KR101250985B1 - Booster pump - Google Patents

Abstract

PURPOSE: A booster pump is provided to extend the service life of a check valve and to reduce maintenance costs according to electricity consumption by preventing the frequent operation of a booster pump. CONSTITUTION: A booster pump comprises a suction header(210), a discharge header(310), and a pump unit(100). The suction header is connected to a suction pipe(200) and flows fluid to the inside thereof. The discharge header discharges the fluid to a discharge pipe(330). The pump unit connects a space between the suction header and discharge header and discharges the fluid by increasing the pressure of the fluid.

Description

Booster pump

The present invention relates to a booster pump for discharging by increasing the pressure of a fluid.

In general, the booster pump is a pump for increasing the pressure of a low fluid and is used to supply water from a water pipe buried in the basement of a building to a water tank located at the top of the building, or to supply water stored in a reservoir to each floor. It is widely used in water supply equipment.

The conventional booster pump includes a reservoir for storing water, as disclosed in Korean Patent Laid-Open Publication No. 10-2009-0040002; A booster pump which pressurizes and transfers water stored in the water storage tank, and a plurality of pumps are connected in parallel to each other; The booster pump includes a main water supply pipe and a low / high floor pipe.

Conventional booster pumps have a configuration such that the booster pumps connected in parallel are operated alternately according to hydraulic pressure or a plurality of booster pumps are operated together to increase the pressure of the fluid in the main water supply pipe from the booster pump so that the low / high rise piping is used. (Hereinafter referred to as discharge pipe).

At this time, a check valve is installed between the booster pump and the discharge pipe to prevent the fluid from flowing back from the discharge pipe to the booster pump.

However, the conventional booster pump has a problem that the check valve is damaged by the discharged fluid because the pressure of the fluid discharged from the booster pump is high.

In addition, since apparently the check valve is not easy to detect the damage, the pressure of the discharge pipe is easily lowered due to the breakage of the check valve, so that the booster pump is frequently started, which increases the maintenance cost according to the electricity consumption. There was a problem that the life of the booster pump is shortened.

In addition, the main water supply pipe is provided with a strainer for filtering foreign matter, if the strainer is full of foreign matter, it is difficult to understand because the booster pump is started in the state that the fluid is not supplied to the main water supply pipe to break the booster pump There was a problem.

In addition, there is a problem in that the discharge pipe is damaged by the pressure of the fluid discharged at the start of the booster pump to damage the discharge pipe.

The present invention has been made to solve the problems described above, the problem to be solved by the present invention is to easily check the damage of the check valve to prevent frequent start-up of the booster pump, reducing the maintenance cost according to electricity consumption It is to provide a booster pump that can extend the life, extend the life, and prevent damage to the check valve.

In addition, it is possible to provide a booster pump that not only prevents damage to the booster pump by excessive force in the absence of fluid by grasping the state of the strainer, but also prevents the discharge pipe from being damaged due to the impact of the discharged fluid. .

Booster pump according to an embodiment of the present invention for achieving the above object is connected to the suction pipe is supplied with the fluid inlet header, the fluid supplied from the suction pipe, the discharge pipe is discharged the fluid introduced into the suction header is connected A booster pump comprising a discharge header being connected between the suction header and the discharge header to increase the pressure of the fluid supplied from the suction header and discharge the discharge header to the discharge header, wherein the pump portion is provided at the suction header. A driving pump for sucking and discharging fluid into the discharge header, a suction gate valve disposed between the driving pump and the suction header to supply or block a fluid flowing from the suction header to the driving pump, the driving pump and the Located between the discharge header to drain the fluid discharged from the drive pump to the discharge header A discharge gate valve for discharging or blocking, a check valve positioned between the driving pump and the discharge header to prevent a backflow of fluid discharged from the driving pump to the discharge header, and between the check valve and the driving pump And a leakage check unit having a blocking plate positioned to reduce an initial pressure of the fluid discharged from the driving pump to the check valve.

The leak check unit is formed with a flow path through which the fluid flows, the blocking plate is rotatably installed in the flow path to open or close the flow path by the pressure of the fluid passing through the flow path to discharge the air in the flow path to the outside. And a main body having an air discharge port, a drain hole for discharging the fluid in the flow path to the outside, and a fixing mechanism provided in the main body to fix or release the blocking plate in a state where the flow path is sealed. Can be.

The fixing mechanism is formed with a fastening hole penetrated through the main body, a handle having a screw rod screwed to the fastening hole and moved up and down by screwing, and coupled to the screw rod, the upper portion of the blocking plate It may include a fixing jig is formed is a plate insertion groove is inserted.

