KR102595708B1 - Filter media replacement device - Google Patents

Abstract

The present invention relates to a filter medium replacement device for pumping the filter medium without damage using compressed air and significantly reducing water usage in the filtration unit.
For this purpose, the filter medium replacement device is a replacement unit that pumps the first filter medium, which is the filter medium to be introduced into the filtration unit, or the second filter medium, which is the filter medium contained in the filtration unit, using compressed air, and a replacement unit that injects the pumped second filter medium into a collection bag. Includes at least one of the collection units.

Description

Filter media replacement device {FILTER MEDIA REPLACEMENT DEVICE}

The present invention relates to a filter medium replacement device, and more specifically, to a filter medium replacement device for pumping the filter medium without damage using compressed air and significantly reducing water usage in the filtration unit.

As industrialization progresses and population increases, problems arise in securing the quality and quantity of water supply. However, in the past, the problem of securing quantity was the priority, but recently, as environmental pollution, especially the contamination of water sources, has intensified, interest in the quality of water has increased.

As the water source becomes more severely polluted, the water purification process becomes more complicated, and methods of adding various types of chemicals have emerged. However, when the water source is not severely polluted, safe household use can be obtained with simple water purification processes such as precipitation, filtration, disinfection, and adsorption. could be supplied.

Small-scale water purification devices using conventional filters require frequent filter replacement every 2 to 3 months, excessive replacement costs, adverse effects due to the proliferation of bacteria over the replacement period, and limitations in water purification ability, so large businesses use water other than drinking water. It has the drawback of not being able to meet the needs of the kitchen.

As the scale of water purification increases, water purification devices using filter media are used. Here, the filter medium introduced into the water purification device must be replaced with a new filter medium after a certain period of time has elapsed. In order to replace the filter medium in a conventional water purification device, a method of pumping the filter medium using a large electric motor pump was used. Looking at the conventional filter material replacement method, divers are deployed from the bottom of a large water purification device containing water using an electric motor pump, hold the suction pipe, suck in and discharge the filter material, and sort it through a sorter.

According to the conventional filter replacement method, the following problems occurred.

First, a high degree of fatigue increases for divers and workers, and as divers are put into the filtration tank containing the filter material and adjust the suction pipe, they are exposed to safety accidents such as risking the lives of divers, and repeated work stoppages for the safety of divers result in increased fatigue. This extremely reduces work efficiency and productivity, making it unsuitable.

Second, due to the discharge characteristics of the electric motor pump, a large amount of water is discharged from the purification device together with the filter medium, resulting in a large amount of water loss, and work efficiency is reduced due to work interruption due to the load of the electric motor.

Third, as an electric motor pump is used, a separate sorter is required depending on the type of filter medium, resulting in additional costs.

Fourth, since an electric motor pump is used when introducing new filter media into the filtration tank, the filter media is damaged by collision between the impeller of the motor pump and the filter media, causing the particles in the filter media to become smaller, and the efficiency of the filter media in the water purification device is rapidly reduced. I do it.

(1) Republic of Korea Patent Publication No. 10-0299349 (Title of invention: Drinking water purification device and method, announced on October 27, 2001) (2) Republic of Korea Patent Publication No. 10-0337541 (Title of invention: Safe water purification treatment system without chemicals, announced on May 21, 2002) (3) Republic of Korea Patent Publication No. 10-2005-0090058 (Title of invention: Integrated automated water purification system with combined functions of sand filtration tank and membrane separation filtration tank, announced on September 9, 2005)

The purpose of the present invention is to solve the conventional problems and provide a filter medium replacement device that pumps the filter medium without damage using compressed air and significantly reduces water usage in the filtration unit.

According to a preferred embodiment for achieving the object of the present invention described above, the filter medium replacement device according to the present invention uses compressed air to replace a first filter medium that is a filter medium to be introduced into a filtration unit or a second filter medium that is accommodated in the filtration unit. A replacement unit for pumping filter media; and a collection unit that injects the pumped second filter medium into a collection bag; Includes at least one of

Here, the replacement unit includes a buffer tank capable of accommodating the first filter medium or the second filter medium; A suction ejector that depressurizes the buffer tank using compressed air; and a discharge ejector that discharges the first filter medium or the second filter medium accommodated in the buffer tank using compressed air.

Here, the buffer tank includes a driving inlet to which the suction ejector is coupled; a filtration inlet through which the first filter medium or the second filter medium flows as the buffer tank is depressurized; a filter outlet through which the first filter medium or the second filter medium is discharged according to the operation of the discharge ejector; and a guide partition provided inside the buffer tank to face the filtration inlet, and guiding the first filter medium or the second filter medium flowing through the filtration inlet to the filtration outlet.

Here, the inductive partition wall includes: a fixed partition fixed to the inside of the buffer tank to face the filtering inlet; and a rotating partition rotatably coupled to the lower end of the fixed partition via the partition axis.

Here, the suction ejector includes a suction chamber in communication with the inside of the buffer tank; A suction diffuser that communicates with the suction chamber and depressurizes the suction chamber as compressed air passes through it; and a suction nozzle module that sprays compressed air toward the suction diffuser to depressurize the suction chamber.

At this time, the suction diffuser includes a suction convergence cone portion coupled to the suction chamber and having a cone shape whose inner diameter gradually decreases in response to the moving direction of the compressed air; a suction pressure portion extending from the suction convergence cone portion and having a diameter equal to or smaller than the minimum inner diameter of the suction convergence cone portion; and a suction diffusion cone portion extending from the suction pressure portion and having a cone shape whose inner diameter gradually increases from the suction pressure portion in response to the moving direction of the compressed air.

