KR20120101772A - Filter performance evaluation device - Google Patents

Abstract

PURPOSE: An apparatus for evaporating the performance of filters is provided to continuously supply plenty of polluted water and to facilitate maintenance by simplifying the structure of an apparatus for evaporating the performance of filters. CONSTITUTION: An apparatus for evaporating the performance of filters includes a mixing tank(10), a storing tank(30), and filters(8). The mixing tank forms and stores polluted water of specific concentration based on pure water and additives. The storing tank stores the polluted water from the mixing tank. The filters purify the polluted water from the storing tank. The apparatus evaporates the performance of the filters. The apparatus further includes an additive tank(20), a conduit(20a), and an interlinking pump(21). The conduit connects the additive tank and the mixing tank. The connecting pump is installed at the conduit. The interlinking pump transfers the constant amount of liquid per unit time.

Description

Filter Performance Evaluation Equipment {FILTER PERFORMANCE EVALUATION DEVICE}

The present invention relates to a filter performance evaluation device, and more particularly, in order to determine the removal performance of specific substances such as volatile organic compounds or harmful heavy metals, influent containing the contaminant may be continuously supplied to the target filter. The present invention relates to an apparatus for evaluating filter performance.

A filter is a device for separating a foreign substance from a contaminated fluid and obtaining a purified fluid. The filter is also installed in home water purifiers and has been used in industrial and mechanical devices.

In order to evaluate the performance of such a filter, a method of preparing a contaminated fluid containing foreign matter, passing it through the filter, and measuring the degree of contamination of the passed fluid is used. Korean Unexamined Patent Publication No. 2003-0066884 (hereinafter referred to as 'prior art') discloses such a filter performance evaluation apparatus.

The filter performance evaluation apparatus according to the prior art includes a pure water storage tank in which pure water is stored, a pump for pumping circulating water, and a sewage tank controlled in such a manner that the pressure inside the tank is controlled to supply a sewage of a certain concentration. To create a.

However, the filter performance evaluation apparatus according to the related art performs feedback control by using various sensors to supply filthy water of a certain concentration, so that the flow path configuration is complicated, and maintenance of valves and pumps installed in the flow path is performed. There were problems such as high cost.

In addition, maintaining the concentration of the sewage may be dependent on the performance of the control device, there is a problem that it may be difficult to maintain a constant concentration of the sewage when the performance of the control device is low.

The present invention is to solve the above problems, the problem of the present invention can continuously supply a large amount of contaminated water having a constant pollution degree, and provides a filter performance evaluation device that is easy to manufacture and maintain a simple structure It is.

In order to solve the problems of the present invention as described above, the filter performance evaluation apparatus according to the present invention, receiving a pure water and additives, respectively, mixing tank for making and storing contaminated water of a specific concentration; A storage tank configured to receive and store the contaminated water generated in the mixing tank; And a filter for receiving and purifying the contaminated water of the storage tank, wherein the performance of the filter is evaluated.

In addition, the filter performance evaluation apparatus according to the present invention, the additive tank in which the additive is stored; A conduit connecting the additive tank and the mixing tank; It is installed in the pipeline, the peristaltic pump for sending a certain amount of liquid per unit time; further characterized in that it comprises a.

The filter performance evaluation apparatus according to the present invention may further include a controller electrically connected to the peristaltic pump to control the peristaltic pump so that only a predetermined amount of the additive in the additive tank flows into the mixing tank. .

In addition, the filter performance evaluation apparatus according to the present invention, the first pipe for supplying pure water to the mixing tank; A first valve installed in the first pipe line; A weight sensing unit for sensing a weight of the mixing tank; And a control unit electrically connected to the weight sensing unit and controlling the first valve to receive a weight value sensed by the weight sensing unit so that a predetermined amount of pure water is supplied.

In addition, the filter performance evaluation apparatus according to the present invention is characterized in that it further comprises a stirrer installed in the mixing tank to help the mixing of pure water and additives.

In addition, the filter performance evaluation apparatus according to the present invention, the water level sensor is installed in the storage tank for detecting the level of contaminated water in the storage tank; A second conduit connecting the mixing tank and the storage tank; A second valve installed in the second pipe; And a control unit electrically connected to the water level sensor to receive a water level value of the water level sensor and to open the second valve when the input value of the water level sensor corresponds to the low water level of the storage tank. It features.