The lower portion of the blocking plate may include a weight portion for increasing the weight so that the blocking plate is rotated by its own weight in the direction of closing the flow path.

The air outlet may include an air outlet valve for opening or closing the air outlet.

The drain hole may include a drain valve for opening or closing the drain hole.

The discharge header may include a flexible joint that is provided at a portion to which the discharge pipe is connected, and is flexibly flexed to prevent the impact of the fluid generated by the operation of the driving pump from being transferred to the discharge pipe.

The suction header is a strainer installed at a portion connected to the suction pipe to filter foreign substances, a first pressure sensor installed at a portion where the fluid of the strainer is sucked, a second pressure sensor installed at a portion where the fluid of the strainer is discharged And a control module for stopping the operation of the driving pump when a pressure difference arbitrarily set by comparing the pressures of the first pressure sensor and the second pressure sensor occurs.

The strainer may be a Y-type strainer that is installed in the inclined direction of the filtering network for filtering foreign matter in the path through which the fluid passes.

The pump unit may be provided in plural in parallel between the suction header and the discharge header.

According to the present invention, it is possible to prevent the breakage of the check valve by reducing the impact of the fluid discharged is installed leak check unit.

In addition, the leak check unit to easily detect the failure of the check valve to prevent frequent start-up of the booster pump due to the failure of the check valve, it is possible to reduce the cost of electricity consumption, and to extend the life of the booster pump.

In addition, the discharge pipe is coupled by the flexible joint portion, it is possible to prevent the damage to the discharge pipe due to the impact of the fluid.

In addition, a first pressure sensor and a second pressure sensor are installed at the front and rear of the strainer to easily detect the state of the strainer, thereby preventing damage to the booster pump due to the start of the booster pump in the absence of fluid in the suction header. Can be.

1 is a configuration diagram schematically showing a configuration of a booster pump according to an embodiment of the present invention.
2 is a side view illustrating a pump unit of a booster pump according to an embodiment of the present invention.
3 is a cross-sectional view taken along line AA of FIG. 2 and is a front sectional view of the leak check unit.
4 is a cross-sectional view taken along the line BB of FIG.
5 is a cross-sectional view schematically showing a flexible joint part constituting a booster pump according to an embodiment of the present invention.
6 is a cross-sectional view schematically showing a strainer constituting a booster pump according to an embodiment of the present invention.

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

As shown in Figure 1 and 2, the booster pump according to an embodiment of the present invention may include a suction header (210). The suction header 210 is formed in the shape of a tube, one side is sealed and the other side can be configured in an open form, the other side is connected to the suction pipe 200 is supplied from the suction pipe 200 is supplied with a fluid Fluid may be supplied into the suction header 210.

Meanwhile, as shown in FIGS. 1 and 6, the suction header 210 may include a strainer 220. The strainer 220 may be installed at a portion in which the suction pipe 200 is connected to the suction header 210 to filter foreign matter contained in the fluid supplied from the suction pipe 200 to the suction header 210.

At this time, the strainer 220 may be implemented as a Y-type strainer in the form of the filter net 250 is installed in the inclined direction in the path through which the fluid is filtered through the filter net 250.

Here, the Y-type strainer can filter out foreign substances by minimizing the resistance of the fluid, and since the filter net 250 is installed in an inclined direction in the path through which the fluid passes, it is possible to easily remove the foreign substances caught in the filter net (FIG. 6). Reference).

In addition, the suction header 210 may include a first pressure sensor 221 and a second pressure sensor 222. The first pressure sensor 221 and the second pressure sensor 222 may measure the pressure of the fluid.

On the other hand, the first pressure sensor 221 is installed on the strainer 220, more specifically, the inlet pipe 200 in the fluid flowing into the strainer 220 to measure the pressure of the fluid flowing into the strainer 220 The second pressure sensor 222 may be installed at a portion where the fluid is discharged to the suction header 210 through the strainer 220, more specifically, the strainer 220, and the pressure of the fluid discharged from the strainer 220. Can be measured.

In addition, the suction header 210 may further include a control module (not shown). The control module compares the pressures measured by the first pressure sensor 221 and the second pressure sensor 222, and when the arbitrarily set pressure difference occurs, the driving pump 110 to stop the operation of the driving pump 110 to be described below. ) Can be controlled.