Here, the suction nozzle module includes: a suction nozzle body coupled to the other side of the suction chamber; a suction nozzle unit coupled to the suction nozzle body to face the suction diffuser and spraying compressed air toward the suction diffuser; and a suction control unit that reciprocates the suction nozzle portion in the suction nozzle body in response to the moving direction of compressed air.

Here, the discharge ejector includes: a discharge chamber communicating with the interior of the buffer tank; An exhaust diffuser that communicates with one side of the exhaust chamber and depressurizes the exhaust chamber as compressed air passes through it; and a suction nozzle module that sprays compressed air toward the discharge diffuser to depressurize the discharge chamber.

At this time, the discharge diffuser includes a cone-shaped discharge convergence cone portion coupled to the discharge chamber and whose inner diameter gradually decreases in response to the moving direction of the compressed air; a discharge pressure portion extending from the discharge convergence cone portion and having a diameter equal to or smaller than a minimum inner diameter of the discharge convergence cone portion; and a cone-shaped discharge diffusion cone portion that extends from the discharge pressure portion and whose inner diameter gradually increases from the discharge pressure portion in response to the moving direction of the compressed air.

Here, the discharge nozzle module includes: a discharge nozzle body coupled to the discharge chamber; a discharge nozzle unit coupled to the discharge nozzle body to face the discharge diffuser and spraying compressed air toward the discharge diffuser; and a discharge control unit that reciprocates the discharge nozzle portion in the discharge nozzle body in response to the moving direction of compressed air.

Here, the discharge ejector includes a connection chamber coupled to the discharge diffuser to surround the discharge diffuser and receiving fluid discharged from the suction ejector; and a communication hole formed through the exhaust diffuser so that the fluid contained in the connection chamber is supplied to the interior of the exhaust diffuser.

Here, the collection unit includes: a collection tank that accommodates the pumped second filter medium and is provided with a suction/discharge unit at the bottom through which the second filter medium is discharged; A discharge door module that opens and closes the collection discharge port; and a collection support part that separates the collection tank from the ground.

At this time, the collection support part includes a collection frame coupled to the collection tank. In addition, the collection support unit further includes a collection moving unit coupled to the collection frame so that the collection frame can move on the ground. In addition, the collection support unit includes a collection rail coupled to the collection frame to form a movement path of the collection bag capable of accommodating the second filter medium discharged from the collection tank; and a bag holder on which the collection bag is seated and slidably coupled to the collection rail.

Here, the discharge door module includes: a discharge door portion rotatably coupled to the collection outlet via a door axis to open and close the collection outlet; and a door driving unit that pivots the discharge door unit in a forward and reverse direction based on the door axis.

Here, the door driving unit includes a pneumatic cylinder operated by compressed air.

Here, the collection unit further includes an opening/closing valve that selects whether the second filter medium is delivered to the collection tank.

Here, the on-off valve includes a butterfly valve operated by compressed air.

Here, the collection unit includes a level sensor that detects the storage height of the second filter medium accommodated in the collection tank; and a collection control unit that controls the opening and closing operation of the discharge door module in response to the accommodation height of the second filter medium detected by the level sensor.

The filter material replacement device according to the present invention further includes a compressor that supplies compressed air to at least one of the replacement unit and the collection unit.

The filter material replacement device according to the present invention further includes a distribution header for distributing compressed air.

According to the filter medium replacement device according to the present invention, the filter medium can be pumped without damage using compressed air, and the amount of water used in the filtration unit can be significantly reduced.

In addition, the present invention allows the first filter medium or the second filter medium to be easily sucked into the buffer tank using compressed air through the detailed connection relationship of the replacement unit, and the first filter medium contained in the buffer tank can be easily discharged using compressed air. This can be delivered to the filtration unit, or the second filter medium contained in the buffer tank can be easily discharged using compressed air and delivered to the collection unit, collection bag, or separator.

In addition, the present invention stably delivers the first filter medium or second filter medium flowing into the filter inlet to the filter outlet through a detailed coupling relationship in the buffer tank, and prevents the first filter medium or second filter medium from scattering inside the buffer tank. It can be suppressed.

In addition, the present invention ensures that the first filter medium or second filter medium flowing into the filtration inlet is stably accommodated inside the buffer tank through the detailed coupling relationship of the guide partition, and the first filter medium or second filter medium flows back from the filtration inlet. can be prevented.

In addition, the present invention can prevent the first filter medium or second filter medium contained in the buffer tank from being transmitted to the suction ejector through the drive suction port through the coupling relationship of the drive filter.

In addition, the present invention clearly reduces the pressure of the suction chamber and the buffer tank through the coupling relationship of the suction ejector, and can easily lower the pressure of the air discharged from the suction diffuser. In addition, the Venturi effect can be clearly implemented through the detailed coupling relationship of the suction diffuser, making it easy to decompress the suction chamber.

In addition, the present invention can adjust the injection position of compressed air sprayed from the suction nozzle unit through the coupling relationship of the suction nozzle module, adjust the decompression ability in the suction chamber, and distinguish the types of filter media to accommodate them in the buffer tank. You can.

In addition, the present invention can clearly suction the first or second filter medium contained in the buffer tank through the coupling relationship of the discharge ejector and easily lower the pressure of the fluid discharged from the discharge diffuser. In addition, the venturi effect can be clearly implemented through the detailed coupling relationship of the discharge diffuser, making it easy to suction into the discharge chamber.

In addition, the present invention can adjust the injection position of the compressed air sprayed from the discharge nozzle unit through the coupling relationship of the discharge nozzle module, adjust the decompression ability in the discharge chamber, and control the first filter media or second filter material discharged from the buffer tank. The discharge rate or discharge pressure of the filter material can be adjusted.

In addition, the present invention can increase the discharge speed of the first filter medium or second filter medium discharged through the discharge ejector through the additional coupling relationship of the discharge ejector, and smooth discharge of the first filter medium or second filter medium.