In addition, the filter performance evaluation apparatus according to the present invention, the supply pipe is installed between the storage tank and the filter for supplying the contaminated water of the storage tank to the filter; And a supply pump installed in the supply pipe and supplying pressurized water to the filter.

In addition, the filter performance evaluation apparatus according to the present invention, the pressure control pipe branch branched from the supply pipe connected to the storage tank; And a pressure regulating valve installed in the pressure regulating pipe passage to block the pressure in the supply passage from rising above a predetermined pressure.

In addition, the filter performance evaluation apparatus according to the present invention, the outflow pipe path extending from the filter to the outside to guide the purified water passing through the filter to the outside; And an outlet valve installed in the outlet pipe passage.

In addition, the filter performance evaluation apparatus according to the present invention, the mixing tank for receiving pure water and additives, respectively, to make and store contaminated water of a specific concentration; A storage tank configured to receive and store the contaminated water generated in the mixing tank; A filter for purifying the contaminated water of the storage tank; An additive tank in which additives are stored; An additive pipe connecting the additive tank and the mixing tank; A peristaltic pump installed in the additive pipe line and sending a fixed amount of liquid per unit time; A first pipe for supplying pure water to the mixing tank; A first valve installed in the first pipe line; A weight sensing unit for sensing a weight of the mixing tank; The first sensor, the first valve, the peristaltic pump, and the water level sensor are electrically connected to each other so that the pure water is supplied until the weight value reaches a predetermined value by receiving the weight value detected by the weight sensing unit. A control unit for opening and closing the valve and driving the peristaltic pump for a predetermined time so that only a predetermined amount of the additive in the additive tank flows into the mixing tank, so that contaminated water of a specific concentration can be prepared in the mixing tank. It characterized in that it is possible to evaluate the performance of the filter according to the water quality of the purified water passing through the filter.

According to the filter performance evaluation apparatus according to the present invention as described above, it is possible to continuously supply a large amount of contaminated water having a constant pollution degree, the effect is that the structure is simple and easy to manufacture and maintenance.

1 is a conceptual diagram showing the flow path configuration of the filter performance evaluation apparatus according to the present invention.
2 is a conceptual diagram showing a control system of the filter performance evaluation apparatus according to the present invention.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the filter performance evaluation apparatus according to the present invention will be described in detail.

1 is a conceptual diagram showing the flow path configuration of the filter performance evaluation apparatus according to the present invention. As shown in FIG. 1, the filter performance evaluation apparatus according to the present invention includes a mixing tank 10 in which contaminated water is generated.

The mixing tank 10 mixes pure water and additives at a predetermined concentration to produce contaminated water having a specific concentration.

One side of the mixing tank 10 is connected to the first pipe line 3a for receiving pure water, and the first pipe line 3a is provided with a first valve 3. Pure water is supplied into the mixing tank 10 when the first valve 3 is opened, and supply of pure water is blocked when the first valve 3 is closed.

An additive tank 20 is installed at the other side of the mixing tank 10. The additive tank 20 is connected by the mixing tank 10 and the additive conduit 20a. A peristaltic pump 21 is installed in the middle of this pipeline 20a. The peristaltic pump 21 is a pump designed to deliver a fixed amount of liquid per unit time, and supplies a fluid having a flow rate proportional to the driving time to the mixing tank 10. When the additives stored in the additive tank 20 are made of a specific substance such as volatile organic compounds or harmful heavy metals, the filter performance of the characteristic substances can be evaluated.

An agitator 11 is installed in the inner space of the mixing tank 10. Since the vortex is formed in the fluid in the mixing tank 10 when the stirrer 11 is driven, pure water and additives introduced into the mixing tank 10 may be homogeneously mixed.

At the bottom of the mixing tank 10, a weight sensing unit 13 is installed. The weight sensing unit 13 may sense the weight of the fluid stored in the mixing tank 10 and the mixing tank 10. Since the weight of the mixing tank 10 itself is constant, the weight and volume change of the fluid stored in the mixing tank 10 may be calculated through the weight value detected by the weight sensing unit 13.

