KR20100007212A - Purification device - Google Patents

Abstract

PURPOSE: A purification apparatus is provided to use domestic water and industrial water stably by removing uranium, radon and volatile organic compounds effectively with a main body part, a cover part, purification parts, and a control part. CONSTITUTION: A purification apparatus includes a main body part, a cover part, a first purification part(30), a second purification part(40), and a control part. A pipeline on an inlet of the main body is connected to a plurality of electronic valves(V1,V2) and a pressure tank. A full water level sensor and a low water level sensor are installed at the bottom and the top of a multi-stage flow path. The first purification part has an air pump(31), a branch pipe(32), and an air discharge pipe(33).

Description

Purification device

The present invention can effectively remove or reduce uranium and dissolved natural radioactive radon and volatile organic compounds (VOCs) contained in water (for example, groundwater) supplied to households and businesses. It relates to a purifier to make.

In general, uranium and radon, which are natural radioactive materials, are dissolved in groundwater used as domestic or commercial water. Contaminated groundwater also contains benzene, toluene, gasoline additives (MTBE; Methyl-T-Butyl), carbon tetrachloride, dichloroethylene, and trihalomethanes (THMs), which are harmful to humans. ), Volatile organic compounds (VOCs) such as vinyl chloride, hydrogen sulfide and carbon dioxide are also dissolved.

의 알파 붕괴 과정에서 생성되며 반감기는 약 3.82일이다. 라돈은 지표수보다는 지하 수에 많이 포함되어 있으며, 이들 라돈이 다량 함유된 지하수를 섭취할 경우에 폐암과 위암 유발의 가능성이 높아진다. 따라서 지하수의 라돈을 제거하기 위한 다양한 연구가 진행되고 있다.In particular, radon is a naturally occurring colorless, tasteless and odorless gas.

Is generated during the alpha decay process and its half-life is about 3.82 days. Radon is found in groundwater rather than surface water, and the consumption of groundwater containing large amounts of radon increases the risk of lung and gastric cancer. Therefore, various researches for removing radon from groundwater have been conducted.

That is, the present invention has been made in view of the above-described trend, and to provide a purifier that can effectively remove uranium, radon and volatile organic compounds from water supplied for domestic or commercial use from a dual treatment purification function. There is a purpose.

The purifying apparatus of the present invention for achieving the above object has an inlet and an outlet of water as an upper opening type, and a main body having a multi-stage flow path having an up-down flow type from a partition of an upper and a lower support type to maintain a constant flow of water. part; A lid part which seals an upper opening of the main body part, and has a discharge port configured to discharge polluted gas of uranium, radon, and volatile organic solvent contained in the water; Bubbles are generated when water flows in a direction from the inlet to the outlet along the multi-stage flow path provided in the main body, thereby separating uranium, radon and volatile organic chemicals contained in the water from the water, and then discharging the outlet. A first purifying unit discharging to the outside through the first purifying unit; And a second purifying unit configured to adsorb uranium, radon and volatile organic chemicals not removed by the first purifying unit when water flows in a direction from the inlet to the outlet along the multistage flow path provided in the main body. ; It includes.

In addition, a jet pump and a sewage tank are connected to the discharge port of the main body so as to store water from which contaminants have been removed.

In addition, on the upper and lower sides of the flow path located on the discharge port side in the main body portion is provided with a high water level sensor and a low water level sensor that operates according to the final water level.

In addition, the high water level sensor and the low water level sensor is a float switch.

In addition, on the inlet side of the main body portion, a plurality of solenoid valves that are opened and closed by the control of the controller to control the inflow of water is provided.

The control unit may control the closing of the solenoid valve sequentially when the high water level sensor is operated, and the opening and controlling of the solenoid valve sequentially when the low water level sensor is operated.

In addition, the control unit is configured to control the first purifying unit to generate bubbles when the water flowing along the multi-stage flow path maintains the proper water level.