In addition, the present invention allows the replacement unit to be freely moved through the replacement moving part.

In addition, the present invention can stably accommodate the pumped second filter agent through the detailed connection relationship of the collection unit.

In addition, the present invention allows the collection bag to be easily placed on the lower side of the collection tank through the detailed connection relationship of the collection support part. In addition, the collection tank can be moved freely through the collection moving part. In addition, the collection bag can be moved smoothly through the collection rail and the bag holder, and the collection bag containing the second filter material can be easily removed from the lower side of the collection tank.

In addition, the present invention can easily open and close the collection outlet through the door driving part.

In addition, the present invention can easily open and close the collection outlet using only compressed air without additional driving means through a pneumatic cylinder.

Additionally, the present invention can control the second filter medium delivered to the collection tank through the additional configuration of an on-off valve.

In addition, the present invention can smoothly operate the on-off valve using only compressed air without additional driving means through the butterfly valve.

In addition, the present invention can control the discharge timing of the second filter medium received through the additional coupling relationship of the collection unit. In addition, the collection control unit controls the opening/closing valve and the discharge door module in conjunction with each other, so that the second filter medium can be accommodated in the collection tank at a preset collection amount, and the second filter medium contained in the collection tank can be easily discharged.

Additionally, the present invention can easily supply compressed air to the unit without additional driving means. In addition, the distribution header allows the suction ejector, discharge ejector, and collection unit to operate smoothly with one compressor.

In addition, the present invention can be used not only in water purification plants and wastewater treatment plants, but also in shipyards, oil tankers, bulk unloading, etc., and improves various work sites by stably supplying pneumatic devices without the need for engine-type suction devices or electric motor pumps with high load rates at high rpm. This is possible and shows high efficiency.

In addition, the present invention can efficiently vacuum transport high-density filter media and foreign substances over long distances, and can minimize or prevent damage to the filter media by applying a valve operation method that suppresses or prevents pneumatic shock when suctioning and discharging the filter media. .

In addition, the present invention can maintain the inside of the buffer tank up to a maximum vacuum of 8000 mmAq for a long time, and can quickly and stably treat the filter media and foreign substances in the filtration unit.

Figure 1 is a diagram showing a filtration unit to which a filter medium replacement device according to an embodiment of the present invention is applied.
Figure 2 is a diagram illustrating a configuration for pumping a filter medium using a filter medium replacement device according to an embodiment of the present invention. (a) shows the filter medium contained in the filtration unit in (a). (b) shows a configuration in which the filter medium replacement device according to an embodiment of the present invention pressurizes the filter medium to be introduced into the filtration unit.
Figure 3 is a diagram showing a replacement unit in the filter material replacement device according to an embodiment of the present invention.
Figure 4 is a diagram showing a buffer tank included in the replacement unit in the filter material replacement device according to an embodiment of the present invention.
Figure 5 is a diagram showing a suction ejector included in the replacement unit in the filter material replacement device according to an embodiment of the present invention.
Figure 6 is a diagram showing a discharge ejector included in the replacement unit in the filter medium replacement device according to an embodiment of the present invention.
Figure 7 is a diagram showing a collection unit in a filter medium replacement device according to an embodiment of the present invention.

Hereinafter, an embodiment of a filter medium replacement device according to the present invention will be described with reference to the attached drawings. At this time, the present invention is not limited or limited by the examples. Additionally, when describing the present invention, detailed descriptions of well-known functions or configurations may be omitted to make the gist of the present invention clear.

The filtration unit 40 according to an embodiment of the present invention filters foreign substances contained in the treated water as the incoming treated water passes through the filter medium, and discharges the filtered water containing the foreign substances. The filtration unit 40 according to an embodiment of the present invention may include a filtration tank 410 and a filtration buffer tank 430, as shown in FIG. 1.

The filtration tank 410 filters foreign substances contained in the treated water as the treated water is supplied. A filtration delivery unit 411 through which water to be treated flows into the upper side wall of the filtration tank 410 is provided. Since the filtration tank 410 according to an embodiment of the present invention adopts a drop-type filtration method, a strainer 412 through which the filtered water passes is provided at the bottom of the filtration tank 410. A filter material for filtering the water to be treated into filtered water is stacked on the bottom of the filter tank 410 or the strainer 412. The filter medium can be divided into a first filtration material 413 representing a first size, and a second filtration material 414 laminated on the first filtration material 413 and representing a second size smaller than the first size. In one embodiment of the present invention, the first filtration material 413 may represent gravel and the second filtration material 414 may represent sand. At this time, the filter material is prevented from passing through the strainer 412.

The filtration buffer tank 430 accommodates the filtrated water discharged from the filtration tank 410. The filtered water contained in the filtration buffer tank 430 is discharged to the next process.

The filtration unit 40 according to an embodiment of the present invention may further include at least one of an input tank 420 and an discharge tank 440, as shown in FIG. 1.

The input tank 420 accommodates the treated water supplied to the filtration tank 410. The input tank 420 is provided on the side of the filtration tank 410 and can serve as a buffer to accommodate the water to be treated. The input tank 420 is in communication with the filtration delivery unit 411 and the treated water is supplied to the input tank 420, so that the treated water can be supplied to the filtration tank 410 through the filtration delivery unit 411. The side wall of the input tank 420 is provided with a filtration inlet 421 through which water to be treated flows. Here, when the filtration input unit 421 is disposed at the same or higher position than the filtration delivery unit 411, the pumping force of the treated water supplied to the input tank 420 can be reduced. In addition, when the filtration input unit 421 is placed at a lower position than the filtration delivery unit 411, the pumping force of the treated water supplied to the input tank 420 increases, but foreign substances remain in the input tank 420. can be suppressed from doing so.