One side of the mixing tank 10 is provided with a first discharge pipe 15a. The first discharge line 15a extends from the lower side of the mixing tank 10 side. The first discharge valve 15 is installed in the middle of the first discharge line 15a. When the first discharge valve 15 is opened, the fluid inside the mixing tank 10 may be discharged through the first discharge line 15a. have. In an abnormal situation such as when there is too much fluid in the mixing tank 10 or when the fluid in the mixing tank 10 is improperly prepared, it is necessary to discharge the fluid in the mixing tank 10 to the outside. Alternatively, when the fluid in the mixing tank becomes unnecessary, the first discharge valve 15 may be opened to discharge the fluid inside the mixing tank 10 to the outside.

Filter performance evaluation apparatus according to the present invention includes a storage tank (30). Storage tank 30 is a storage space is formed therein to temporarily store the fluid prepared in the mixing tank 10 to be supplied to the outside when necessary for filter performance evaluation.

The second conduit 5a is installed between the mixing tank 10 and the storage tank 30. One end of the second conduit 5a is connected to the lower side of the mixing tank 10 side, and the other end of the second conduit 5a is connected to the upper part of the storage tank 30. The second valve 5 is installed in the middle of the second pipe line 5a. When the second valve 5 is opened, the fluid in the mixing tank 10 is supplied to the storage tank 30, and the second valve 5 is When closed, the fluid in the mixing tank 10 is trapped without being discharged to the outside in the mixing tank 10.

The water level sensor 33 is installed inside the storage tank 30 to sense the level of the fluid stored in the storage tank 30.

On the upper side of the storage tank 30, a gas discharge line 31a is installed. The gas discharge valve 31 is installed in the middle of the gas discharge line 31a, and when the gas discharge valve 31 is opened, the gas in the storage tank 30 can be discharged to the outside.

The second discharge pipe 35a is installed at the lower side of the storage tank 30. The second discharge pipe path 35a extends outward from the side surface of the storage tank 30, and a second discharge valve 35 is installed in the middle of the second discharge pipe path 35a. When the second discharge valve 35 is opened, the fluid inside the storage tank 30 is discharged to the outside through the second discharge pipe 35a. When the fluid in the storage tank 30 becomes unnecessary, the fluid in the storage tank 30 is discharged to the outside through the second discharge pipe path 35a.

In the filter performance evaluation apparatus according to the present invention, a filter 8 which is the object of performance evaluation is mounted. The filter 8 may be formed as a removable cartridge so that one filter performance evaluation apparatus may sequentially evaluate the performance of the plurality of filters 8.

A supply line 39a is installed between the filter 8 and the storage tank 30. One end of the supply conduit 39a is connected to the lower side of the storage tank 30, and the other end of the supply conduit 39a is connected to the inlet of the filter 8.

The supply pump 39 and the third valve 7 are provided in the middle of the supply line 39a. The supply pump 39 pressurizes the fluid stored in the storage tank 30 and sends the fluid to the filter 8. The third valve 7 opens and closes the supply line 39a, and when the third valve 7 is opened, fluid movement is possible through the supply line 39a. When the third valve 7 is closed, the supply line 39a is closed. Fluid movement through the tube becomes impossible.

A pressure regulating pipe passage 37a is branched between the third valve 7 and the filter 8 of the supply pipe 39a. The pressure regulation pipe 37a is branched from the supply pipe 39a and extends to the side of the storage tank 30. A pressure regulating valve 37 is installed in the middle of the pressure regulating passage 37a, and when the pressure regulating valve 37 is opened, the fluid is recovered from the supply passage 39a through the pressure regulating passage 37a into the storage tank 30. When the pressure control valve 37 is closed, it is impossible to recover the fluid from the supply line 39a to the storage tank 30 through the pressure control line 37a.

The pressure regulating valve 37 is for preventing the pipeline and the system from being destroyed by preventing an abnormally high pressure of the fluid flowing through the pipeline. The pressure regulating valve 37 is not opened or closed by a user's operation. The pressure regulating valve 37 is opened when the pressure of the fluid inside the pressure regulating passage 37a is higher than the set pressure, and closed when the pressure is lower than the set pressure. Therefore, the pressure of the fluid supplied to the filter 8 can be kept constant due to the pressure regulating valve 37, and the fluid discharged from the lower portion of the storage tank 30 is recovered to the upper portion of the storage tank 30. As a result, the fluid in the storage tank 30 may be mixed.