The first purifying unit may further include: an air pump driven under the control of the controller; A branch pipe branched to the air pump and disposed on a multistage flow path in the main body part; And an air discharge pipe connected to each branch pipe integrally and having a plurality of air holes to generate bubbles when the air is supplied according to the pumping of the air pump. It includes.

In addition, the branch pipe which is integral with the air discharge pipe is detachable from the air pump, and for the attachment and detachment of the branch pipe, the main body portion is configured with an auxiliary cover coupled.

In addition, the auxiliary cover is rotatable about an axis of one side, the other side of the auxiliary cover is configured with a locking portion.

In addition, the locking portion is composed of a spring and a pressing ball for pressing the cotton contact surface to prevent the separation of the branch pipe from the closing of the auxiliary cover, the groove portion for inserting a portion of the pressing ball in the main body portion Is formed.

The second purification section is an activated carbon filter disposed on a multistage flow path in the main body section.

In addition, the second purifying part is a structure that can be separated when the separation of the branch pipe in the main body portion for removal of the uranium and radon and volatile organic chemicals when the adsorption is made, in the body portion for the separation structure The filter fixing part for attaching and detaching the second purification unit is formed.

The purifier of the present invention removes uranium, radon and volatile organic compounds contained in the water through the activated carbon filter and the activated carbon filter. You will get the effect of using.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a combined perspective view showing a structure of a purifier according to an embodiment of the present invention, FIG. 2 is an exploded view of a purifier according to an embodiment of the present invention, and FIG. 3 is a structure of the purifier according to an embodiment of the present invention. The cross-sectional view shown is shown.

4 is an enlarged view of an air discharge pipe included in the purification apparatus according to the embodiment of the present invention, and FIG. 5 is a block diagram showing a control diagram of the purification apparatus according to the embodiment of the present invention.

1 to 5, the purification apparatus according to the embodiment of the present invention includes a main body portion 10, a cover portion 20, and first and second purification units 30 and 40 and a controller 50. It includes.

The main body 10 has an upper opening type, and an inlet 11 for inflow of water and an outlet 12 for discharging water are formed at the lower ends of the front and rear sides, respectively, and the pipeline on the inlet 11 side. There is a plurality of solenoid valve (V1) (V2) and the pressure tank 100 for controlling the flow of water is configured.

In addition, a jet pump 61 and a sewage tank 62 are connected to the pipeline on the outlet 12 side.

At this time, the inside of the main body portion 10 is discharged through the outlet 12 to maintain a constant flow of water flowing through the inlet 11, the upper and lower support partitions (a1) ( From a2), the multistage flow path U of the up-and-down flow type is formed.

In addition, the high and low water level sensor S1 and the low water level sensor S1 of the float switch type so as to be operated in accordance with the final water level on the upper and lower sides of the flow path U located on the outlet 12 side in the main body 10. Is installed.

The cover part 20 seals an upper opening of the main body part 10, and a discharge port 21 is configured to discharge uranium, radon, and volatile organic compounds included in the water.

The first purification unit 30 generates bubbles when water flows in the direction of the discharge port 12 from the inlet port 11 along the multi-stage flow path provided in the main body unit 10 to be included in the water. Separating uranium and radon and volatile organic compounds from water and then discharging them out through the outlet 21 includes an air pump 31, a branch pipe 32, and an air discharge pipe 33. .

The air pump 31 is driven under the control of the controller 50, and the branch pipe 32 is branched to the air pump 31 so as to be disposed on the multistage flow path in the main body 10. do.

In the state where the air discharge pipe 33 is integrally connected to the respective branch pipes 32, a plurality of air holes 33a to generate bubbles when air is supplied according to the pumping of the air pump 31 ) Is formed.

At this time, the branch pipe 32 which is integral with the air discharge pipe 33 is detachable from the air pump 31, the auxiliary cover (top) on one side upper end of the main body 10 for the detachable 71) is a combined configuration.