The discharge tank 440 discharges the filtered water supplied from the filtration buffer tank 430. A filtration discharge portion 441 through which filtered water is discharged is provided at the bottom of the discharge tank 440 or the bottom of the side wall of the discharge tank 440.

Since the overflow partition wall 450 is disposed between the filtration buffer tank 430 and the discharge tank 440 at a height lower than the height of the input tank 420 and spaced apart from the input tank 420, the filtration buffer tank 430 As the filtered water is replenished, the filtered water overflows from the overflow partition wall 450 and is delivered to the discharge tank 440.

At this time, the filter medium stacked in the filtration tank 410 must be replaced with a new filter medium after a certain period of time has elapsed. Accordingly, the filter medium replacement device according to an embodiment of the present invention can be used.

As shown in FIG. 2, the filter medium replacement device according to an embodiment of the present invention pumps the first filter medium and supplies it to the filtration unit 40, pumps the second filter medium and supplies it to the filtration and collection means, or pumps the second filter medium to supply it to the filtration and collection means. The second filter agent can be added to the collection bag 20a at a preset collection amount. Here, the first filter medium refers to the filter medium to be introduced into the filtration unit 40, and the second filter medium refers to the filter medium accommodated in the filtration unit 40. Additionally, the filtration and collection means may include at least one of a collection unit 20, a collection bag 20a, and a sorting unit 50.

The filter replacement device according to an embodiment of the present invention may include at least one of a replacement unit 10 and a collection unit 20.

The replacement unit 10 pumps the first or second filter medium using compressed air.

The replacement unit 10 includes a buffer tank 110 that can accommodate the first or second filter medium, a suction ejector 120 that depressurizes the buffer tank 110 using compressed air, and a buffer tank 110 that uses compressed air to depressurize the buffer tank 110. It may include a discharge ejector 130 that discharges the first or second filter medium accommodated in (110).

The buffer tank 110 includes a driving inlet 111 to which the suction ejector 120 is coupled, a filtration inlet 112 through which the first or second filter media flows as the buffer tank 110 is depressurized, and a discharge ejector ( 130) is provided inside the buffer tank 110 to face the filtration outlet 113 through which the first or second filter media is discharged, and the filtration inlet 112, and flows in through the filtration inlet 112. A guiding partition 115 that guides the first or second filter media to the filtration outlet 113 may be included.

The driving inlet 111 is provided in the central portion of the upper surface of the buffer tank 110 to ensure uniform decompression of the buffer tank 110.

The filtration inlet 112 is provided on the upper side of the buffer tank 110 to maximize the capacity of the first or second filter medium in the buffer tank 110. Since the driving filter 114 is coupled to the filtering inlet 112, foreign substances formed in the buffer space can be prevented from being transmitted to the suction ejector 120.

The filtration outlet 113 is provided on the lower surface of the buffer tank 110 to facilitate smooth discharge of the first or second filter medium contained in the buffer tank 110. The lower part of the buffer tank 110 has a cone shape with an inner diameter that gradually becomes smaller and converges to the filtration outlet 113, so that the first or second filter media can be stably guided to the filtration outlet 113.

The induction partition wall 115 includes a fixed partition wall 1151 fixed to the inside of the buffer tank 110 so as to face the filtration inlet 112, and a rotatable structure at the lower end of the fixed partition wall 1151 via the partition axis 1153. It may include a rotating partition 1152 that is coupled. Then, as the first or second filter medium is accommodated in the buffer tank 110, the rotating partition wall 1152 rotates to expand the accommodation space in which the first or second filter medium is placed inside the buffer tank 110. , As the first or second filter medium is discharged from the buffer tank 110, the accommodation space is reduced to smoothly depressurize the internal pressure of the buffer tank 110, and the first filter medium is discharged from the inside of the buffer tank 110. Alternatively, scattering of the second filter medium can be minimized.

The suction ejector 120 includes a suction chamber 121 in communication with the inside of the buffer tank 110, and a suction diffuser 123 that communicates with the suction chamber 121 and depressurizes the suction chamber 121 as compressed air passes through. It may include a suction nozzle module 122 that sprays compressed air toward the suction diffuser 123 to depressurize the suction chamber 121.

The suction chamber 121 is provided with a suction connection part 1211 connected to the drive suction port 111 provided in the buffer tank 110, so that it can be easily coupled to the buffer tank 110.

The suction diffuser 123 includes a cone-shaped suction convergence cone portion 1231 that is coupled to the suction chamber 121 and whose inner diameter gradually decreases in response to the moving direction of the compressed air, and a suction convergence cone portion extending from the suction convergence cone portion 1231. A suction pressure portion 1232 having a diameter equal to or smaller than the minimum inner diameter of the cone portion 1231, and a suction pressure portion 1232 extending from the suction pressure portion 1232 and having an inner diameter gradually increasing from the suction pressure portion 1232 in response to the moving direction of the compressed air. A suction diffusion cone portion 1233 having an increasing cone shape may be included.

The suction nozzle module 122 is coupled to the suction nozzle body 1221 so as to face the suction nozzle body 1221 coupled to the other side of the suction chamber 121, and is compressed toward the suction diffuser 123. It may include a suction nozzle unit 1222 that sprays air, and a suction control unit 1223 that reciprocates the suction nozzle unit 1222 in the suction nozzle body 1221 in response to the moving direction of the compressed air. Here, the suction control unit 1223 can reciprocate the suction nozzle unit 1222 in the suction nozzle body 1221 through various known forms such as a screw method, a ball screw method, and a cylinder method.

The discharge ejector 130 has a discharge chamber 131 in communication with the inside of the buffer tank 110, and an discharge diffuser that communicates with one side of the discharge chamber 131 and depressurizes the discharge chamber 131 as compressed air passes through 133) and a suction nozzle module 122 that sprays compressed air toward the discharge diffuser 133 to depressurize the discharge chamber 131.

