CN205838709U - A kind of reverse osmosis membrane water cleaning systems - Google Patents

Abstract

The utility model provides a reverse osmosis membrane water purification system, comprising a reverse osmosis membrane, a control chip, a water inlet branch, a water purification branch, a water tank, a waste water branch and a faucet; A branch and a waste water branch; a first solenoid valve is arranged on the water inlet branch, a second solenoid valve is arranged on the waste water branch; a detection module is also included, and the detection module detects the water in the water purification branch Pressure and flow, generate water pressure detection signal and flow detection signal and output to the control chip, the control chip receives the water pressure detection signal and flow detection signal and generates a control signal to control the first electromagnetic valve and/or the second electromagnetic valve valve action. The utility model does not need to install a high-pressure pump to pressurize the water source in the water inlet branch, and realizes the on-off control of the water circuit through the cooperation between the control chip, the detection module, the solenoid valve and the water tank, and effectively controls the water purification of the reverse osmosis membrane. The overall energy consumption of the system improves the practicality.

Description

A reverse osmosis membrane water purification system

technical field

The utility model relates to the technical field of water purification equipment, in particular to a reverse osmosis membrane water purification system.

Background technique

Because it can remove various harmful impurities in water and has high removal efficiency, reverse osmosis water purifiers have won a large number of markets. According to statistics, the production and sales of household reverse osmosis water purifiers account for about 48% of the total household water purifiers, and the export volume accounts for 86% of the total household water purifiers.

In traditional reverse osmosis membrane water purifiers, the water circuit needs to be pressurized at the raw water end, and the technical means usually used is to increase the water pressure by adding a high-pressure pump at the raw water end. However, the flow of tap water is unstable after being increased by a high-pressure pump. On the one hand, it is necessary to add equipment such as wastewater ratio to keep the water pressure constant to avoid damage to the reverse osmosis membrane. On the other hand, the process of generating pure water under pressure is relatively slow, which may affect the water purification of the reverse osmosis membrane. machine experience. Moreover, since the overall energy consumption of the high-pressure pump is high, setting the high-pressure pump will increase the cost and power consumption of the entire reverse osmosis membrane water purifier.

Therefore, the traditional reverse osmosis membrane water purifier has the defects of long water production process, poor user experience and high power consumption.

Contents of the invention

The utility model aims to design a brand-new reverse osmosis membrane water purification system, which overcomes the defects of long water production process, poor user experience and high power consumption in traditional reverse osmosis membrane water purifiers.

The utility model provides a reverse osmosis membrane water purification system, comprising a reverse osmosis membrane, a control chip, a water inlet branch, a water purification branch, a water tank, a waste water branch and a faucet; A branch and a waste water branch; a first solenoid valve is arranged on the water inlet branch, a second solenoid valve is arranged on the waste water branch; a detection module is also included, and the detection module detects the water in the water purification branch pressure and flow, generate water pressure detection signal and flow detection signal and output to the control chip, the control chip receives the water pressure detection signal and flow detection signal and generates a control signal to control the first solenoid valve and/or the second solenoid valve The solenoid valve operates.

Further, the water tank has a pure water inlet end and a concentrated water inlet end; the pure water inlet end is respectively connected to the reverse osmosis membrane pure water outlet end and the pure water outlet port through the first tee.

Further, the detection module includes a high-pressure switch, and the high-voltage switch is arranged between the pure water outlet end of the reverse osmosis membrane and the pure water inlet end of the water tank.

Further, the detection module further includes a flow switch, and the flow switch is arranged at the pure water outlet.

Further, the concentrated water inlet end is provided with a second tee; the concentrated water inlet end is respectively connected to the reverse osmosis membrane concentrated water outlet end and the drainage outlet through the second tee.

Further, a third solenoid valve is also provided between the concentrated water outlet end of the reverse osmosis membrane and the concentrated water inlet end of the water tank.

Further, the flow switch detects and generates a flow detection signal and outputs it to the control chip, the control chip receives the flow detection signal and generates a control signal to the third solenoid valve, and the third solenoid valve receives the control signal and operates.

Further, a one-way valve is also provided on the water purification branch.

