RU2484884C1 - Water treatment plant - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to water treatment membrane-type plants with filtration rate of lower than 1 liter per minute. Proposed plant comprises fluid feed means, fluid treatment unit, treated fluid discharge means, free-flow cleaned fluid intake container, treated fluid level control means and treated fluid flow control means. It differs from known plants in peculiar design of treated fluid flow control means, container, treated fluid level control means and their arrangement in the plant. Note here that treated fluid flow control means is arranged at the container body or cover while treated fluid level control means allows retaining the latter in open position and is arranged inside container or fluid treatment unit.

EFFECT: higher reliability and performances, simplified design.

37 cl, 10 dwg

Description

FIELD OF THE INVENTION

The invention relates to installations for purifying a membrane-type liquid, preferably with a filtration rate of less than 1 liter per minute, comprising means for supplying a liquid to be cleaned, a liquid purification unit, a means for removing purified liquid, a portable portable container for receiving purified liquid, means for controlling the filling level of the purified liquid and a device control the flow of purified liquid.

BACKGROUND

According to the application US 20070045159 dated 01.03.2007, B01D 35/14, SHIN-PING LEE, there is a known installation for cleaning liquids, designed to be placed under the sink. The installation includes a reverse osmosis unit (50) and a base (11), designed to accommodate a container (15) for the purified liquid on it (Figure 1). The base (11) has an opening (17) through which the purified liquid enters the container (15) equipped with a one-way valve (18). The container (15) consists of a housing and a cover (19) pivotally mounted on the upper part of the base (11). The container has a handle (151) for transferring without liquid (Figure 4). In the bottom of the container there is a hole located respectively to the hole (17) in the base (11). A means (191) is located in the lid (19) for releasing the overpressure (overpressure occurs when the purified liquid is pumped out of the container (15) for consumption). The installation comprises means (40) for controlling the filling level of the purified liquid having an upper element (41) for controlling the filling level of the purified liquid, a lower element (42) for controlling the filling level of the purified liquid, and an electronic control device (20) (FIG. 2). The upper element (41) for controlling the filling level of the purified liquid is a float valve pivotally mounted on the upper part of the base (11) and extends into the container (15). The lower element (42) for controlling the filling level of the purified liquid is located at the base (11). When opening the tap (70) having an electronic switch (60) connected to the means (40) for controlling the level of filling, the control device (20) sends a signal to the pump (30) to pump the purified liquid from the container (15) to the tap (70) for consumption. When the means (40) for controlling the filling level of the purified liquid determines that the liquid is at the lower level, the control device (20) will signal the activation of the pump (30) for pumping the liquid into the container (15), which will continue until the purified the liquid does not reach the set upper limit level, then the pump (30) will shut off. When the means (40) for monitoring the filling level of the purified liquid determines that there is no liquid in the container (15), the pump (30) will also be turned off. Installation works from a network.

The known installation has several disadvantages. Firstly, to pump purified liquid into a container (15), as well as to drain the purified liquid to a tap (70), use a pump (30) located in the base (11) of the installation. The presence of a pump (30) complicates the design of the installation and reduces the reliability of its operation, because during pumping of the purified liquid by the pump (30) for consumption, if the means (40) determine the absence of liquid in the container (15), the pump (30) may burn out and the installation may break. In addition, the container (15) is pressurized and does not provide the opportunity to transfer purified liquid in it after the end of the filtration process, since there is an opening in the bottom of the container that remains open during transfer, which reduces the operational characteristics of the liquid purification unit.

A known installation for the purification of liquid membrane type, manufactured by Weil Industrieanlagen GmbH, Germany (http://www.rowa-wasser.de/trink_produkt.htm?ID=240&gruppe=48&bereich=2, Fig.1, 2). The installation includes a reverse osmosis unit and a portable non-pressure jug located on a specially designed stand. A supply line of purified liquid is connected to the stand. The support is equipped with a means for determining the weight and an arc-shaped pipeline having a funnel in the upper central part with an outlet through which the purified liquid enters the jug. The installation is connected to cold water supply, the reverse osmosis unit is located under the sink, and the stand for the jug and the arc-shaped pipe are respectively located above the sink. The reverse osmosis unit is connected to the stand via a purified fluid line. Thus, the liquid purification unit does not require a storage tank, instead it filters water directly into a 1.5-liter jug made of durable glass. Depending on the installation model and the liquid pressure in the water supply line, the filling of the jug takes place from 5 to 15 minutes, after which the filling process stops automatically. The control of the filling level is carried out by the microcontroller after installing the jug on the stand according to its weight using the means for determining the weight located in the stand.

A disadvantage of the known installation is the complex design of the means for controlling the filling level of the purified liquid, which provides water to the jug and includes scales. The water supply depends on the filling level of the jug, which is measured by an indirect method - by weight. The balance reacts to the mass of the "jug + water" system. If the user instead of the prescribed jug accidentally tries to use a different container, for example a smaller jug, the volume of liquid required by weight to stop filling in the prescribed jug may not fit in another smaller jug and the liquid will go over the edge - this reduces the reliability of the installation for cleaning fluid. In addition, the presence of a stationary stand for the jug, located above the sink, occupies most of the space of the working kitchen area, which is usually the most loaded, which also reduces the operational characteristics of the known installation.

According to the application US 2009/0288999 dated November 26, 2009, B01D 61/12, SHIN-PING LEE there is a known installation for cleaning liquids with reverse osmosis, operating from the network, i.e. has a power cord for connecting the unit to a power outlet (Figure 1). The installation contains a block (11) reverse osmosis (Fig.3, 5). The reverse osmosis unit is enclosed in a housing (1) equipped with an installation platform (12) in which there is an opening (13) for the outlet of the purified liquid. On the installation platform (12) there is a removable non-pressure container (2) consisting of a housing (not shown in the drawings), a cover (25), a holder (26), a spout (27) and an opening (21) for receiving the purified liquid located in the bottom of the container (2), respectively, the outlet (13) of the mounting platform (12).