That is, in the state in which the auxiliary cover 71 is rotatable about the shaft 72 on one side as shown in FIG. 2, the branch pipe 32 is not separated from the other side of the auxiliary cover 71. Locking portion 73 to increase the coupling force so as to be configured.

At this time, the locking portion 73 is composed of a spring (73a) and the pressing ball (73b) for pressing the cotton contact surface to prevent the separation of the branch pipe 32 from the closing of the auxiliary cover (71), Body portion 10 is preferably configured with a groove portion 13 so that a portion of the pressing ball (73b) can be inserted.

Here, as shown in Figure 6, the auxiliary cover 71 may also be configured as a slide type, in this case, one surface of the auxiliary cover 71 made of the slide type and one surface of the main body portion 10, respectively. It is preferable to configure the base 81 and the latch 82.

The second purification unit 40 is the first purification unit when the water flows in the direction of the discharge port 12 from the inlet port 11 along the multi-stage flow path U provided in the main body portion 10 ( 30) to adsorb uranium, radon and volatile organic compounds that have not been removed by using a activated carbon filter, which is protected by a cover and can be attached and detached, and the main body 10 has a filter for desorption of the activated carbon filter. It is preferable to form the government 14.

Here, the activated carbon of the activated carbon filter is an aggregate of amorphous carbon in which micropores are formed, and is an adsorbent having a large internal surface area by forming fine pores of a molecular size in the activation process.

The control unit 50 is configured in a control panel (not shown) provided on an outer surface of the main body unit 10, and sequentially operates the solenoid valves V1 and V2 during the operation of the full water level sensor S1. When the low water level sensor S2 is closed, the solenoid valves V1 and V2 are sequentially opened and controlled, while water flowing along the multistage flow path is appropriately level in the flow path in the main body 10. It is configured to control the air pump 31 included in the first purifying unit 30 so that bubbles can be generated when maintaining.

Referring to Figures 1 to 5 attached to the operation according to the embodiment of the present invention configured as described above are as follows.

First, in a state in which a predetermined amount of water is stored in the pressure tank 100 so as to maintain a constant pressure, the low water level is sensed from the low water level sensor S2 in the main body 10 constituting the purification device, and the water level of the low water level sensor S2 is detected. When the binary operation is performed, the controller 50 sequentially opens and controls the plurality of solenoid valves V1 and V2 connected to the inlet 11 side pipeline of the main body 10 from the switching operation.

Here, the opening control of the plurality of solenoid valves V1 and V2 in sequence prevents noise generated when water is suddenly introduced into the main body 10 from the opening of the solenoid valves V1 and V2. To do this.

Then, the water stored in the pressure tank 100 from the opening of the solenoid valve (V1) (V2) is introduced into the interior through the inlet port 11 of the body portion 10, the inflow water is the body portion Through (10) through the flow path (U) formed by the upper and lower support type partitions (a1) (a2) to the outlet (12) side in the order of ① → ② → ③ → ④ → ⑤ → ⑥ → ⑦ Will be reached.

Here, the water reaching the outlet 12 side is maintained by the upper and lower support partitions a1 and a2 to maintain a constant speed.

At this time, the water is finally introduced into the flow path (U) side of the position of ⑦, when the water level rises to the upper side of the lower supporting partition wall (a2), the high water level sensor (S1) formed in the flow path (U) is the water level. The sensing operation is performed while the switching operation is performed, and the control unit 50 sequentially closes and controls the plurality of solenoid valves V1 and V2 from the switching operation, thereby blocking the inflow of water into the main body unit 10.

On the other hand, when the flow is kept constant along the flow path U formed by the upper and lower support walls a1 and a2 after the water flows into the main body 10 as described above. The controller 50 controls the first purification unit 30 to separate uranium, radon, and volatile organic compounds contained in the water from the water.

That is, the controller 50 operates the air pump 31 included in the first purification unit 30, and the air generated from the operation of the air pump 31 is multistage through the branch pipe 32. Guided to the air discharge pipe 33 is respectively disposed on the bottom surface of the flow path (U) made.

