotator 121: rotator body
122: shaft 123: connection hole
124: connection groove 125:
130: valve cover 131: cover body
132: first hook portion 133: second hook portion
134: fastening ring 140: first sealing member
150: second sealing member 160: third sealing member
P1: first flow path P2: second flow path

Claims (15)

A valve body having a plurality of inlet ports connected to different flow paths and an outlet port through which the fluid introduced through the inlet port is discharged;
A rotator rotatably installed in the valve body and forming a connection channel so that any one of the plurality of inlet ports selectively communicates with the outlet port according to a rotated position; And
And a valve cover coupled to the valve body to rotatably support the rotator,
Wherein the connection passage is formed along an outer periphery of the rotator. The method according to claim 1,
Wherein the connection passage includes a connection hole corresponding to the plurality of inlet ports and a connection groove connecting the connection hole and the outlet port. 3. The method of claim 2,
Wherein the plurality of inlet ports are formed on a rear surface of the valve body in a circumferential direction, the outlet port is formed on one side surface of the valve body, the connection hole is formed in a rear surface of the rotator, And the connection groove is formed to communicate with the outer surface of the rotator in the circumferential direction. The method according to claim 1,
A locking projection is formed on one side of the rotator,
Wherein the valve body is formed with a first engaging jaw and a second engaging jaw to engage the engaging protrusion to limit a turning radius of the rotator in both directions. 5. The method of claim 4,
The inlet port located at one side of the plurality of inlet ports communicates with the connection channel and the outlet port when the rotator is rotated in one direction so that the blocking protrusion is caught by the first latching jaw,
Wherein the inlet port located at the other of the plurality of inlet ports communicates with the connection channel and the outlet port when the rotator is rotated in the opposite direction so that the blocking protrusion is caught by the second latching jaw. The method according to claim 1,
A locking projection is formed on one side of the rotator,
The valve cover is provided with a first hook for recognizing completion of the switching of the oil passage by one-way or counter-rotation of the rotator by generating a contact sound while being restrained after being elastically displaced by being hooked on the locking projection by rotation of the rotator, And the first and second hook portions are formed on both sides. The method according to claim 6,
Wherein a guide surface is formed on a front end surface of the valve body to guide the engaging protrusion when the rotator rotates, and the first hook portion and the second hook portion contact the guide surface to generate a contact sound. Switch valve The method according to claim 6,
Wherein the valve body is provided with a first engaging protrusion and a second engaging protrusion for engaging the engaging protrusion to restrict a bi-directional rotation radius of the rotator,
Within the bi-directional rotation radius of the rotator,
A fluid communication is made between any one of the plurality of inlet ports and the outlet port when the engagement protrusion is located between the first hook portion and the first engagement protrusion or between the second hook portion and the second engagement protrusion Section,
And a non-operating section in which fluid communication between the plurality of inlet ports and the outlet port is interrupted when the engaging projection is located in a region between the first hook section and the second hook section. The method according to claim 1,
Wherein a plurality of fastening protrusions are formed on one of the valve body and the valve cover,
Wherein the valve body and the valve cover are formed with a plurality of fastening rings to be engaged with the fastening protrusions. The method according to claim 1,
Wherein a sealing member for watertightness maintenance is provided between the plurality of inlet ports and the rotator, and between the valve body and the rotator. A first flow path connecting the cold water discharge pipe to which cold water is supplied and the first water pipe;
A second flow path connecting the stationary export water pipe to which the purified water is supplied and the first water pipe;
A flow path switching valve provided at an intersection of the cold export water pipe and the regular export water pipe for switching the flow path to supply either the cold water or the purified water to the first water pipe;
And a first storage tank in which cold water supplied to the cold export water pipe is stored,
Wherein the flow path switching valve includes an operating section in which cold water or purified water is discharged through the first flow path or the second flow path and a non-operating section in which both the cold water and the purified water flow out through the first flow path and the second flow path are blocked The water treatment apparatus comprising: 12. The method of claim 11,
Wherein the first storage tank is provided with a ball tower that mechanically blocks the inflow of water when the water level becomes a certain level. 12. The method of claim 11,
The flow path switching valve includes:
A valve body having a first inlet connected to the cold export water pipe, a second inlet connected to the regular export water pipe, and a water outlet connected to the first water pipe;
A rotator rotatably installed in the valve body to form a connection channel so that any one of the first inlet and the second inlet and the outlet may be selectively communicated with each other depending on the rotational position; And
And a valve cover coupled to the valve body and rotatably supporting the rotator. 14. The method of claim 13,
Wherein the connection passage is formed along the outer circumference of the rotator. 14. The method of claim 13,
Characterized in that the rotator is rotated by manual operation of the user

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