Further, the water tank has a pure water chamber and a concentrated water chamber; the pure water inlet end is set on the side wall of the pure water chamber, and the concentrated water inlet end is set on the side wall of the concentrated water chamber on the side wall.

Further, the front end of the reverse osmosis membrane is also provided with a pre-filter, and the pre-filter includes one or more of PP filter membrane, granular activated carbon or PP cotton filter.

Different from the traditional reverse osmosis water purification system, the reverse osmosis water purification system proposed by the utility model does not need to set up a high-pressure pump to pressurize the water source in the water inlet branch, but through the control chip, the detection module and the first electromagnetic The cooperation between the valve, the second solenoid valve and the water tank realizes the on-off control of the waterway, which simplifies the waterway design and functional components while ensuring the original water purification effect, and effectively controls the overall energy consumption of the reverse osmosis membrane water purification system , which improves the usability.

Description of drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention or the prior art, the following will briefly introduce the accompanying drawings that need to be used in the description of the embodiments or the prior art. Obviously, the appended drawings in the following description The drawings are some embodiments of the utility model, and those skilled in the art can also obtain other drawings according to these drawings on the premise of not paying creative labor.

Fig. 1 is a structural schematic diagram of an embodiment of the reverse osmosis membrane water purification system proposed by the utility model.

detailed description

The utility model provides a reverse osmosis membrane water purification system. The reverse osmosis membrane water purification system is mainly composed of a reverse osmosis membrane, a control chip, a water inlet branch, a water tank, a waste water branch and a faucet. The water inlet branch introduces tap water into the reverse osmosis membrane water purification system and purifies it through the reverse osmosis membrane. The pure water and concentrated water passing through the reverse osmosis membrane filter element flow into the water purification branch and the waste water branch through the pure water outlet and the concentrated water outlet respectively. The water tank is respectively connected with the water purification branch and the waste water branch, and plays the role of temporarily storing pure water and concentrated water. Different from the traditional reverse osmosis water purification system, the reverse osmosis water purification system proposed by the utility model does not need a high-pressure pump to pressurize the water source. Specifically, a first electromagnetic valve is arranged on the water inlet branch, and a second electromagnetic valve is arranged on the waste water branch. The reverse osmosis membrane water purification system also includes a detection module, which detects the water pressure and flow of the water purification branch, generates a water pressure detection signal and a flow detection signal, and outputs them to the control chip. The control chip receives the water pressure detection signal and the flow detection signal and generates a control signal to control the action of the first solenoid valve and/or the second solenoid valve, so that the water tank, the first solenoid valve, the second solenoid valve and the detection module cooperate to In the reverse osmosis membrane water purification system, the on-off control of the waterway avoids the use of high-pressure pumps to pressurize the waterway, reduces the energy consumption and water production cycle of the reverse osmosis membrane water purification system, and improves the user experience. Reasonable design, low energy consumption and good practicability.

In order to make the purpose, technical solutions and advantages of the embodiments of the utility model more clear, the technical solutions in the embodiments of the utility model will be clearly and completely described below in conjunction with the accompanying drawings in the embodiments of the utility model. Obviously, the described The embodiments are some embodiments of the present utility model, but not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by persons of ordinary skill in the art without making creative efforts belong to the scope of protection of the present utility model.

Referring to Fig. 1, it is a structural schematic diagram of the first embodiment of the reverse osmosis membrane water purification system proposed by the utility model. As shown in the figure, in this embodiment, the reverse osmosis membrane water purification system mainly consists of a reverse osmosis membrane 1, a control chip (not shown in the figure), a water inlet branch 2, a water purification branch 4, a water tank 7, and a waste water branch. Road 8 and a tap (not shown in the figure). Different from the prior art, in this embodiment, no high-pressure pump is provided at the front end of the reverse osmosis membrane 1 . The water inlet branch 2 communicates with the reverse osmosis membrane 1 through the pre-filter 11 , and the pre-filter 11 is arranged at the front end of the reverse osmosis membrane 1 . The pre-filter element 11 can be composed of one or more of PP filter membrane, granular activated carbon or PP cotton filter element, and can also be provided with more layers of filter membrane according to actual needs, and the filter membrane can also be selected from other filters with the same or similar The membrane performs the same function and is not limited here.