Then, the air is injected into the main body 10 through the multi-stage air hole 33a formed in the air discharge pipe 33, and thus bubbles are generated in the water. Dissociates radon, uranium and volatile organic compounds from the water and pushes them to the upper side of the body portion 10.

At this time, the upper side of the main body portion 10 is sealed by the cover portion 20 having a discharge port 21,

Uranium, radon, and volatile organic compounds that are collected on the upper side of the main body 10 are discharged to the outside of the main body 10 through the discharge port 21 of the cover 20.

In addition, the second purification section 40 made of an activated carbon filter is installed in the multi-stage flow path U in a fixed state by the filter fixing part 14,

In the second purifying unit 40, a portion of uranium, radon, and volatile organic compounds which are not separated from the water from the bubble generation of the first purifying unit 30 are adsorbed.

Therefore, since the separation and adsorption of uranium, radon, and volatile organic compounds is performed by the first and second purification units 30 and 40, the outlet port flows along the multi-stage flow path U in the main body unit 10. Water confined to the final flow path (U) side located on the (12) side is a state in which contaminants such as uranium and radon or volatile organic compounds have been removed, and the contaminant-removed water is pumped by the jet pump 61. It is stored in the holding tank 62 from the operation.

On the other hand, the second purification section 40 disposed on the multi-stage flow path U side in the main body unit 10 is separated from the main body unit 10 so that cleaning can be performed while the system operation is turned off. It is.

That is, after separating the cover portion 20 from the main body portion 10, as shown in Figure 2 attached to one side of the main body portion 10 to rotate the auxiliary cover 71 around the shaft 72. Alternatively, or as shown in Figure 6 attached to remove the latch 82 of the body portion 10 from the locking projection 81 of the auxiliary cover 71, the auxiliary cover 71 is moved horizontally slide.

Then, since the upper side of the separation pipe 32 is opened, by releasing the coupling portion of the separation pipe 32 and the air pump 31, the air discharge is integrally connected to the separation pipe 32, of course. Pipe 33 is to be separated from the main body portion 10.

Accordingly, when the pipes 32 and 33 are separated as described above, the second purifying part 40 made of the activated carbon filter fixed to the multi-stage flow path U in the body part 10 is the main body part. Separation is easily performed from (10), and accordingly, cleaning can be performed to easily remove uranium and radon or volatile organic compounds adsorbed on the activated carbon filter from the outside.

Here, when the auxiliary cover 71 is to be rotated about the shaft 72 so that the flow does not occur after the pipes 32 and 33 are recombined, the other side of the auxiliary cover 71. The locking portion 73 formed on the auxiliary cover 71 and the main body 10 to increase the coupling force.

That is, the locking portion 73 is a spring 73a and the pressing ball 73b for pressing the contact surface of the main body portion 10 so as to prevent the separation of the branch pipe 32 from the closing of the auxiliary cover (71). And a groove portion 13 formed in the main body portion 10 to allow a part of the pressing ball 73b to be inserted therein.

A portion of the pressing ball 73b is inserted into the groove portion 13 from the elastic force of the spring 73a, while the auxiliary cover 71 maintains a firmly coupled state without being detached from one surface of the main body portion 10, It will be able to hold the branch pipe (32).

Hereinafter, the present invention is not limited to the above specific preferred embodiments, and various modifications can be made by those skilled in the art without departing from the gist of the present invention as claimed in the claims. Of course, such changes are within the scope of the claims.

1 is a perspective view showing a structure of a purification device according to an embodiment of the present invention.

2 is an exploded view of a purification apparatus according to an embodiment of the present invention.

Figure 3 is a cross-sectional view showing the structure of the purification device in an embodiment of the present invention.

Figure 4 is an enlarged view of the air discharge pipe included in the purification apparatus according to the embodiment of the present invention.