The unit is equipped with means (3) for controlling the filling level of the purified liquid. The means (3) for controlling the filling level of the purified liquid consists of a housing (311) with a movable magnetic float (312) installed inside the container (2) in its upper part, and two magnetic switches (32, 33), sequentially mounted one after the other on the inner side of the housing (1) of the reverse osmosis unit (11). The switches (32, 33) are installed in such a way that the magnetic float (312) located inside the container (2), moving along its body (311), interacts with them (elements of the means for controlling the filling level of the purified liquid are located in different parts of the installation, and namely, one inside the container (2), and the other inside the case (1) of the reverse osmosis unit (11)). The means (3) for controlling the filling level of the purified liquid is equipped with a microcontroller (34). As the container (2) is filled, the level of the purified liquid will be raised by the float (312), the float (312) contacts the switch (33) and a corresponding signal is generated on the microcontroller (34), or when the consumer removes the container (2) from the platform (12) earlier than the end time of filtering, on the contrary, the contact of the float (312) opens with the switch (32) with the formation of the corresponding signal.

The installation is equipped with a device for controlling the flow of purified liquid, made with the possibility of transition to the open position with the beginning of the filtration process and the flow of liquid into the container (2) and transition to the closed position with the end of the filtration process and the flow of liquid into the container. The purified liquid flow control device consists of a flow valve (23) located in the opening (21) of the bottom of the container (2) and an electromagnetic valve (15) located in the mounting platform (12) of the housing (1) of the reverse osmosis unit (11). When the container (2) is mounted on the platform (12), the stem (231) of the flow valve (23) abuts against the protrusion (131) located on the platform (12), and the flow valve (23) opens, the magnetic float (312) comes into contact with a switch (32), applying a signal to the solenoid valve (15) through the microcontroller (34) to start the filtering process (the solenoid valve (15) goes into the open position). The flow of purified liquid into the container (2) begins and its filling. As the container (2) is filled, the magnetic float (312) comes into contact with another switch (33), giving a signal to the electromagnetic valve (15) to stop the filtering process (the electromagnetic valve (15) switches to the closed position). The flow of purified liquid into the container (2) is stopped. The user removes the container (2) from the platform (12), the stem (231) of the flow valve (23) in the bottom of the container (2) is locked, preventing the cleaned liquid from flowing out of the hole (21) in the bottom. Similarly, the filtering process can be stopped when the container (2) is not completely filled. The user removes the container (2) from the platform (12), the magnetic float (312) opens with the corresponding switch (32), and a signal is sent to the electromagnetic valve (15) to complete the filtration process (prototype).

One of the disadvantages of the known installation is that it has a complex mechanism for the interaction of the purified liquid flow control device with means (3) for controlling the filling level of the purified liquid, requiring two valves (23, 15) and a magnetic float (312) with two magnetic switches ( 32, 33), which complicates the design of the installation for cleaning liquid. Another disadvantage is that the magnetic elements of the means for monitoring the filling level of the purified liquid, which are functionally interconnected, are located in different parts of the installation (the magnetic float (312) is located in the container (2), and the switches (32, 33) inside the case (1) of the unit ( 11) reverse osmosis, respectively). In different parts of the installation are also located functionally interconnected valves of the purified liquid flow control device (the flow valve (23) is located in the bottom of the container (2), and the electromagnetic valve (15) inside the installation platform (12) of the housing (1) of the block (11) ) reverse osmosis), which together reduces the reliability of the installation during its operation. Another disadvantage of the known installation is that, for example, some particle, for example, a grain of sand, which during filtration can clog into the flow valve (23) located in the bottom of the container (2), can accidentally get into the container (2), and when removing the container (2) from the platform (12), the flow valve (23) may not completely lock up and the purified liquid will seep through the bottom. It also reduces the reliability of the liquid purification plant. In addition, the installation is designed to be placed above the sink, for example, on the surface of the working kitchen area, which, as a rule, is the most loaded. Moreover, the presence of a platform for installing the container significantly increases the dimensions of the installation and does not allow the main cleaning unit (11) to be placed under the sink, which reduces the operational characteristics of the installation for cleaning liquids.

SUMMARY OF THE INVENTION

The general objective of the invention and the required technical result achieved by using the invention is the development of a new installation for the purification of liquid membrane type, preferably with a filtration rate of less than 1 liter per minute, increasing reliability and improving the operational characteristics of the installation while simplifying its design.