The discharge chamber 131 is provided with a discharge connection portion 1311 connected to the filtration discharge port 113 provided in the buffer tank 110, so that it can be easily combined with the buffer tank 110.

The discharge diffuser 133 includes a cone-shaped discharge convergence cone portion 1331 that is coupled to the discharge chamber 131 and whose inner diameter gradually decreases in response to the moving direction of the compressed air, and a discharge convergence cone portion 1331 extending from the discharge convergence cone portion 1331. A discharge pressure portion 1332 having a diameter equal to or smaller than the minimum inner diameter of the cone portion 1331, and extending from the discharge pressure portion 1332, the inner diameter gradually increases from the discharge pressure portion 1332 in response to the moving direction of the compressed air. A cone-shaped discharge diffusion cone portion 1333 that increases in size may be included.

The discharge nozzle module 132 is coupled to the discharge nozzle body 1321 so as to face the discharge chamber 131 and the discharge diffuser 133, and directs compressed air toward the discharge diffuser 133. It may include a discharge nozzle portion 1322 for spraying, and a cut portion 1323 of the discharge tank 440 that reciprocates the discharge nozzle portion 1322 in the discharge nozzle body 1321 in response to the moving direction of the compressed air. Here, the cut portion 1323 of the discharge tank 440 can reciprocate the discharge nozzle portion 1322 in the discharge nozzle body 1321 through various known forms such as a screw method, a ball screw method, and a cylinder method.

The discharge ejector 130 is coupled to the discharge diffuser 133 so as to surround the discharge diffuser 133, and has a connection chamber 134 that accommodates the fluid discharged from the suction ejector 120, and the fluid contained in the connection chamber 134. It may further include a communication hole 135 formed through the exhaust diffuser 133 to be supplied into the exhaust diffuser 133. Since the connection chamber 134 is connected to the suction diffuser 123 of the suction ejector 120 through the exhaust line (P4), the fluid discharged from the suction ejector 120 passes through the exhaust line (P4) to the connection chamber (134). ) is supplied to. The communication hole portion 135 is formed to be inclined toward the outlet of the discharge diffuser 133 in response to the direction of movement of the pressure air, thereby smoothing the movement of the first or second filter medium passing through the discharge diffuser 133 and discharge. It is possible to suppress or prevent the first or second filter medium from remaining in the diffuser 133.

The replacement unit may further include a replacement frame 110a that separates the buffer tank from the ground. The replacement frame 110a is coupled to the buffer tank.

The replacement unit may further include a replacement moving part 160 coupled to the collection frame 241 so that the replacement frame 110a can be moved on the ground. The replacement frame 110a connects the buffer tank and the replacement moving part 160. For example, the replacement movable unit 160 may include a replacement wheel rotatably coupled to the lower end of the replacement frame 110a to enable rolling movement on the ground. As another example, the replacement moving unit 160 may include a replacement cart to which the replacement frame 110a is coupled.

The collection unit 20 injects the pumped second filter medium into the collection bag 20a.

The collection unit 20 includes a collection tank 210 that accommodates the pumped second filter material, a discharge door module 230 that opens and closes the part where the second filter material is discharged from the collection tank 210, and a collection tank 210. It may include a collection support portion 240 that separates the from the ground.

The collection tank 210 may include a tank header 211 to which the discharge ejector 130 is connected, and a collection outlet 212 through which the second filter medium contained in the collection tank 210 is discharged.

The tank header 211 is provided on the upper surface of the collection tank 210 or the upper side of the collection tank 210 to ensure that the pumped second filter agent is stably delivered to the collection tank 210.

The collection outlet 212 is provided at the lower part of the collection tank 210 to facilitate the discharge of the second filter medium contained in the collection tank 210. The lower part of the collection tank 210 has a cone shape with an inner diameter that gradually becomes smaller and converges to the collection outlet 212, so that the second filter medium can be stably guided to the collection outlet 212.

The discharge door module 230 opens and closes the collection discharge port 212. The discharge door module 230 includes a discharge door portion 231 rotatably coupled to the collection discharge port 212 via the door shaft 232 to open and close the collection discharge port 212, and the door shaft 232. It may include a door driving unit 233 that pivots the discharge door unit 231 in the forward and reverse directions. In particular, it is advantageous for the door driving unit 233 to include a pneumatic cylinder operated by compressed air.

The collection support portion 240 may include a collection frame 241 coupled to the collection tank 210.

The collection support unit 240 may further include a collection moving unit 242 coupled to the collection frame 241 so that the collection frame 241 can move on the ground. For example, the collection moving unit 242 may include a collection wheel rotatably coupled to the lower end of the collection frame 241 to enable rolling movement on the ground. As another example, the collection moving unit 242 may include a collection truck to which the collection frame 241 is coupled.

The collection support portion 240 is coupled to the collection frame 241 and includes a collection rail 243 that forms a movement path for the collection bag 20a that can accommodate the second filter medium discharged from the collection tank 210, and a collection bag 20a. ) may further include a back holder 244 on which the bag is seated and slideably coupled to the collection rail 243.

The collection unit 20 may further include an opening/closing valve 220 that selects whether or not the second filter medium is delivered to the collection tank 210. In particular, it is advantageous for the on-off valve 220 to include a butterfly valve operated by compressed air.

The collection unit 20 includes a level sensor 260 that detects the receiving height of the second filter medium accommodated in the collection tank 210, and an opening/closing valve ( It may further include a collection control unit 250 that controls at least one of the opening and closing operation of the 220 and the opening and closing operation of the discharge door module 230.