For example, the control module may be configured to stop the operation of the driving pump 110 when a difference between the pressures measured by the first pressure sensor 221 and the second pressure sensor 222 occurs 10 kg / cm ² .

As such, when the pressure measured by the first pressure sensor 221 and the second pressure sensor 222 is a predetermined pressure difference, the control module may determine that the strainer 220 is full of foreign matter, so that the suction header In the low water level state of 210, it is possible to prevent damage to the booster pump due to excessive starting of the driving pump 110.

In this case, the first pressure sensor 221 and the second pressure sensor 222 may be configured to include a diagram and a gauge, respectively. The diagram can be deformed by the pressure of the fluid, and the gauges are combined to maintain the shape of the diagram, indicating the varying length of the gauge that changes with the deformation of the diagram as a change in resistance with current using a Wheatstone bridge circuit. It can be configured to measure the pressure in the form.

Here, the first pressure sensor 221 and the second pressure sensor 222 may be configured as a pressure sensor that can measure the pressure of a variety of known types of fluid.

On the other hand, the suction header 210 may include a suction pressure sensor 230. The suction pressure sensor 230 detects the pressure of the fluid supplied from the suction pipe 200 to the suction header 210 and when the pressure is greater than or equal to a predetermined pressure, the driving pump 110 is operated, and if the pressure is less than or equal to the predetermined pressure, the driving pump. It may be configured to stop the operation of 110.

That is, when there is no fluid in the suction header 210, the suction pressure sensor 230 may prevent the driving pump 110 from being damaged due to excessive starting of the driving pump 110.

Booster pump according to an embodiment of the present invention may include a discharge header (310). The discharge header 310 may receive the fluid supplied to the suction header 210 and discharge it to the discharge pipe 300.

On the other hand, the discharge header 310 is formed in a tubular shape, one side is closed, the other side may be configured in an open form, the other side of the open discharge pipe 300 for discharging the fluid supplied to the discharge header 310 This can be combined.

At this time, the discharge header 310 may be arranged side by side spaced apart from the suction header 210 at a predetermined interval.

On the other hand, the discharge header 310 may include a flexible joint 320. The flexible joint 320 connects the discharge header 310 and the discharge pipe 300 to each other so that the pressure of the fluid is transmitted to the discharge pipe 300 during the operation of starting or stopping the driving pump 110 to be described below. The portion at which the discharge header 310 and the discharge pipe 300 are connected may be prevented from being damaged.

At this time, the flexible joint 320 is a corrugated pipe that can be flexibly curved, one end is coupled to the open portion of the discharge header 310, the other end may be configured to be coupled to the discharge pipe (300). .

In addition, the discharge header 310 may be provided with a water level sensor 330. The level sensor 330 may control the driving pump 110 to be described below by measuring the pressure of the fluid discharged from the discharge header 310 to the discharge pipe 300 by the level difference.

For example, when the water level sensor 330 is insufficient water in the discharge header 310, the drive pump 110 to supply a fluid to the discharge pipe 300, when the discharge header 310 is full of water, It may be configured to stop the operation of the drive pump 110.

Here, the level sensor 330 provided in the discharge header 310 and the suction pressure sensor 230 provided in the suction header 210 may be configured to replace each other.

As shown in Figure 1 and 2, the booster pump according to an embodiment of the present invention may include a pump unit (100). The pump unit 100 may connect between the suction header 210 and the discharge header 310 to increase the pressure of the fluid supplied from the suction header 210 and discharge the discharge header 310.

On the other hand, the pump unit 100 may include a driving pump (110). The driving pump 110 may rotate the impeller by a motor to discharge the fluid of the suction header 210 by increasing the pressure of the fluid to the discharge header 310 by the impeller.

Here, the drive pump 110 may be implemented as a known inverter pump for adjusting the rotational speed of the impeller according to the flow rate of the fluid or a known direct-drive pump for rotating the impeller at a constant speed irrespective of the flow rate of the fluid. Since the driving pump 110 is a known technique, further detailed description thereof will be omitted.

The pump unit 100 may include a suction gate valve 120. The suction gate valve 120 may be installed between the suction header 210 and the driving pump 110 to supply or block the fluid supplied from the suction header 210 to the driving pump 110.

On the other hand, the suction gate valve 120 may shut off the fluid supplied from the suction header 210 to the driving pump 110 by locking the suction gate valve 120 when a failure occurs in the pump unit 100.

The pump unit 100 may include a discharge gate valve 130. The discharge gate valve 130 may be installed between the driving pump 110 and the discharge header 310 to supply or block the fluid discharged from the driving pump 110 to the discharge header 310.

