RU2547482C2 - Water treatment system with hydraulic control - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to water treatment with hydraulic control and can be used for drinking water treatment with the help of various algorithms of water flows switching and system remote hydraulic control. Proposed system is equipped with ejection device arranged to feed purified water to consumer at notable length from accumulation vessel.

EFFECT: hydrodynamic compensation of differences in length and height between purified water feed point and accumulation vessel.

5 cl, 1 dwg

Description

The present invention relates to a hydraulically controlled water purification system and is intended for the treatment of water, primarily drinking water, with the possibility of implementing algorithms for various switching of water flows and remote hydraulic control of the system.

Despite the widespread use of household reverse osmosis systems, there is a real problem of placing a clean water tap from the storage device of the water treatment system at a remote distance from each other, which is an important technical problem, the solution of which will reduce the energy consumption that is spent on servicing this type of system, especially since The need for low-capacity installations is particularly great and diverse. The inclusion of electric pumps in such systems increases their cost and complicates the design. In this regard, the development of technically simple water treatment systems with hydraulic control is relevant.

In the prior art, a water purification system US 6764595 [IPC B01D 61/10, 61/12, publ. 07/20/2004] using a storage tank such as a water-water tank, which is equipped with an elastic chamber located inside the storage tank and designed for purified water, and a displacement cavity for technical (tap) water formed by the space between the elastic chamber and the housing of the storage tank. To regulate the process of pumping water into the storage tank, the system is equipped with a hydraulic unit with two control valves connected in series, one after the other. The hydraulic unit contains a water pressure sensitive automatic primary control valve for pumping industrial water into the displacement cavity of the storage tank, which has a control and a controlled chamber. The control chamber of the water injection control valve is connected via a check valve to a clean water tap, and the input of the controlled chamber is connected to a source (water supply) of process water. Thus, the water purification system includes a filtration unit, a hydraulic unit, a storage tank and a clean water tap that communicate with each other using connecting elements. The disadvantage of the water purification system according to US Pat. No. 6764595 is that this system does not eliminate the differential pressure, which in turn brings the control pressure closer to the closing pressure of the inlet valve and therefore does not allow the connection of a clean water tap at a remote distance from the storage device.

In the prior art, a known water purification system is presented in RF patent No. 2421270 [IPC B01D 61/02, C02F 1/44, publ. 06/20/2011] and we have chosen as a prototype. The system includes a filtration unit, a hydraulic unit, a storage tank such as a water-water tank, a non-return valve and a clear water valve that communicate with each other using connecting elements, and the hydraulic unit contains an automatic valve with control and management cameras for pumping industrial water into the displacement cavity of the storage tank and drainage control, where the control valve for pumping industrial water into the displacement cavity is normally open. A disadvantage of the known water purification system is the inability to provide purified water to the consumer at a remote distance from the storage tank, i.e. this system should be installed in close proximity to a clean water tap, as the farther the clean water tap is installed from the storage tank, the faster the control valve for pumping industrial water into the displacement cavity of the storage tank will close.

In such water purification systems (US 6764595, RF No. 2421270), to control water from an elastic chamber of a storage tank such as a water-water tank, a process water injection control valve is used by supplying technical water to the displacement cavity when opening the tap for clean water. It should be noted that the pure water tap and the connecting elements have hydraulic resistance, which in turn leads to the appearance of a pressure drop on these elements and, as a result, brings the control pressure closer to the closing pressure of the control valve for pumping industrial water into the displacement cavity of the storage tank. This phenomenon imposes a restriction on the length and height of the connecting element from the storage device to the tap of clean water. The invention is aimed at eliminating these disadvantages.

The aim of the invention is to increase the efficiency of the water treatment system in the mode of water supply to the consumer by achieving a technical result.

The technical result consists in hydrodynamic compensation of differences in length and height between the point of supply of purified water and the storage capacity of the water treatment system.

The technical result is achieved by the fact that the hydraulically controlled water purification system includes a filtration unit, a hydraulic control unit, a storage tank, connecting elements and a purified water supply, the system being equipped with an ejection device that is configured to supply purified water to the consumer at a remote distance from the storage containers, while the ejection device is connected to the storage tank, the hydraulic unit and the means for supplying purified water using the only elements where the ejection device is installed in front of the purified water supply and connected to the hydraulic unit using connecting elements with the ability to control the injection of process water into the displacement cavity of the storage device, while the ejection device is installed on the connecting element between the storage device and the purified water supply, where the ejection device is installed in the means for supplying purified water, while the ejection device is installed but in the threaded sleeve of the purified water supply.