The filter replacement device according to an embodiment of the present invention may further include a compressor 140 that supplies compressed air to at least one of the replacement unit 10 and the collection unit 20. Compressor 140 may take on a variety of known forms.

The filter material replacement device according to an embodiment of the present invention may further include a distribution header 150 that distributes compressed air. The distribution header 150 is connected to the compressor 140 via a pressure supply line.

First, the distribution header 150 is provided with a first pressure line (P1) connected to the suction ejector 120 and a second pressure line (P2) connected to the discharge ejector 130, so that the suction ejector 120 and the discharge Compressed air can be supplied to each ejector 130. The first pressure line (P1) is equipped with a first valve (V1) that selects whether to deliver the compressed air supplied to the suction ejector 120, and the second pressure line (P2) is provided with a first valve (V1) that selects whether to deliver the compressed air supplied to the suction ejector 120. A second valve (V2) that selects whether to deliver compressed air may be provided.

Second, the distribution header 150 is provided with a third pressure line (P3) connected to at least one of the discharge door module 230 and the opening/closing valve 220 of the collection unit 20 to connect the discharge door module 230 and the Compressed air can be supplied to at least one of the on-off valves 220. The third pressure line (P3) may be provided with a third valve (V3) that selects whether to deliver compressed air supplied to at least one of the discharge door module 230 and the opening/closing valve 220. The third pressure line (P3) is connected to the collection control unit 250, and compressed air can be supplied to at least one of the discharge door module 230 and the opening/closing valve 220 under the control of the collection control unit 250. .

Third, the distribution header 150 may be provided with a first pressure line (P1), a second pressure line (P2), and a third pressure line (P3).

The non-explained symbol R1 connects the filter material supply unit 30 and the filtration inlet 112 of the buffer tank 110 to form a supply path for the first filter material, or the filtration inlet 112 of the filtration unit 40 and the buffer tank 110. It is a replacement supply line (R1) that connects (112) to form a supply path for the second filter medium.

The unexplained symbol R2 connects the discharge ejector 130 and the filtration unit 40 to form an discharge path of the first filter medium, or connects the discharge ejector 130 and the filtration collection means to form an discharge path of the second filter medium. This is the replacement discharge line (R2).

The unexplained symbol R3 connects the filtration outlet 113 of the buffer tank 110 and the discharge connection 1311 of the discharge ejector 130 to form a movement path for the first or second filter medium contained in the buffer tank 110. This is the replacement connection line (R3).

The unexplained numeral 30 denotes a filter material supply unit 30 in which the first filter material is accommodated. The filter material supply unit 30 may be connected to the filtering inlet 112 provided in the buffer tank 110 of the replacement unit 10 via a replacement supply line (R1).

The unexplained reference numeral 50 is a sorting unit 50 that sorts and discharges the second filter media by size. The sorting unit 50 may be connected to the exhaust diffuser 133 provided in the exhaust ejector 130 of the replacement unit 10 via the replacement discharge line (R2).

From now on, the operation of the filter medium replacement device according to an embodiment of the present invention will be described.

First, the filter medium replacement device according to an embodiment of the present invention pumps the first filter medium and supplies it to the filtration unit 40. In more detail, as compressed air is supplied to the suction ejector 120 and the discharge ejector 130 according to the operation of the compressor 140, the inside of the buffer tank 110 is depressurized. At this time, the first filter medium accommodated in the filter medium supply unit 30 passes through the replacement supply line (R1) and the filter inlet 112 according to the operation of the suction ejector 120 and the discharge ejector 130, and then flows into the inside of the buffer tank 110. is accepted in The first filter medium accommodated in the buffer tank 110 is connected to the filtration outlet 113, the replacement connection line (R3), the discharge chamber 131, the discharge diffuser 133, and the replacement discharge line (R2) according to the operation of the discharge ejector 130. ), the first filter medium accommodated in the filter medium supply unit 30 can be supplied to the filtration unit 40.

Second, the filter medium replacement device according to an embodiment of the present invention pumps the second filter medium and supplies it to the filtration and collection means. In more detail, as compressed air is supplied to the suction ejector 120 and the discharge ejector 130 according to the operation of the compressor 140, the inside of the buffer tank 110 is depressurized. At this time, the second filter medium accommodated in the filtration unit 40 is inside the buffer tank 110 through the replacement supply line (R1) and the filtration inlet 112 according to the operation of the suction ejector 120 and the discharge ejector 130. It is accepted. The second filter medium accommodated in the buffer tank 110 is connected to the filtration outlet 113, the replacement connection line (R3), the discharge chamber 131, the discharge diffuser 133, and the replacement discharge line (R2) according to the operation of the discharge ejector 130. ), the second filter medium accommodated in the filtration unit 40 can be discharged to the filtration and collection means.

Third, the filter medium replacement device according to an embodiment of the present invention puts the pumped second filter medium into the collection bag (20a). In more detail, when compressed air is supplied to the collection control unit 250 according to the operation of the compressor 140, as the collection control unit 250 supplies compressed air to the opening and closing valve 220, the opening and closing valve 220 is connected to the tank header ( 211) and the replacement discharge line (R2) are opened, and the second filter medium is received in the collection tank 210 through the replacement discharge line (R2) and the tank header 211. In addition, when compressed air is supplied to the collection control unit 250 according to the operation of the compressor 140, the collection control unit 250 supplies compressed air to the discharge door module 230, and the discharge door module 230 opens the collection outlet. (212) is closed to block discharge of the second filter medium contained in the collection tank (210). When the level sensor 260 detects the second filter medium as the second filter medium is accommodated in the collection tank 210, it is determined that the second filter medium of the preset collection amount is accommodated in the collection tank 210, and the collection control unit 250 As ) supplies compressed air to the on-off valve 220, at least one of the tank header 211 and the replacement discharge line (R2) closes the on-off valve 220. In addition, when the level sensor 260 detects the second filter medium as the second filter medium is accommodated in the collection tank 210, it is determined that the second filter medium of the preset collection amount is accommodated in the collection tank 210, and the collection control unit As (250) supplies compressed air to the discharge door module 230, the discharge door module 230 opens the collection discharge port 212. Accordingly, the second filter medium contained in the collection tank 210 with a preset collection amount can be discharged into the bag.