The task and the required technical result when using the invention is achieved by the fact that the installation for the purification of liquid membrane type, preferably with a filtration rate of less than 1 liter per minute, consisting of means for supplying the liquid to be cleaned, liquid purification unit, means for removing the purified liquid, pressure-free portable container for purified liquid, comprising a housing and a cover, means for controlling the filling level of the purified liquid, a device for controlling the flow of purified liquid, made with the possibility of moving to the open position with the beginning of the filtration process and the liquid entering the container and moving to the closed position with the end of the filtration process and the liquid entering the container by interacting with the means for controlling the filling level of the purified liquid, according to the invention, the liquid purification unit comprises a device for controlling the flow of purified liquid , which is an integral part of it, where the device for controlling the flow of purified liquid is configured to open position and connections with the container, as well as with the possibility of moving to the closed position and disconnecting from the container by interacting with a means for controlling the filling level of the purified liquid and with an additional element for its installation, while the element for installing the purified liquid flow control device is located in the case or lid container, and means for controlling the level of filling of the purified liquid, configured to hold the device for controlling the flow of purified liquid in the open floor location, located in the container or in the liquid purification unit, and the fact that the device for controlling the flow of purified liquid includes a control valve and connecting means, and the fact that the device for controlling the flow of purified liquid is made with the possibility of transition to the open position under the action of physical force produced by the user , and the fact that the connecting means consists of an adapter having a housing and a fastening element, while the adapter is located at the outlet of the means for removing the purified liquid, the input of the cat it is connected to the outlet of the liquid purification unit, and the control valve is located inside the adapter housing of the connecting means or on the means for removing the purified liquid, and the element for installing the purified liquid flow control device consists of a body having an installation cavity in communication with the container and a zone an emphasis made in the form of a protrusion or plate on the inner side of the housing, and the fact that the means for monitoring the filling level of the purified liquid containing the liquid level sensor is located in pus of the container or in the lid of the container and has an actuator connected to the level sensor of the purified liquid, and the fact that the means for monitoring the level of filling of the purified liquid containing the liquid level sensor is located in the device for controlling the flow of the purified liquid and has an actuator connected to the level sensor purified liquid, and the fact that the actuating element is in the form of a lever mechanism or in the form of a control unit, and the fact that the lever mechanism includes a lever, one end of which it is one with a liquid level sensor, and the other is equipped with a fastener; the lever is fixed in the housing or the lid of the container with the possibility of rotation around its axis, and the fastening elements are made in the form of a locking cavity on the outside of the adapter housing and capable of interacting with it the locking protrusion at one of the ends of the lever, respectively, and the fact that the fastening elements are made in the form of a locking protrusion on the outer side of the adapter housing and capable of interacting with the locking cavity on one from the ends of the lever, respectively, and the fact that part of the lever mechanism, preferably part of the lever, protrudes from the container, and the lever mechanism is configured to interrupt the filtering process at any time under the action of physical force exerted by the user on its protruding part, and the fact that the purified liquid level sensor is a float type sensor or a dynamometric type sensor, and the fact that the control unit is located in the housing of the element for installing the flow control device th fluid and is provided with a fastening element, the input of which is connected to the output of the control unit, and the fact that the control unit is located in the adapter housing of the connecting means of the purified liquid flow control device and is equipped with a fastening element, the input of which is connected to the output of the control unit, and that the elements the fastenings are made in the form of a locking protrusion on the outer side of the adapter housing and an electrically controlled locking cavity capable of interacting with it on the inner side of the element housing for installation and devices for controlling the flow of purified liquid, respectively, and the fact that the fastening elements are made in the form of a locking cavity on the outer side of the adapter body and capable of interacting with it an electrically controlled locking protrusion on the inner side of the body of the element for installing the device for controlling the flow of purified liquid, respectively, and that the fastening element is made in the form of an electrically controlled protrusion on the outside of the adapter body capable of fixing the flow control device liquid in the container due to the frictional force arising from the contact of the protrusion with the inner side of the element body for installing the purified liquid flow control device, and the fact that the control unit is equipped with a position sensor, the position sensor and the control unit being interconnected, and the output of the control unit being connected with the input of the control valve of the purified liquid flow control device, and the fact that the liquid level sensor is a conductivity sensor or a non-contact sensor, and that Your control of the flow of purified liquid additionally contains a safety valve located inside the adapter housing of the connecting means, and the fact that the membrane-type liquid purification installation contains mineralization means and an indication of at least one filter element of the liquid purification unit located in the body or cover container, and the fact that the device controls the flow of purified liquid made with the possibility of transition to the open position while simultaneously connecting to the container, as well as with the possibility of moving to the closed position while simultaneously disconnecting from the container by synchronizing in time with the means for controlling the level of filling of the purified liquid and with an additional element for its installation, and the fact that the device for controlling the flow of purified liquid is made with the possibility of moving into the open position after connection with the container, as well as with the possibility of moving to the closed position before disconnecting from the container by means of a sequential during no interaction with the means for controlling the filling level of the purified liquid and with an additional element for its installation, and the fact that the means for removing the purified liquid is, for example, in the form of a flexible hose, tube, flexible double hose or double tube, and the fact that the means for removing the purified the liquid additionally contains a length lock, and the fact that the fastening elements are configured to fix and hold the device for controlling the flow of purified liquid in the open position by friction or geometrically on the circuit.

A distinctive feature of the invention is the design of the device for controlling the flow of purified liquid, a container and means for controlling the level of filling of the purified liquid, and their relative position in the installation. Unlike the closest analogue, due to the essential features of the claimed invention, a simplification of the design of the liquid purification installation is achieved, in which the liquid purification unit comprises a purified liquid flow control device and a purified liquid removal means as integral parts thereof, and a means for controlling the filling level of the purified liquid, configured to hold the purified liquid flow control device in an open position, located in a container or in a liquid purification unit , due to which, at the same time, an increase in the reliability of the installation during its operation is achieved. The design solution provides the convenience and ease of installation and disconnection of the purified liquid flow control device from the container, which does not require a special installation platform or stand for filling, and when transferring a filled container, unlike the closest analogue, the possibility of filtered liquid leakage through the bottom of the container is excluded, whereby an improvement in the operational characteristics of the liquid purification plant is achieved.

LIST OF GRAPHIC MATERIALS

The invention will be more clear from the description, which is not restrictive and given with reference to the accompanying drawings, in which:

Figure 1 - shows a copy of the first part of the advertising booklet of 2011 by Weil Industrieanlagen GmbH (prior art);

Figure 2 - shows a copy of the second part of the advertising booklet of 2011 by Weil Industrieanlagen GmbH (prior art);

Figure 3 - shows a General diagram of an installation for purifying a membrane-type liquid (the container is disconnected from the liquid purification unit);

Figure 4 - shows a General diagram of an installation for purifying a membrane-type liquid (the container is connected to a liquid purification unit);

Figure 5 - shows a General view of the surface of the sink, means for draining the purified liquid, the device for controlling the flow of purified liquid and the container (the device for controlling the flow of purified liquid is disconnected from the container);

6 - shows a General view of the surface of the sink, means for draining the purified liquid, the device for controlling the flow of purified liquid and the container (the device for controlling the purified liquid is connected to the container);

7 - shows a container with a liquid level at the time of the filtering process;

Fig. 8 shows a container with a liquid level at the moment immediately after the end of the filtration process;

Fig.9 - shows the upper part of the container at the time of the filtering process;

Figure 10 - shows the upper part of the container at the time immediately after the end of the filtering process;

SUMMARY OF THE INVENTION

The membrane-type liquid purification installation consists of means 1 for supplying the liquid to be cleaned, liquid purification unit 2, means 3 for discharging the purified liquid, device 4 for controlling the flow of purified liquid and a pressureless portable container 5 for purified liquid (Figs. 3, 4).