Figure 5 is a block diagram showing a control diagram for the purification apparatus according to an embodiment of the present invention.

6 is a cross-sectional open view of a state in which the auxiliary cover is moved in a sliding manner in another embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

10; Main body 11; Inlet

12; Outlet 13; Home

14; Filter fixing 20; Cover

21; Outlet 30; 1st purification department

31; Air pump 32; Branch piping

33; Air discharge piping 33a; Air hole

40; A second purifying unit 50; Control

61; Jet pump 62; Holding tank

71; Auxiliary cover 72; shaft

73; Locking portion 73a; spring

73b; Compression ball 81; Jamming

82; Brace 100; Pressure tank

V1, V2; Solenoid valves a1, a2; septum

U; Flow path S1; Water level sensor

S2; Low water level sensor

Claims (13)

A main body part having an inlet and an outlet of water as an upper opening type, and having a multistage flow path having an upper and lower flow type formed from partition walls of upper and lower support types to maintain a constant flow of water; A lid part which seals an upper opening of the main body part, and has a discharge port configured to discharge polluted gas of uranium, radon, and volatile organic solvent contained in the water; Bubbles are generated when water flows in a direction from the inlet to the outlet along the multi-stage flow path provided in the main body, thereby separating uranium, radon and volatile organic chemicals contained in the water from the water, and then discharging the outlet. A first purifying unit discharging to the outside through the first purifying unit; And, A second purifying unit configured to adsorb uranium, radon and volatile organic chemicals not removed by the first purifying unit when water flows in a direction from the inlet to the outlet along the multistage flow path provided in the main body; Purifying device comprising a. The purifying apparatus according to claim 1, wherein a jet pump and a sewage tank are connected to the outlet of the main body so as to store water from which contaminants have been removed. The purifier according to claim 1, wherein a water level sensor and a low water level sensor are installed on the upper and lower sides of the flow path located at the outlet port side of the main body to operate according to the final water level. The purifier according to claim 3, wherein the full water level sensor and the low water level sensor are float switches. The purifying apparatus according to claim 1, wherein a plurality of solenoid valves are provided on the inlet side of the main body to control the flow of water to be opened and closed by the control of the controller. The purifying apparatus according to claim 5, wherein the controller controls the plurality of solenoid valves to be sequentially closed during the operation of the high water level sensor, and sequentially opens and controls the plurality of the solenoid valves during the operation of the low water level sensor. The purifying apparatus according to claim 5, wherein the control unit is configured to control the first purifying unit to generate bubbles when the water flowing along the multi-stage flow path maintains a proper water level. The method according to claim 1 or 7, wherein the first purification unit, An air pump driven by the control unit; A branch pipe branched to the air pump and disposed on a multistage flow path in the main body part; And, An air discharge pipe connected to each branch pipe integrally and having a plurality of air holes to generate bubbles when air is supplied according to the pumping of the air pump; Purifying device comprising a. The purge of claim 8, wherein the branch pipe that is integrated with the air discharge pipe is detachable from the air pump, and the main body part is configured with an auxiliary cover for detachable attachment and detachment of the branch pipe. Device. The purifying apparatus according to claim 9, wherein the auxiliary cover is rotatable about an axis of one side, and a locking part is formed at the other side of the auxiliary cover. The method of claim 10, wherein the locking portion is composed of a spring and the pressing ball for pressing the cotton contact surface to prevent the separation of the branch pipe from the closing of the auxiliary cover, a portion of the pressing ball can be inserted into the main body portion Purifying apparatus, characterized in that for forming a groove portion. The purifying apparatus according to claim 1, wherein the second purifying unit is an activated carbon filter each disposed on a multistage flow path in the main body. The method of claim 1 or 12, The second purifying unit is a structure that can be separated when the separation of the branch pipe in the body portion for removal of the uranium and radon and volatile organic chemicals when the adsorption is made, the body in the body portion for the separation structure 2 Purifier, characterized in that for forming a filter fixing for detachable attachment.

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