A distinctive feature of the claimed water purification system is the presence of an ejection device in its design, which allows the control pressure of the connecting element to be transferred from the storage tank to the purified water supply means and to the hydraulic unit, where the object of the control pressure is a process water injection control valve that controls water displacement from the storage cavity by supplying process water to the displacing cavity with an open cleaner nnoy water. In the present invention, the control pressure is transmitted from the hydraulic unit to the ejection device connected to the connecting element from the storage tank to the purified water supply means through the ejection device, and the creation of the vacuum or the transition point of the control pressure is at the point of association of these connecting elements and is an ejection device capable of creating a vacuum in the connecting element from the hydraulic unit to the cleaned feed means water when water flows through the connecting element from the storage tank to the means for supplying purified water. Due to the transfer of control pressure through the ejection device through the connecting element to the hydraulic unit, the control valve for pumping industrial water does not close. Thus, the hydraulic resistance of the connecting element from the storage tank to the purified water supply means was overcome. The proposed technical solution in the field of water purification using hydraulic control systems is novel and meets the criterion of inventive step, and its industrial applicability is confirmed by its description.

The figure shows a water treatment system with hydraulic control in General, where the control valve for pumping industrial water into the displacement cavity of the storage tank is normally open, the drain control valve is normally closed, and the purified water supply means is normally open.

The hydraulic water treatment system in general form (in Fig.) Contains a filtration unit 1, a hydraulic control unit 2, a storage tank 3, connecting elements 4 made, for example, in the form of flexible pipes and fittings, and a purified water supply means 5 connected with the hydraulic unit 2 through an ejection device 6, installed with the possibility of providing purified water to the consumer at a remote distance, for example, but not limited to, from 1 to 30 m from the storage tank 3. To the ejection device 6 the hydraulic unit 2 with the control valve 7 for pumping technical water into the displacement cavity 8 of the storage tank 3 with an elastic chamber 9 for purified water and located inside the storage device 3 is connected. The hydraulic unit 2 has a valve 7 that is sensitive to water pressure with control and controlled cameras and drainage control valve 10. The inlet of the filtration unit 1 is connected to a source of process water under pressure, and the output of the filtration unit 1 with purified water is connected to the elastic chamber 9 of the storage tank 3, and the elastic chamber 9 of the storage tank 3 is connected to the means 5 for supplying purified water through an ejection channel 4 device 6, and the output of the filtration unit 1 with impurities is connected by means of a connecting element 4 with drainage. The water filtration unit (1) is, for example, but not limited to, a membrane element (reverse osmosis or nanofiltration membrane in a housing) or a cascade of membrane elements. In the particular case (if a reverse osmosis membrane is used as a filtration unit or blocks), the inventive system may include a hydraulic shutoff valve (not shown in Fig.) Installed in front of the reverse osmosis membrane and connected via a connecting element 4 to this reverse osmosis membrane. Such a valve blocks the flow of water to the reverse osmosis membrane when there is no water flow in the water treatment system and the elastic chamber 9 of the storage tank 3 is completely filled with purified water. The inventive water purification system may include a prefilter, postfilter, mineralization unit (not shown in Fig.), While the prefilter is one or more filters for the pretreatment of industrial water, cleaning it from mechanical particles (e.g. sand) and / or chemical compounds ( for example, chlorine), and the post-filter is made of activated coconut charcoal and is designed to remove residual unpleasant odor and taste after storing purified water in an elastic chamber 9 of the storage tank 3. Ejection device ystvo 6 may be disposed on the connecting member 4 between the storage tank 3 and supply means 5, purified water, or be set in a threaded sleeve (Fig. not shown) feeding means 5 of purified water. The specific location of the ejection device is determined depending on the operating conditions and the dimensions of the hydraulic water treatment system. Preferably, the ejection device 6 is made in the form of a tapering cone-shaped confuser, passing into the working chamber of the ejection device 6, with the possibility of the formation of an ejection effect in this chamber at the moment of supplying purified water to the means 5, where the working chamber of the ejection device 6 passes into an expanding conical diffuser, while a hydraulic unit 2 is connected to the working chamber of the ejection device 6 by means of a connecting element. The ejection device 6 can be made in the form of a Ventu tube and or in the form of a supersonic nozzle. As a means 5 for supplying purified water, a faucet with a spout, or a mixer, or a faucet type drinking fountain can be used.