A first solenoid valve 3 is arranged on the water inlet branch 2, and the first solenoid valve 3 is arranged on the front end of the reverse osmosis membrane 1, and is used to control the water flow treated by the pre-filter element 11 to enter the reverse osmosis membrane 1 for filtration or Shut off the water flow into the reverse osmosis membrane 1. The concentrated water outlet end of the reverse osmosis membrane 1 is connected to the waste water branch 8, which is used to discharge the waste water treated by the reverse osmosis membrane 1. A second solenoid valve 10 is arranged on the waste water branch 8, and the second solenoid valve 10 is used to control On-off of waste water branch 8. The reverse osmosis membrane water purification system proposed in this embodiment also includes a water tank 7 , and the water tank 7 is composed of a pure water chamber 71 and a concentrated water chamber 72 . In order to optimize the design of the waterway, the pure water chamber 71 is arranged on the upper side of the water tank 7 , and the concentrated water chamber 72 is arranged on the lower side of the water tank 7 . The upper end of the pure water chamber 71 is provided with a pure water inlet port 73 , and the lower end of the concentrated water chamber 72 is provided with a concentrated water inlet port 74 . The pure water inlet 73 is respectively connected to the pure water outlet of the reverse osmosis membrane 1 and the pure water outlet 5 of the reverse osmosis membrane water purification system through the first tee 6, and further connected to the water tap for users to directly use pure water. The concentrated water inlet 74 is respectively connected to the concentrated water outlet and the drain outlet of the reverse osmosis membrane 1 through the second tee 9 . Therefore, the water tank 7 is connected to the water purification branch 4 and the waste water branch 8 through the first one-way 6 and the second three-way 9 . A one-way valve 13 is also arranged on the water purification branch 4 to prevent the water in the water tank 7 from flowing back into the reverse osmosis membrane 1 .

A third solenoid valve 11 is also arranged on the waste water branch 8 , and the third solenoid valve 11 is arranged between the concentrated water outlet end of the reverse osmosis membrane and the concentrated water inlet end 74 of the water tank 7 . In this embodiment, a detection module is also included, specifically, the detection module at least includes a high pressure switch 41 and a flow switch 42 arranged on the water purification branch 4 . The high pressure switch 41 is arranged between the pure water outlet end of the reverse osmosis membrane and the pure water inlet end 73 of the water tank 7 . The flow switch 42 is arranged at the pure water outlet 5 .

The working process of the reverse osmosis membrane water purification system provided in this embodiment is roughly as follows: when the water tap is closed. At this time, the flow switch 42 generates and outputs a first flow detection signal to the control chip, and the first flow detection signal represents that the water purification branch 4 has no immediate flow. Now the control chip outputs the first control signal to control the opening of the first electromagnetic valve 3, the opening of the second electromagnetic valve 10, the closing of the third electromagnetic valve 11, and the tap water passes through the pre-filter 11 and then enters the reverse osmosis membrane 1. The pure water purified twice enters the pure water cavity 71 of the water tank 7 through the water purification branch 4 and the one-way valve 13 for storage. During this process, the pressure in the pure water chamber 71 is greater than the pressure in the concentrated water chamber 72, and the concentrated water in the concentrated water chamber 72 is discharged from the reverse osmosis membrane water purification system through the waste water branch 8 along the drain outlet, and the reverse osmosis membrane 1 The waste water generated continuously is also discharged from the drainage outlet. The waste water immediately formed by the reverse osmosis membrane 1 can also be discharged through a branch of the waste water branch 8, and a waste water ratio of 12 can also be set on this branch.

When the pure water in the pure water chamber 71 of the water tank 7 is full, the high pressure switch 41 detects and generates a first pressure detection signal to the control chip, and the control chip receives the first pressure detection signal and generates a second control signal to the first solenoid valve 3 , control the first solenoid valve 3 to close. At this moment, there is still no water flowing through the flow switch 42 , the second solenoid valve 10 is kept open, and the third solenoid valve 11 is closed.