Since the liquid purification device is designed to draw liquid from highways under pressure, for example, from drinking water supply systems, the means 1 for supplying the liquid to be cleaned can be made in the form of a fitting (not shown in the drawings) with a hydraulic shut-off valve 6 (FIG. 3, 4). The output of the means for supplying the cleaned liquid 1 is connected to the input of the liquid purification unit 2.

The membrane-type liquid purification unit 2, preferably with a filtration rate of less than 1 l / min, consists of at least one sorption purification module 7 and at least one module 8 with a membrane, a purified liquid flow control device 4 and a purified liquid removal means 3, the means 3 of the outlet of the purified liquid and the device 4 for controlling the flow of purified liquid are integral and do not disconnect during operation of the installation, i.e. are integral parts of the liquid purification unit 2 (FIG. 3). As the membrane, for example, a reverse osmosis membrane or a nanofiltration membrane is used. Drainage is carried out along the line 9, which is equipped with a restrictor (not shown in the drawings) in order to create the pressure necessary for the liquid filtration process inside the membrane module 8. The line 10 connects the hydraulic shut-off valve 6 and the means 3 for removing the purified liquid and is intended for feedback on the pressure (liquid) between the device 4 for controlling the flow of purified liquid and a shutoff hydraulically controlled valve 6. Block 2 of the liquid purification is designed to filter the liquid and install pouring in under the sink.

The means 3 for removing the purified liquid connected to the output of the liquid cleaning unit 2 is, for example, in the form of a flexible hose or tube having sufficient rigidity. The length of the hose or tube is at least 25 cm. The means 3 for discharging the cleaned liquid can be made in the form of a double hose or a double tube - internal (main), for supplying the cleaned liquid, and external (protective), to protect the inner tube from damage in case of possible inaccurate use by the user of the tool 3.

The purified liquid flow control device 4 includes a control valve and connecting means 11 (Fig. 7). The control valve is made, for example, in the form of a mechanical valve 12 (Fig. 9), a mechanical valve with a damper (not shown in the drawings) or an electromagnetic valve (not shown in the drawings). The valve 12 has a seat 13 and a spring-loaded movable rod 14, the spring 15 provides a force for a quick transition of the purified liquid flow control device 4 to the open or closed position. The connecting means 11 is designed to connect the device 4 for controlling the flow of purified liquid with the container 5 and consists of an adapter 16 having a housing 17 and a fastening element made, for example, in the form of a locking cavity 18 or a locking protrusion (not shown in the drawings) on the outside the housing 17 of the adapter 16 (Fig.9).

The connecting means 11, in particular the adapter 16, is located at the outlet of the means 3 for removing the purified liquid. The outlet of the purified liquid removal means 3 is mounted above the sink (FIG. 5) so that the purified liquid removal means 3 can be adjusted in length, which increases the usability of the membrane type liquid cleaning unit, i.e. the user, grabbing the connecting means 11 with his hand and pulling it, can pull the purified liquid discharge means 3 to the required length (the purified liquid flow control device 4 moves together with the purified liquid discharge means 3) and connect the purified liquid flow control device 4 to the container 5 ( 6) for filling the container with purified liquid in any place of his choice, for example, a kitchen area. After disconnecting the purified liquid flow control device 4 from the container 5, the user removes that part of the purified liquid removal means 3 that he pulled out back under the sink and installs the connecting means 11 in its original place above the sink. Also, for ease of operation of the installation, a length lock can be provided in it for means 3 for draining the purified liquid to draw it under the sink, made in the form of a weighting agent 19 (Figs. 5, 6) or an automatic retraction device (not shown in the drawings), which will also located under the sink. The length lock can additionally be used as a limiter for pulling the purified liquid removal means 3, which is clearly seen in Figures 5, 6 with the weighting agent 19 as an example. To further improve the operational characteristics of the installation for the purified liquid removal means 3, an additional decorative basing and guiding means can be additionally provided 20 located above the sink (Figs. 5, 6).

The container 5 includes a housing 21, a lid 22 and an additional element 23 for installing the device 4 for controlling the flow of purified liquid (Fig.7). The container 5 may be made in the form of a tank, bottle, vessel or container of any shape, in particular a jug type container. The element 23 for installing the device 4 for controlling the flow of purified liquid consists of a housing 24 (Fig. 9) with an installation cavity 25 communicating with the container 5 through the hole 26, and a stop zone made in the form of a protrusion 27 or plate (not shown in the drawings), limiting the installation depth of the device 4 for controlling the flow of purified liquid in the container 5. The element 23 for installing the device 4 for controlling the flow of purified liquid can be made as a separate part (not shown in the drawings) or integrally with the container 5 (Figs. 7-10) . The element 23 for installing the purified liquid flow control device 4 may be provided with a fastening element (not shown in the drawings) for additional fixing of the device 4 in the housing 24. The fastening element may be made in the form of a protrusion on the inner side of the housing 24 of the installation cavity 25 holding the device 4 by means of friction against the housing 17 of the adapter 16, or in the form of a slot on the housing 24 of the installation cavity 25, capable of interacting with a protrusion on the housing 17 of the adapter 16 (bayonet).

The means 28 for controlling the filling level of the purified liquid is located in the cleaning unit (not shown in the drawings) or in the container 5 (Fig. 7) and consists of a level sensor of the purified liquid and an actuating element connected to it. The actuating element is made in the form of a lever mechanism 29 (Fig.7) or a control unit (not shown in the drawings). The lever mechanism 29 is a lever 30, mounted in the housing 21 (not shown) or in the lid 22 of the container 5, in particular, in the housing 24 of the element 23, made in one piece with the container 5 (Fig.9), with the possibility rotation around the axis 31 (Fig.9). One of the ends of the lever 30 is provided with a fastening element, made, for example, in the form of a locking protrusion 32 (Fig.9), capable of interacting by means of a geometric closure with the locking cavity 18 of the connecting means 11, or, accordingly, vice versa in the form of a locking cavity (not shown in the drawings ), capable of interacting by means of a geometric closure with the locking protrusion of the connecting means 11 (not shown in the drawings). The locking protrusion 32 ensures the fixation of the adapter 16 in the housing 24 of the element 23, holding the valve stem 14 of the valve 12 open (Fig. 9), and releasing the adapter 16 from fixing at the end of the filtration process (Fig. 10).