The water purification system with hydraulic control operates as follows. When you turn on the system for the first time, i.e. connecting it to a source of process water, an inlet tap opens (not shown in FIG.). Since the means 5 for supplying purified water is open, the pressure in the cavity of the elastic chamber 9 of the storage tank 3 slightly exceeds zero. And since the pressure drop across the filtration unit 1 is close to zero, the pressure in front of the filtration unit 1 is determined by the pressure in the cavity of the elastic chamber 9, and it also differs slightly from zero. Since in this case the filtration unit 1 is a significant hydraulic resistance, water does not pass through the filtration unit 1 and does not enter the cavity of the elastic chamber 9 of the storage tank 3, and from the source of process water enters the controllable chamber of the valve 7 for pumping technical water of the hydraulic unit 2 In the cavity of the controlled chamber of the pressure control valve 7, process water exerts pressure on a flexible membrane that seals it with the cavity associated with the atmosphere; the membrane, in turn, exerts pressure on the end face of the valve stem 7, and since there is no pressure in the control cavity at this time (the purified water supply means 5 is open), no pressure is exerted from the side of the control cavity on the stem end, which leads to displacement stock, i.e. the pressure control valve 7 is opened and technical water flows through it into the displacement cavity 8 of the storage tank 3. The technical water entering the displacement cavity 8 exerts pressure on the walls of the elastic chamber 9, thereby compressing it and squeezing out the technical air through the open means 5 supply of purified water to the atmosphere. This happens until the process water entering the displacement cavity 8 of the storage tank 3 fills the entire volume of the storage tank 3. In this case, the process water continues to exert pressure on the walls of the elastic chamber 9 of the storage tank 3, then the treated water cannot enter its cavity and falls into the open means 5 for supplying purified water and flows freely from its spout. When the purified water supply means 5 is closed, the flow of purified water stops, which leads to an increase in pressure within the system. In this case, the stem of the pressure control valve 7 begins to move towards the controlled cavity until it shuts off the water supply from it, as a result of which the water from the source of process water stops in the displacement cavity 8 of the storage tank 3. At the same time, the stem of the control valve 10 drainage begins to move towards the controlled cavity until it stops and opens, as a result of which the process water from the displacement cavity 8 of the storage tank 3 is drained through the valve 10 into the drainage, the technical pressure Coy water on an elastic wall of the chamber 9 in the storage container 3 is reduced, the elastic chamber 9 is filled with purified water. The process continues until the elastic chamber 9 occupies the entire volume provided to it by the storage tank 3. After the elastic chamber 9 is completely filled with purified water, the pressure inside the system begins to increase, the supply of process water to the inlet of the filtration unit 1 stops, i.e. the system occupies its original operating position, and the pressure in the hydraulic unit 2 of the system exceeds zero (0.6 kg s / cm ² ).

When you open the purified water supply 5, the pressure in the water treatment system drops, the drainage control valve 10 closes, stopping the access of process water from the displacement cavity 8 of the storage tank 3 to the drainage, and the process water injection control valve 7 opens, as a result of which the process water the valve 7 begins to flow into the displacement cavity 8 of the storage tank 3, creating pressure on the walls of the elastic chamber 9 and squeezing purified water out of it into the purified water supply means 5. However, the connecting elements 4 and the purified water supply means 5 have their own hydraulic resistances, the so-called local hydraulic resistances, which lead to a pressure drop on these elements and loss of energy of the supplied purified water to the consumer, which brings the control pressure closer to the closing pressure of the process water injection control valve 7 into the displacing cavity 8 of the storage tank 3. Thus, the purified water under pressure is sent through the connecting elements 4 through ejection device 6 and enters the purified water supply means 5. Due to the fact that the control chamber of the control valve 7 for pumping industrial water into the displacement cavity 8 of the storage tank 3 is connected to the ejection device 6, conditions are created that intensify the flow rate of purified water from the elastic chamber 9 of the storage tank 3 to the purified water supply means 5. The flow moving to the purified water supply means 5 at a high speed entrains the medium from the connecting element 4 from the hydraulic unit 2 to the ejection device 6, creating a vacuum in this section of the connecting element 4, this leads to a pressure drop in the control chamber of the valve 7 and provides full opening of the valve 7, which contributes to the maximum flow of process water into the displacing cavity 8 of the storage tank 3. When closing the means 5 for supplying purified water, the pressure in the connecting element 4 from of the capacity 3 to the purified water supply means 5 increases, the discharge control valve 7 closes, stopping the flow of process water into the displacement cavity 8 of the storage tank 3, and the drain control valve 10 opens, as a result of which the process water from the displacement cavity 8 is drained through valve 10 into drainage, the pressure of industrial water on the walls of the elastic chamber 9 in the storage tank 3 is reduced, the elastic chamber 9 is filled with purified water. Thus, as necessary in purified water, the user then opens or closes the purified water supply means 5, and the processes described above are repeated.

In accordance with the present invention, a hydraulically controlled water purification system is created with the possibility of providing purified water to the consumer at a remote distance from the storage tank. In the present description of the invention presents a preferred embodiment of the invention. Disclosure and description will be clear to specialists in this field of technology, various changes in form and details can be made without departing from the essence and scope of the claims of the claimed invention.

Claims (5)

1. The hydraulically controlled water purification system includes a filtration unit, a hydraulic unit, a storage tank, connecting elements and a purified water supply, characterized in that it is equipped with an ejection device installed with the ability to provide purified water to the consumer at a remote distance from the storage tank, this ejection device is connected to a storage tank, a hydraulic unit and a means for supplying purified water using connecting elements. 2. The system according to claim 1, characterized in that the ejection device is installed in front of the purified water supply and connected to the hydraulic unit using connecting elements with the ability to control the injection of process water into the displacement cavity of the storage tank. 3. The system according to claim 2, characterized in that the ejection device is mounted on the connecting element between the storage tank and the means for supplying purified water. 4. The system according to claim 1, characterized in that the ejection device is installed in the means for supplying purified water. 5. The system according to claim 4, characterized in that the ejection device is installed in the threaded sleeve of the purified water supply means.