When the faucet is opened to receive water, there is water flowing through the flow switch 42, the flow switch 42 generates and outputs a second flow detection signal to the control chip, and the control chip receives the second flow detection signal and outputs a third control signal to control the second solenoid valve 10 is closed, and the third solenoid valve 11 is opened. At the same time, the high pressure switch 41 detects and generates a second pressure detection signal to the control chip, and the control chip receives the second pressure detection signal and generates a fourth control signal to control opening of the first solenoid valve 3 . The pressure in the pure water cavity 71 of the water tank 7 gradually decreases, and the concentrated water at the concentrated water outlet of the reverse osmosis membrane 1 enters the concentrated water cavity 72 of the water tank through the third solenoid valve 11 for storage and waits for the next drainage process.

Different from the traditional reverse osmosis water purification system, the reverse osmosis water purification system proposed by the utility model does not need to set up a high-pressure pump to pressurize the water source in the water inlet branch, but through the control chip, the detection module and the first electromagnetic The cooperation between the valve, the second solenoid valve and the water tank realizes the on-off control of the waterway, which simplifies the waterway design and functional components while ensuring the original water purification effect, and effectively controls the overall energy consumption of the reverse osmosis membrane water purification system , which improves the usability.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solutions of the present utility model, and are not intended to limit it; although the utility model has been described in detail with reference to the foregoing embodiments, those of ordinary skill in the art should understand that: It is still possible to modify the technical solutions recorded in the foregoing embodiments, or perform equivalent replacements for some of the technical features; and these modifications or replacements do not make the essence of the corresponding technical solutions deviate from the spirit of the technical solutions of the various embodiments of the present invention. and range.

Claims (10)

1. a reverse osmosis membrane water purification system, is characterized in that, comprises reverse osmosis membrane, control chip, water inlet branch, water purification branch, water tank, waste water branch and faucet; Wherein, described water tank communicates with described A water purification branch and a waste water branch; a first solenoid valve is arranged on the water inlet branch, and a second solenoid valve is arranged on the waste water branch; a detection module is also included, and the detection module detects that the water purification branch The water pressure and flow rate, generate water pressure detection signal and flow detection signal and output to the control chip, the control chip receives the water pressure detection signal and flow detection signal and generates a control signal to control the first solenoid valve and/or The second solenoid valve operates. 2. The reverse osmosis membrane water purification system according to claim 1, wherein the water tank has a pure water inlet and a concentrated water inlet; the pure water inlet is communicated with each other through the first tee Reverse osmosis membrane pure water outlet and pure water outlet. 3. The reverse osmosis membrane water purification system according to claim 2, wherein the detection module comprises a high-pressure switch, and the high-voltage switch is arranged at the pure water outlet end of the reverse osmosis membrane and the pure water inlet end of the water tank between. 4. The reverse osmosis membrane water purification system according to claim 3, wherein the detection module further comprises a flow switch, and the flow switch is arranged at the pure water outlet. 5. The reverse osmosis membrane water purification system according to claim 4, wherein the concentrated water inlet end is provided with a second tee; the concentrated water inlet end is respectively connected to the reverse osmosis through the second three way Membrane concentrated water outlet and drainage outlet. 6. The reverse osmosis membrane water purification system according to claim 5, characterized in that, a third solenoid valve is further arranged between the concentrated water outlet end of the reverse osmosis membrane and the concentrated water inlet end of the water tank. 7. The reverse osmosis membrane water purification system according to claim 6, wherein the flow switch detects and generates a flow detection signal to be output to a control chip, and the control chip receives the flow detection signal and generates a control signal to The third electromagnetic valve, the third electromagnetic valve receives the control signal and acts. 8. The reverse osmosis membrane water purification system according to claim 7, characterized in that a check valve is also arranged on the water purification branch road. 9. The reverse osmosis membrane water purification system according to claim 8, characterized in that, the water tank has a pure water chamber and a concentrated water chamber; the pure water inlet port is set on the side wall of the pure water chamber Above, the concentrated water inlet port is opened on the side wall of the concentrated water chamber. 10. The reverse osmosis membrane water purification system according to claim 9, characterized in that, the front end of the reverse osmosis membrane is also provided with a pre-filter, and the pre-filter includes a PP filter membrane, granular activated carbon or PP cotton filter one or more of them.