One end of the filter 8 is connected to the supply line 39a as described above, and the other end is connected to the outlet line 9a. Fluid flows into the filter 8 through the supply pipe 39a, and the fluid passing through the filter 8 is discharged to the outside through the outflow pipe 9a. An outlet valve 9 is installed in the middle of the outlet pipe line 9a so that the fluid can be discharged to the outside of the filter performance evaluation apparatus through the outlet pipe line 9a when the outlet valve 9 is opened.

2 is a conceptual diagram showing a control system of the filter performance evaluation apparatus according to the present invention. The control system of the filter performance evaluation apparatus according to the present invention includes an operation unit 41 which receives a control signal by a user's operation and a control unit 40 which receives an operation signal of the operation unit 41 and controls the entire system. .

The control unit 40 is electrically connected to the weight sensing unit 13 to receive a signal regarding the weight of the fluid stored in the mixing tank 10 through the weight sensing unit 13, and is electrically connected to the water level sensor 33 The sensor 33 receives a signal regarding the level of the fluid stored in the storage tank 30.

In addition, the control unit 40 includes a first valve 3 installed in the first conduit 3a, a second valve 5 installed in the second conduit 5a, and a third valve installed in the supply conduit 39a. (7) It is electrically connected with the outflow valve 9 provided in the outflow pipe path 9a, and opens and closes by transmitting an electrical signal to these valves.

In addition, the control unit 40 is electrically connected to the peristaltic pump 21 and the supply pump 39, and sends a drive signal to the peristaltic pump 21 and the supply pump 39. Therefore, the peristaltic pump 21 and the supply pump 39 are driven or stopped according to the drive signal of the controller 40.

The control method of the specific control part 40 is as follows.

First, the control unit 40 receives the weight signal from the weight sensing unit 13 when the input weight value is equal to the weight of the mixing tank 10, that is, when it is confirmed that there is no fluid in the mixing tank 10, the water level sensor ( 33) receives the water level signal. When the input water level value corresponds to the low level of the storage tank 30, and when it is confirmed that there is no fluid in the storage tank 30, the controller 40 opens the first valve 3. That is, when both the mixing tank 10 and the storage tank 30 are empty, the first valve 3 is opened to introduce pure water into the mixing tank 10.

The control unit 40 detects the weight of the mixing tank 10 through the weight sensing unit 13 after opening the first valve 3. As the pure water is supplied to the mixing tank 10, the weight value gradually increases. When this weight value becomes larger than a predetermined value, the control part 40 closes the 1st valve 3, and stops water supply to the mixing tank 10. FIG.

The control unit 40 drives the peristaltic pump 21 and the stirrer 11 for a predetermined time after closing the first valve 3. This setting time is set in consideration of the previously set weight value and the concentration of the desired preparation water.

The concentration of the preparation water produced by mixing in the mixing tank 10 is proportional to the amount of additives and inversely proportional to the amount of pure water. In addition, the amount of the additive contained in the preparation water is proportional to the predetermined driving time described above, and the amount of the pure water included in the preparation water is proportional to the predetermined weight value described above. Therefore, the concentration of the preparation water generated in the mixing tank 10 is proportional to the predetermined driving time and inversely proportional to the predetermined weight value.

Therefore, if the desired concentration of the preparation water is set and a predetermined driving time corresponding to the capacity of the mixing tank 10 is set, the driving time of the peristaltic pump 21 may be obtained through experiments. The driving time of the peristaltic pump 21 and the weight value of the mixing tank 10 obtained in this way may be stored in the controller 40 to automatically obtain a desired concentration of preparation water.

When the drive stops after driving the peristaltic pump 21 and the stirrer 11 for a predetermined time, the control unit 40 opens the second valve 5 to store the preparation water of the mixing tank 10 in the storage tank 30. Send to. In addition, the control unit 40 receives the water level value of the water level sensor 33 and closes the second valve 5 when the input value reaches the high water level so that the preparation water is supplied from the mixing tank 10 to the storage tank 30. Block it.

This prepares the filter performance evaluation apparatus for use. In this situation, when the user inputs a command to perform the filter performance evaluation to the control unit 40 through the operation unit 41, the control unit 40 receives the command to drive the supply pump 39 and the outlet valve 9 Open When the supply pump 39 is driven, the fluid in the storage tank 30 flows into the filter 8 through the supply pump 39 and the third valve 7, and the fluid passing through the filter 8 flows out of the outlet valve 9. It flows out through).