If the control valve is made in the form of a mechanical valve with a shutter pivotally mounted in the housing 17 of the adapter 16 (not shown in the drawings), then the locking protrusion 32 will also fix and keep the valve shutter open throughout the entire filtering process, while fixing the adapter 16 in the container 5 can be carried out before the shutter moves to the open position, for example, by bayonet connection of the housing 17 of the adapter 16 with the element 23 of the container 5 under the influence of physical effort of the user. Accordingly, bayonet separation of the adapter 16 from the element 23 of the container 5 (not shown in the drawings) can also be carried out under the influence of the physical effort of the user after the shutter moves to the closed position (not shown in the drawings).

The other end of the lever 30 is connected to a purified liquid level sensor, which is a float type sensor made in the form of an open float 33 (Figs. 7, 8) or a closed float (not shown in the drawings), or a dynamometric type sensor (not shown in the drawings) . The dynamometer type sensor (not shown in the drawings) may include a spring located on the outer side of the bottom of the container 5, while one of the ends of the lever 30 will extend beyond the housing 21 of the container 5 and abut against a flat surface on which the container 5 is mounted. As it fills of the container 5 with liquid, the spring will be compressed, and the end of the lever 30 abutting against a flat surface will actuate the lever mechanism 29.

The lid 22 of the container 5 must be additionally engaged with the housing 21 (not shown in the drawings) or have a certain mass, which would not allow the lever 30 to push out or displace the lid 22 from the container 5 during its operation. Additional engagement of the cover 22 with the housing 21 can be carried out, for example, by means of fixing made in the form of a special protrusion on the cover 22 and the corresponding special cavity on the housing 21 or, accordingly, vice versa (not shown in the drawings).

Part of the lever mechanism 29 may protrude beyond the cover 22. The protruding part may be made in the form of a separate part, for example in the form of a button (not shown) capable of interacting with one of the ends of the lever, or in the form of a protruding part 34 (Fig.7- 10) of the lever 30 in such a way that the user, by pressing on the protruding part 34 of the lever mechanism 29, can release the adapter 16 from fixing, regardless of the position of the level of the purified liquid in the container 5, i.e. stop the filtering process at any time.

The actuating element can be made in the form of a control unit equipped with a power source, the output of which is connected to the input of the control unit (not shown in the drawings). The control unit and the purified liquid level sensor are interconnected. The purified liquid level sensor is a conductivity sensor or a proximity sensor (not shown in the drawings). The control unit is located in the container 5 (not shown in the drawings), or in the purified liquid flow control device 4 (not shown in the drawings) and is equipped with a fastening element, the input of which is connected to the output of the control unit.

If the control unit is located in the container 5, for example, in the housing 24 of the element 23 (not shown in the drawings), then the fastening element can be made in the form of an electrically controlled locking protrusion or an electrically controlled locking cavity (not shown in the drawings) capable of interacting by geometrical closure with a locking cavity 18 or a locking protrusion (not shown in the drawings), respectively, on the outer side of the housing 17 of the adapter 16. Similarly to the locking protrusion 32 (Fig.9, 10) electrically controlled locking protrusion provides fixation of the adapter 16 in the container 5, keeping the stem 14 of the valve 12 open, and release the adapter 16 from fixing at the end of the filtration process (not shown in the drawings). Or if the control valve is made in the form of a mechanical valve with a flap pivotally mounted in the housing 17 of the adapter 16 (not shown in the drawings), then the electrically controlled locking protrusion, similar to the locking protrusion 32, will keep the valve flap open during filtration, while fixing the adapter 16 in the container 5 can be carried out before the shutter moves to the open position, for example, by bayonet connection of the housing 17 of the adapter 16 with the element 23 of the container 5 under the action of physical force of Tell. Accordingly, the bayonet separation of the adapter 16 from the element 23 of the container 5 can also be carried out under the influence of the physical effort of the user after the shutter moves to the closed position (not shown in the drawings).

If the control unit is located in the device 4 for controlling the flow of purified liquid, for example, in the case 17 of the adapter 16 (not shown in the drawings), the fastening element of the control unit can be made in the form of an electrically controlled locking protrusion also located on the outside of the case 17 of the adapter 16 to keep the device 4 controlling the flow of purified liquid in the container 5 in the open position due to the friction force arising from the contact of the protrusion with the inner side of the housing 24 of the element 23 (in the drawings shown).

If the control valve is designed as an electromagnetic valve, its input will be connected to the output of the control unit. The electromagnetic valve may be located in the housing 17 of the adapter 16 and connected to the control unit by means of contacts (not shown in the drawings) or on the means 3 for discharging purified liquid and connected to the control unit by means of contacts or via a radio channel (not shown in the drawings). If the electromagnetic valve is located on the means 3 for removal of the purified liquid, the installation for cleaning the liquid can be additionally equipped with a safety valve located inside the housing 17 of the adapter 16 of the connecting means 11 (not shown in the drawings).

The control unit is equipped with a position sensor that sends a signal to the control unit about the connection of the purified liquid flow control device 4 to the container 5 and, accordingly, its disconnection. The position sensor and the control unit are interconnected by contacts or via a radio channel. The position sensor may be an optical sensor or a micro switch (button). If the position sensor is made in the form of a microswitch (button) located on the outside of the housing 17 of the adapter 16, it can additionally hold the purified liquid flow control device 4 in the open position due to the friction force that occurs when the button surface contacts the inner side of the element body 24 23 (not shown in the drawings).

The control unit can be additionally equipped with a button (not shown in the drawings) for supplying a signal to the control unit to release the adapter 16 of the purified liquid flow control device 4 from fixation. The button may be located, for example, on the housing 21 or the lid 22 of the container 5, while the output of the button will be connected to the input of the control unit. The user by pressing the button can release the adapter 16 from fixing, regardless of the position of the level of the purified liquid in the container 5, i.e. stop the filtering process at any time.

Thus, the means 28 for controlling the filling level of the purified liquid is located in the liquid purification unit 2 (not shown in the drawings) or in the container 5 (Figs. 7, 8).