In particular, the collection control unit 250 can inject a preset collection amount of the second filter medium into the collection tank 210 by controlling the operation of the opening and closing valve 220. In addition, with the opening/closing valve 220 closed, the collection control unit 250 operates the discharge door module 230 to open the collection outlet 212, thereby transferring a preset collection amount of the second filter material to the collection bag 20a. can be discharged to

When the second filter medium is accommodated in the collection bag (20a), the bag holder 244 slides along the collection rail 243, and the collection bag 20a is separated from the lower side of the collection tank 210 and moves to the bag holder 244. ) can be easily separated from the

According to the above-described filter material replacement device, the filter material can be pumped without damage using compressed air, and the amount of water used in the filtration unit 40 can be significantly reduced.

In addition, through the detailed connection relationship of the replacement unit 10, the first filter medium or the second filter medium can be easily sucked into the buffer tank 110 using compressed air, and the first filter medium or the second filter medium can be easily sucked into the buffer tank 110 using compressed air. The first filter medium can be easily discharged and delivered to the filtration unit 40, or the second filter medium contained in the buffer tank 110 can be easily discharged using compressed air and delivered to the collection unit 20, collection bag 20a, or separator. You can.

In addition, the first filter medium or second filter medium flowing into the filter inlet 112 is stably delivered to the filter outlet 113 through a detailed coupling relationship in the buffer tank 110, and the first filter medium or second filter medium is connected to the buffer tank. Scattering inside (110) can be suppressed.

In addition, the first filter medium or second filter medium flowing into the filtration inlet 112 is stably accommodated inside the buffer tank 110 through the detailed coupling relationship of the guide partition 115, and the It is possible to prevent the first filter medium or the second filter medium from flowing back.

In addition, the coupling relationship of the driving filter 114 can prevent the first or second filter media contained in the buffer tank 110 from being transmitted to the suction ejector 120 through the driving suction port 111.

In addition, through the coupling relationship of the suction ejector 120, the pressure of the suction chamber 121 and the buffer tank 110 can be clearly reduced, and the pressure of the air discharged from the suction diffuser 123 can be easily lowered. In addition, the Venturi effect can be clearly implemented through the detailed coupling relationship of the suction diffuser 123, making it possible to easily depressurize the suction chamber 121.

In addition, the injection position of the compressed air sprayed from the suction nozzle unit 1222 can be adjusted through the coupling relationship of the suction nozzle module 122, the decompression ability in the suction chamber 121 can be adjusted, and the type of filter material can be distinguished. Thus, it can be accommodated in the buffer tank 110.

In addition, through the coupling relationship of the discharge ejector 130, suction of the first or second filter medium contained in the buffer tank 110 can be clearly achieved and the pressure of the fluid discharged from the discharge diffuser 133 can be easily lowered. In addition, the venturi effect can be clearly implemented through the detailed coupling relationship of the discharge diffuser 133, making it easy to suction into the discharge chamber 131.

In addition, the injection position of the compressed air sprayed from the discharge nozzle unit 1322 can be adjusted through the coupling relationship of the discharge nozzle module 132, the decompression ability in the discharge chamber 131 can be adjusted, and the buffer tank 110 The discharge amount, discharge speed, or discharge pressure of the first or second filter media discharged from can be adjusted.

In addition, through the additional coupling relationship of the discharge ejector 130, the discharge speed of the first or second filter medium discharged through the discharge ejector 130 can be increased and the discharge of the first filter medium or second filter medium can be smoothed. there is.

In addition, the replacement unit 10 can be freely moved through the replacement moving unit 160.

In addition, the pumped second filter agent can be stably accommodated through the detailed connection relationship of the collection unit 20.

In addition, the collection bag 20a can be easily placed on the lower side of the collection tank 210 through the detailed coupling relationship of the collection support portion 240. Additionally, the collection tank 210 can be freely moved through the collection moving unit 242. In addition, the collection bag 20a can be moved smoothly through the collection rail 243 and the bag holder, and the collection bag 20a containing the second filter material can be easily removed from the lower side of the collection tank 210.

In addition, the collection outlet 212 can be easily opened and closed through the door driving part 233.

In addition, through the pneumatic cylinder, the collection outlet 212 can be easily opened and closed using only compressed air without any additional driving means.

In addition, the second filter medium delivered to the collection tank 210 can be adjusted through the additional configuration of the on-off valve 220.

In addition, the butterfly valve allows the opening/closing valve 220 to operate smoothly using only compressed air without any additional driving means.

In addition, the discharge timing of the second filter medium received can be adjusted through the additional coupling relationship of the collection unit 20. In addition, the collection control unit 250 controls the opening and closing valve 220 and the discharge door module 230 in conjunction with each other, so that the second filter medium can be accommodated in the collection tank 210 at a preset collection amount, and the collection tank ( The second filter medium contained in 210) can be easily discharged.

In addition, compressed air can be easily supplied to the unit without additional driving means. In addition, the suction ejector 120, the discharge ejector 130, and the collection unit 20 can be smoothly operated with one compressor 140 through the distribution header 150.

In addition, it can be used not only in water purification plants and wastewater treatment plants, but also in shipyards, oil tankers, and bulk unloading. Various work site improvements are possible through the stable supply of pneumatic devices without the need for engine-type suction devices or electric motor pumps with high load rates at high rpm. , indicates high efficiency.