Thus, the performance of the filter 8 can be evaluated by supplying the contaminated water having a specific concentration to the filter 8, and discharging the purified water passing through the filter 8 through the outlet pipe 9a and measuring the quality of the purified water. Can be.

Filter performance evaluation apparatus according to the present invention is prepared in accordance with the appropriate concentration in the mixing tank 10, and then stored in the storage tank 30, it is easy to adjust the appropriate concentration and at the same time can continuously supply a large amount of preparation water. There is an advantage that it may be. In addition, the system has only two sensors, that is, the weight sensing unit 13 and the water level sensor 33, and has only two driving pumps, that is, the interlocking pump 21 and the supply pump 39, the structure is simple and easy to control the system The manufacturing cost is low and the maintenance is easy.

3 1st valve 5 2nd valve
7 3rd Valve 8 Filter
9 Outlet valve 10 Mixing tank
11 Stirrer 13 Weight sensing unit
15 First discharge valve 20 Additive tank
21 Peristaltic pump 30 Storage tank
31 Gas exhaust valve 33 Water level sensor
39 Supply Pump 40 Controls

Claims (10)

A mixing tank receiving pure water and additives to make contaminated water at a specific concentration;
A storage tank configured to receive and store the contaminated water generated in the mixing tank;
And a filter for supplying and purifying the contaminated water of the storage tank, wherein the filter performance evaluation apparatus comprises evaluating the performance of the filter. The method of claim 1,
An additive tank in which additives are stored;
A conduit connecting the additive tank and the mixing tank;
And a peristaltic pump installed in the conduit for transmitting a predetermined amount of liquid per unit time. The method of claim 2,
And a control unit electrically connected to the peristaltic pump to control the peristaltic pump such that only a predetermined amount of the additive in the additive tank flows into the mixing tank. The method of claim 1,
A first pipe for supplying pure water to the mixing tank;
A first valve installed in the first pipe line;
A weight sensing unit for sensing a weight of the mixing tank;
And a control unit electrically connected to the weight sensing unit to control the first valve to receive a weight value sensed by the weight sensing unit and to supply a predetermined amount of pure water. The method of claim 1,
Filter performance evaluation apparatus further comprises a stirrer installed in the mixing tank to help the mixing of pure water and additives. The method of claim 1,
A water level sensor installed in the storage tank and detecting a level of the contaminated water in the storage tank;
A second conduit connecting the mixing tank and the storage tank;
A second valve installed in the second pipe;
And a control unit electrically connected to the water level sensor to receive a water level value of the water level sensor and to open the second valve when the input value of the water level sensor corresponds to the low water level of the storage tank. A filter performance evaluation apparatus characterized by the above-mentioned. The method of claim 1,
A supply pipe installed between the storage tank and the filter to supply the contaminated water of the storage tank to the filter;
And a supply pump installed in the supply pipe and supplying the contaminated water to the filter. The method of claim 7, wherein
A pressure regulator pipe branched from the supply pipe and connected to the storage tank;
And a pressure regulating valve installed in the pressure regulating passage to block the pressure of the supply passage from rising above a predetermined pressure. The method of claim 7, wherein
An outflow pipe path extending outward from the filter to guide the purified water passing through the filter to the outside;
Filter performance evaluation apparatus further comprises; an outlet valve installed in the outlet pipe. A mixing tank receiving pure water and additives to make contaminated water at a specific concentration;
A storage tank configured to receive and store the contaminated water generated in the mixing tank;
A filter for purifying the contaminated water of the storage tank;
An additive tank in which additives are stored;
An additive pipe connecting the additive tank and the mixing tank;
A peristaltic pump installed in the additive pipe line and sending a fixed amount of liquid per unit time;
A first pipe for supplying pure water to the mixing tank;
A first valve installed in the first pipe line;
A weight sensing unit for sensing a weight of the mixing tank;
The first sensor, the first valve, the peristaltic pump, and the water level sensor are electrically connected to each other so that the pure water is supplied until the weight value reaches a predetermined value by receiving the weight value detected by the weight sensing unit. A control unit for opening and closing the valve and driving the peristaltic pump for a predetermined time so that only a predetermined amount of the additive in the additive tank flows into the mixing tank, so that contaminated water of a specific concentration can be prepared in the mixing tank. Filter performance evaluation apparatus that can evaluate the performance of the filter according to the water quality of the purified water passing through the filter.

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