The membrane-type liquid purification installation may contain a mineralization agent (not shown in the drawings) for mineral enrichment of the liquid that has been purified in the liquid purification unit 2. The mineralization tool is made, for example, in the form of individual granules of a mineralizer, a perforated container filled with a mineralizing composition, or a bag with a mineralizing composition, and also in the form of a device for dispensing a mineral concentrate. Depending on the modification of the installation, the mineralization agent can be located in any part of it, for example, in a liquid purification unit 2 or in a container 5.

Installation for cleaning liquid may include an indication device for determining the status of the resource of at least one filter element of the liquid cleaning unit 2 (not shown in the drawings). The indicating device is preferably located in the upper part of the housing or the lid of the container 5.

The liquid purification installation can be made of various modifications, including the inclusion of additional blocks both before and after the liquid purification unit 2, for example, such as sorption, ion-exchange, as well as modules and cartridges filled with special resins (for example, antibacterial), ultraviolet sources.

Installation for cleaning liquid membrane type works as follows.

Initially, the device 4 for controlling the flow of purified liquid is in the closed position without communication with the container 5 (Figure 5). To obtain the purified liquid for consumption, the user draws out the means 3 for supplying the purified liquid, the outlet of which with the device for controlling the flow of purified liquid 4 located on it, is installed above the sink, to the required length (Figs. 5, 6). To start the filtration process and the flow of liquid into the container 5, the purified liquid flow control device 4 must be moved to the open position, for this the user must insert (put) the adapter 16 of the purified liquid flow control device 4 into the housing 24 of the element 23 of the cover 22 of the container 5 .

If the actuating element is made in the form of a lever mechanism 29, then when the user inserts the adapter 16 into the body 24 of the element 23, the lever 30 is tilted, passing the adapter 16 into the cavity 25, the rod 14 of the valve 12 abuts against the protrusion 27, and the spring 15 ensures that the rod is lifted due to its compression 14 simultaneously with the transition of the purified liquid flow control device 4 to the open position, at this moment the locking protrusion 32 of the lever 30 enters the locking cavity 18, fixing the adapter 16 from longitudinal movement and holding the device of 4 control flow of purified fluid during filtration in an open position the mass of the float 33. Thus, the flow control unit 4 the purified liquid in the open position in a spring-loaded condition. If the control valve of the purified liquid flow control device 4 is made in the form of a mechanical valve with a damper, then when the user inserts the adapter 16 into the housing 24 of the element 23, the user simultaneously makes a bayonet connection of the housing 17 of the adapter 16 with the housing 24 of the element 23, the lever 30 then tilts, skipping adapter 16 inside the cavity 25.

When the lever 30 returns to its original position, its locking protrusion 32 comes into contact with the damper and opens it, keeping the mass of the float 33 in the open position during filtration.

If the actuating element is made in the form of a control unit, then when the user inserts the adapter 16 into the housing 24 in the case of a mechanical valve 12, its rod 14 also abuts against the protrusion 27, the spring 15 due to its compression ensures the rod 14 is lifted simultaneously with the passage of the cleaned flow control device 4 liquid in the open position, at the time of compression of the spring 15, the control unit sends a signal to the electrically controlled locking protrusion about the entrance to the locking trough 18. The electrically controlled locking the protrusion protrudes into the locking cavity 18, fixing the adapter 16 from longitudinal movement and keeping the flow control device 4 cleaned during filtration in the open position. Thus, the device 4 for controlling the flow of purified liquid in the open position is in a spring-loaded state. In the case of a mechanical valve with a flap, when the user inserts the adapter 16 into the body 24 of the element 23, the user simultaneously makes a bayonet connection of the body 17 of the adapter 16 with the body 24 of the element 23. Then, the electrically controlled locking protrusion comes into contact with the flap by the signal from the control unit, opening it and holding the float mass 33 in the open position during filtration. If the control valve is made in the form of an electromagnetic valve, then when the user inserts the adapter 16 into the installation point On the signal 25 from the position sensor, the control unit sends a signal to the solenoid valve about its transition to the open position and at the same time to the electrically controlled protrusion about fixing the adapter 16 from longitudinal movement in the installation cavity 25 of the container 5. In this case, the signal is sent to the electromagnetic valve to open the position can be made even after fixing the adapter 16. If the control unit is located in the housing 17 of the adapter 16 (or in the liquid cleaning unit 2), then the adapter 16 can be fixed due to the frictional force arising from the contact of the electrically controlled locking protrusion (located on the outer side of the housing 17 of the adapter 16) with the inner side of the housing 24 of the installation cavity 25. If the purified fluid flow control device 4 is configured to be connected to the container 5 by a bayonet fitting, then fixation the adapter 16 can be carried out under the influence of the physical effort of the user (manually).

After opening the control valve, the liquid under pressure from the drinking water supply passes through the means 1 for supplying the liquid to be cleaned, opens the hydraulic shut-off valve 6 and enters the inlet of the liquid purification unit 2. In block 2, the liquid enters, for example, into sorption purification module 7, where active chlorine, heavy metal ions and organic substances are removed, and then to module 8 with a membrane, where harmful impurities, bacteria, viruses, most of the dissolved salts are removed and organic matter.

As a result of the passage of fluid through module 8, a purified liquid and concentrate are formed with the membrane. Concentrate on line 9 enters the drainage. The purified liquid through the purified liquid removal means 3 and the purified liquid flow control device 4 enters the container 5.

As the container 5 is filled, the level of the purified liquid 35 (Fig. 8) rises and reaches its predetermined maximum value. The level sensor of the purified liquid provides a signal to the actuator on the transition of the device for controlling the flow of purified liquid to the closed position.

If the actuating element is made in the form of a lever mechanism 29, the level of the purified liquid raises the float 33, thereby turning the lever 30 and releasing the adapter 16 from fixing (Figure 10). Under the action of the spring 15, the adapter 16 snaps off, disconnecting the purified liquid flow control device 4 from the container 5 simultaneously with closing the valve 12. If the control valve is made in the form of a mechanical valve with a shutter, and the adapter 16 is connected to the container 5 by a bayonet connection, the level of the purified liquid raises the float 33, thereby turning the lever 30. The locking protrusion 32 ceases to press on the shutter and it closes. Moreover, the release of the adapter 16 from the fixation can be done manually at the request of the user at any time.