In addition, high-specific gravity filter media and foreign substances from a distance can be efficiently vacuum transported, and damage to the filter media can be minimized or prevented by applying a valve operation method that suppresses or prevents pneumatic shock when the filter media is suctioned and discharged.

In addition, the inside of the buffer tank 110 can reach a maximum vacuum level of 8000 mmAq, which can be maintained for a long time, and the filter media and foreign substances in the filtration unit 40 can be treated quickly and reliably.

As described above, preferred embodiments of the present invention have been described with reference to the drawings, but those skilled in the art may vary the present invention without departing from the spirit and scope of the present invention as set forth in the following claims. It can be modified or changed.

10: Replacement unit 110: Buffer tank 110a: Replacement frame
111: driving inlet 112: filtration inlet 113: filtration outlet
114: Drive filter 115: Induction partition 1151: Fixed partition
1152: Rotating bulkhead 1153: Bulkhead shaft 120: Suction ejector
121: Suction chamber 1211: Suction connection 122: Suction nozzle module
1221: Suction nozzle body 1222: Suction nozzle part 1223: Suction control part
123: Suction diffuser 1231: Suction convergence cone part 1232: Suction pressure part
1233: Suction diffusion cone part 130: Discharge ejector 131: Discharge chamber
1311: Discharge connection 132: Discharge nozzle module 1321: Discharge nozzle body
1322: Discharge nozzle unit 1323: Discharge control unit 133: Discharge diffuser
1331: Discharge convergence cone part 1332: Discharge pressure part 1333: Discharge diffusion cone part
134: Connection chamber 135: Communication hole part 160: Replacement moving part
140: Compressor 150: Distribution header
20: collection unit 210: collection tank 211: tank header
212: Collection outlet 220: Open/close valve 230: Discharge door module
231: discharge door part 232: door axis 233: door driving part
240: Collection support unit 241: Collection frame 242: Collection moving unit
243: Collection rail 244: Back stand 250: Collection control unit
260: Level sensor
20a: collection bag
30: Filter material supply unit
40: filtration unit 410: filtration tank 411: filtration delivery unit
412: Strainer 413: First filtration material 414: Second filtration material
420: Input tank 421: Filtration input unit 430: Filtration buffer tank
440: discharge tank 441: filtration discharge unit 450: overflow partition wall
50: Sorting unit
R1: Replacement supply line R2: Replacement discharge line R3: Replacement connection line
V1: 1st valve V2: 2nd valve V3: 3rd valve
P1: 1st pressure line P2: 2nd pressure line P3: 3rd pressure line
P4: exhaust line

Claims (6)

A filter medium replacement device for supplying the first filter medium to be introduced into the filtration unit or collecting the second filter medium contained in the filtration unit,
The filter material replacement device,
a replacement unit that pumps the first filter medium or the second filter medium using compressed air; and
It includes a collection unit that injects the pumped second filter medium into a collection bag,
The collection unit is,
a collection tank that accommodates the second filter medium and has a collection outlet at the bottom through which the second filter medium is discharged; and
It includes a collection support part that separates the collection tank from the ground,
The collection support part,
A collection frame coupled to the collection tank; and
It includes a collection moving part coupled to the collection frame so that the collection frame can move on the ground,
The replacement unit is,
A buffer tank capable of accommodating the first or second filter media;
A suction ejector that depressurizes the buffer tank using compressed air;
a discharge ejector that discharges the first filter medium or the second filter medium accommodated in the buffer tank using compressed air;
a replacement frame that separates the buffer tank from the ground and is coupled to the buffer tank; and
It includes a replacement moving part coupled to the collection frame so that the replacement frame can move on the ground,
The suction ejector is,
a suction chamber communicating with the interior of the buffer tank;
A suction diffuser that communicates with the suction chamber and depressurizes the suction chamber as compressed air passes through it; and
It includes a suction nozzle module that sprays compressed air toward the suction diffuser to depressurize the suction chamber,
The discharge ejector,
a discharge chamber communicating with the interior of the buffer tank;
An exhaust diffuser that communicates with one side of the exhaust chamber and depressurizes the exhaust chamber as compressed air passes through it;
A discharge nozzle module that sprays compressed air toward the discharge diffuser to depressurize the discharge chamber;
A connection chamber coupled to the exhaust diffuser to surround the exhaust diffuser and receiving pressure air discharged from the suction diffuser; and
It includes a communication hole formed through the discharge diffuser so that the fluid contained in the connection chamber is supplied to the interior of the discharge diffuser,
The communication hole part,
It is connected to the suction diffuser and supplies fluid discharged from the suction ejector to the connection chamber,
A filter material replacement device that is inclined toward the outlet in response to the direction of movement of the pressure air in the connection chamber.
According to paragraph 1,
In the buffer tank,
a driving inlet to which the suction ejector is coupled;
a filtration inlet through which the first filter medium or the second filter medium flows as the buffer tank is depressurized;
a filter outlet through which the first filter medium or the second filter medium is discharged according to the operation of the discharge ejector; and
A filter material comprising: a guide partition provided inside the buffer tank to face the filter inlet and guiding the first filter medium or the second filter medium flowing in through the filter inlet to the filtration outlet; replacement device.
delete delete According to paragraph 1,
The discharge nozzle module is,
A discharge nozzle body coupled to the discharge chamber;
a discharge nozzle unit coupled to the discharge nozzle body to face the discharge diffuser and spraying compressed air toward the discharge diffuser; and
A discharge control unit that reciprocates the discharge nozzle portion in the discharge nozzle body in response to the direction of movement of compressed air.
According to paragraph 1,
The collection unit is a filter medium replacement device, characterized in that it further includes a discharge door module that opens and closes the collection discharge port.

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