If the actuating element is made in the form of a control unit, then in the case of a mechanical valve 12, the purified liquid level sensor registers a predetermined maximum level of purified liquid and sends a signal to the control unit to release the adapter 16 from fixing. An electrically controlled locking protrusion emerges from the locking cavity 18 and, under the action of the spring 15, the adapter 16 is snapped off, disconnecting the purified liquid flow control device 4 from the container 5 simultaneously with closing of the valve 12. If the control valve is made in the form of a mechanical valve with a shutter, and the adapter 16 is connected to the container 5 with a bayonet connection, the level sensor of the purified liquid registers the set maximum level of the purified liquid and sends a signal to the control unit to terminate the contact of electro directs the locking protrusion with a flap. The protrusion ceases to press on the shutter and it closes. Moreover, the release of the adapter 16 from the fixation can be done manually at the request of the user at any time. If the control valve is made in the form of an electromagnetic valve, the level sensor of the purified liquid registers the set maximum level of the purified liquid and sends a signal to the control unit to close the electromagnetic valve and at the same time to release the adapter 16 from fixing. In this case, the signal on the release of the adapter 16 from fixing can be applied after the electromagnetic valve is closed. In this case, the release from fixation can occur under the influence of the physical effort of the user, if the device 4 for controlling the flow of purified liquid is connected to the housing of the installation cavity by a bayonet connection.

After closing the control valve, the flow of purified liquid into the container stops and the filtration process stops, the pressure increases in the means 3 for removing the purified liquid, under the action of which the hydraulic shut-off valve 6 closes (pressure feedback between the valves is carried out along line 10). The user returns the device 4 for controlling the flow of purified liquid to its original place above the sink (Figure 5) and carries away the container 5 for consumption of the purified liquid. The liquid purifier goes into standby mode. In standby mode, only the outlet of the purified liquid means 3 with the purified liquid flow control device 4 located on it remains on the sink, which even if there is an additional decorative base and guide means 20 (Figure 5) take up so little space that the surface above the sink remains free . In this case, only the liquid purification unit 2 remains under the sink, having small dimensions and not taking up much space, unlike the closest analogue. As necessary, in the purified liquid, the user takes the container 5 and installs the purified liquid control device 4 therein (FIG. 6). The cycle repeats.

Unlike the closest analogue, in which the valves of the purified liquid flow control device, as well as the magnetic elements of the purified liquid filling level control device, are located in different parts of the installation, respectively, in the claimed invention, the purified liquid flow control device 4 is an integral part of the liquid cleaning unit, and means 28 for controlling the filling level of the purified liquid is located in the container 5 or in the liquid cleaning unit 2, due to which a simplification of the design is achieved SETTING while improving the reliability of the installation during its operation. The design solution provides the convenience and ease of installation and disconnection of the device 4 for controlling the flow of purified liquid from the container 5, for filling which, unlike the closest analogue, a special installation platform or stand is not required, and when the filled container is transported, it is impossible to leak the purified liquid through the bottom container. Filling of the container 5 can be carried out not only on the surface of the working kitchen area (above the sink), which, as a rule, is the most loaded, but also in any other place of the kitchen zone selected by the user, thereby improving the operational characteristics of the liquid cleaning plant .

The container 5, as well as the lever mechanism 29 and the float 33 are made of plastic materials and are in contact with the purified liquid. After some time after the start of operation of the installation for liquid purification, the container 5, as well as the lever mechanism 29 and the float 33 can be washed with disinfectants separately from the liquid purification unit 2, which also improves the operational characteristics of the liquid purification unit.

For carrying out the claimed invention, there are installations for purifying a liquid of a membrane type, preferably with a filtration rate of less than 1 liter per minute, both in the general case and in particular cases of execution, mainly known materials and elements used in the field of water treatment can be used and blocks.

Despite the fact that the present invention has been described in connection with the embodiment, which is currently considered the most practically advantageous and preferred, it should be understood that the invention is not limited to the described embodiments, but rather it covers various modifications and variations within the essence and scope of the proposed claims.

Claims (37)

1. Installation for cleaning liquid membrane type, preferably with a filtration rate of less than 1 liter per minute, consisting of means for supplying the liquid to be cleaned, liquid purification unit, means for draining the purified liquid, pressureless portable container for purified liquid, including a housing and a cover, control means the level of filling of the purified liquid, the device for controlling the flow of purified liquid, made with the possibility of transition to the open position with the beginning of the filtration process and the flow of liquid into the cont the tuner and the transition to the closed position with the end of the filtration process and the flow of liquid into the container by interacting with a means for controlling the filling level of the purified liquid, characterized in that the liquid purification unit comprises a purified liquid flow control device, which is an integral part of it, where the purified liquid flow control device made with the possibility of transition to the open position and connection with the container, as well as the possibility of transition to the closed position and disconnection from the container by interacting with means for controlling the level of filling of the purified liquid and with an additional element for installing it, while the element for installing the device for controlling the flow of purified liquid is located in the body or lid of the container, and the means for controlling the level of filling of the purified liquid, made with the possibility of holding the control device the stream of purified liquid in the open position, located in the container or in the liquid purification unit. 2. Installation for cleaning liquid membrane type according to claim 1, characterized in that the device for controlling the flow of purified liquid includes a control valve and connecting means. 3. The membrane-type liquid purification installation according to claim 1, characterized in that the purified liquid flow control device is configured to transition to the open position under the influence of physical force produced by the user. 4. Installation for cleaning liquid membrane type according to claim 2, characterized in that the connecting means consists of an adapter having a housing and an attachment element. 5. Installation for cleaning liquid membrane type according to claim 4, characterized in that the adapter is located at the outlet of the drainage means of the purified liquid, the input of which is connected to the output of the liquid purification unit. 6. Installation for cleaning liquid membrane type according to claim 2, characterized in that the control valve is located inside the adapter housing of the connecting means or on the means of removal of the purified liquid. 7. Installation for cleaning liquid membrane type according to claim 1, characterized in that the element for installing a device for controlling the flow of purified liquid consists of a housing having an installation cavity in communication with the container, and a stop zone. 8. Installation for cleaning liquid membrane type according to claim 7, characterized in that the stop zone is made in the form of a protrusion or plate on the inner side of the housing. 9. The membrane-type liquid purification installation according to claim 1, characterized in that the means for monitoring the filling level of the purified liquid, comprising a liquid level sensor, is located in the container body or in the container lid and has an actuator connected to the level sensor of the purified liquid. 10. Installation for cleaning liquid membrane type according to claim 1, characterized in that the means for controlling the filling level of the purified liquid containing the liquid level sensor is located in the device for controlling the flow of purified liquid and has an actuator connected to the level sensor of the purified liquid. 11. Installation for cleaning liquid membrane type according to claim 9, characterized in that the actuating element is made in the form of a lever mechanism. 12. Installation for cleaning liquid membrane type according to any one of paragraphs.9 and 10, characterized in that the actuating element is made in the form of a control unit. 13. Installation for cleaning liquid membrane type according to claim 11, characterized in that the lever mechanism includes a lever, one end of which is connected to a liquid level sensor, and the other is equipped with a fastening element. 14. Installation for cleaning liquid membrane type according to item 13, characterized in that the lever is fixed in the housing or the lid of the container with the possibility of rotation around its axis. 15. Installation for cleaning liquid membrane type according to any one of paragraphs.4 and 13, characterized in that the fastening elements are made in the form of a locking cavity on the outer side of the adapter housing and capable of interacting with the locking protrusion at one end of the lever, respectively. 16. Installation for cleaning liquid membrane type according to any one of paragraphs.4 and 13, characterized in that the fastening elements are made in the form of a locking protrusion on the outer side of the adapter housing and capable of interacting with the locking cavity at one end of the lever, respectively. 17. Installation for cleaning liquid membrane type according to claim 11, characterized in that part of the lever mechanism, preferably part of the lever, protrudes from the container. 18. Installation for cleaning liquid membrane type according to 17, characterized in that the lever mechanism is configured to interrupt the filtering process at any time under the influence of physical force produced by the user on its protruding part. 19. Installation for cleaning liquid membrane type according to any one of paragraphs.9 and 13, characterized in that the level sensor of the purified liquid is a float type sensor. 20. Installation for cleaning liquid membrane type according to any one of paragraphs.9 and 13, characterized in that the level sensor of the purified liquid is a dynamometric type sensor. 21. Installation for cleaning the membrane-type liquid according to claim 12, characterized in that the control unit is located in the housing of the element for installing the purified liquid flow control device and is equipped with a fastening element, the input of which is connected to the output of the control unit. 22. The membrane-type liquid purification installation according to claim 12, characterized in that the control unit is located in the adapter housing of the connecting means of the purified liquid flow control device and is provided with a fastening element, the input of which is connected to the output of the control unit. 23. Installation for cleaning liquid membrane type according to any one of paragraphs.4 and 21, characterized in that the fastening elements are made in the form of a locking protrusion on the outer side of the adapter housing and capable of interacting with it electrically controlled locking cavity on the inner side of the housing of the element for installing the device control the flow of purified liquid, respectively. 24. Installation for cleaning liquid membrane type according to any one of paragraphs.4 and 21, characterized in that the fastening elements are made in the form of a locking cavity on the outer side of the adapter housing and capable of interacting with him electrically controlled locking protrusion on the inner side of the housing of the element for installing the device control the flow of purified liquid, respectively. 25. The membrane-type liquid purification plant according to claim 22, wherein the fastening element is made in the form of an electrically-controlled protrusion on the outer side of the adapter body capable of fixing a device for controlling the flow of purified liquid in the container by the friction force arising from the contact of the protrusion with the inner side element housing for installing a purified liquid flow control device. 26. The membrane-type liquid purification plant of Claim 12, wherein the control unit is provided with a position sensor, the position sensor and the control unit being interconnected, and the output of the control unit being connected to the control valve inlet of the purified liquid flow control device. 27. Installation for cleaning liquid membrane type according to any one of paragraphs.9 and 10, characterized in that the liquid level sensor is a conductivity sensor. 28. Installation for cleaning liquid membrane type according to any one of paragraphs.9 and 10, characterized in that the liquid level sensor is a non-contact sensor. 29. Installation for cleaning liquid membrane type according to any one of paragraphs.2 and 4, characterized in that the device for controlling the flow of purified liquid further comprises a safety valve located inside the adapter housing of the connecting means. 30. Installation for cleaning liquid membrane type according to claim 1, characterized in that it contains a means of mineralization. 31. Installation for cleaning liquid membrane type according to claim 1, characterized in that it contains an indication of at least one filter element of the liquid purification unit. 32. Installation for cleaning liquid membrane type according to p, characterized in that the indicating device is located in the housing or lid of the container. 33. The membrane-type liquid purification installation according to claim 1, characterized in that the purified liquid flow control device is configured to move to the open position while simultaneously connecting to the container, and also to move to the closed position while disconnecting from the container by synchronous in time of interaction with a means of controlling the filling level of the purified liquid and with an additional element for its installation. 34. The membrane-type liquid purification installation according to claim 1, characterized in that the purified liquid flow control device is configured to move to the open position after being connected to the container, and also to move to the closed position before being disconnected from the container by means of a sequential time interaction with a means of controlling the filling level of the purified liquid and with an additional element for its installation. 35. Installation for cleaning liquid membrane type according to claim 1, characterized in that the means for draining the purified liquid is made, for example, in the form of a flexible hose, tube, flexible double hose or double tube. 36. Installation for cleaning liquid membrane type according to claim 1, characterized in that the means for draining the purified liquid further comprises a length lock. 37. Installation for cleaning liquid membrane type according to any one of paragraphs.4, 13, 21 and 22, characterized in that the fastening elements are configured to fix and hold the device for controlling the flow of purified liquid in the open position by friction or geometric closure.

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