On the other hand, the discharge gate valve 130, when a failure occurs in the pump unit 100, by closing the discharge gate valve 130 may block the flow of fluid from the discharge header 310 to the drive pump 110.

The pump unit 100 may include a check valve 140. The check valve 140 is installed between the driving pump 110 and the discharge gate valve 130 so that the fluid discharged from the driving pump 110 toward the discharge gate valve 130, that is, toward the discharge header 310 is driven again. The pump 110 can be prevented from flowing back in the direction in which it is located.

3 and 4, the pump unit 100 may include a leak check unit 150. The leak check unit 150 can easily determine the failure of the check valve 140, the failure of the check valve 140 due to the pressure of the fluid discharged from the drive pump 110 to the check valve 140 It can be prevented from occurring.

The leak checking unit 150 may include a main body 151. The main body 151 may have a flow path 151a through which fluid discharged from the driving pump 110 to the check valve 140 passes through the main body 151, and the main body 151 may include the driving pump 110 and the check valve. 140 may be coupled in a form that is screwed together.

In addition, an air discharge port 154 communicating with the flow path 151a may be formed at an upper portion of the main body 151 so that the air of the flow path 151a is discharged to the outside, and a flow path 151a at the lower portion of the main body 151. Drain hole 153 may be formed in communication with the flow path (151a) so that the fluid of the) can be discharged to the outside.

In this case, an air discharge valve 154a may be installed at the air outlet 154 to open or close the air outlet 154, and the drain hole 153 may be opened or closed. The drain valve 153a may be installed.

In addition, the air discharge port 154 and the drain hole 153 may be configured to be connected to the flow path 151a of the portion where the discharge header 310 is positioned around the blocking plate 152 to be described below.

In addition, the leakage checking unit 150 may include a blocking plate 152. The blocking plate 152 may open or close the flow path 151a, and the fluid passing through the flow path 151a may impact to reduce the initial pressure of the fluid supplied from the drive pump 110 to the check valve 140. Can be.

That is, since the blocking plate 152 is in a state in which the flow path 151a is closed, the fluid discharged from the driving pump 110 impacts the blocking plate 110 and before the blocking plate 110 opens the flow path 151a. The pressure of the fluid, that is, the driving pump 110 may be driven to reduce the pressure of the fluid discharged initially.

On the other hand, the blocking plate 152 may be formed in a disk shape that can block the flow path (151a), the blocking plate 152 is rotated about the horizontal axis in the central portion of the flow path (151a) of the main body 151 It can be installed to be possible.

In addition, the blocking plate 152 may be provided with a weight part 152a. The weight portion 152a is a portion that is relatively heavier than other portions of the portion of the blocking plate 152 and is provided at the lower portion of the blocking plate 152 so that the blocking plate 152 is always self-weighted. The blocking plate 152 may be positioned to close the flow path 151a, that is, to be positioned perpendicular to the flow path 151a.

In this case, the weight part 152a may be configured in a form in which a weight body is installed in the lower part of the blocking plate 152 or the thickness of the lower part of the blocking plate 152 becomes thick.

The leak checking unit 150 may include a fixing mechanism 155. The fixing mechanism 155 can fix the opening and closing plate 152 in a state where the flow path 151a is closed. Meanwhile, the fixing mechanism 155 may include a handle 156 and a fixing jig 157.

On the other hand, the handle 156 may be provided with a screw rod 158, the thread is formed on the outer surface at the bottom. In addition, a fastening hole penetrating the flow path 151a is formed in the main body 151 at an upper portion of the main body 151, and a thread is formed on an inner circumferential surface of the fastening hole so that the screw rod 158 of the handle 156 is formed. The screw rod 158 can be moved upward or downward in the fastening hole according to the rotation direction when the handle 156 is rotated by being coupled to the fastening hole.

In addition, the fixing jig 157 is coupled to the end of the screw rod 158 penetrating the handle 156, more specifically the main body 151, the screw rod 158 according to the rotation direction when the handle 156 is rotated In addition, the fixing jig 157 may be configured to move upward or downward.

On the other hand, the fixing jig 157 may be formed with a plate inserting groove 157a into which the upper end portion of the blocking plate 152 may be fitted, and the plate inserting groove 157a may be formed to be widened downward. Can be.

In this case, the fixing jig 157 may be detached from the blocking plate 152 when the blocking plate 152 is rotated so as not to disturb the rotation of the blocking plate 152 by the fixing jig 157 positioned in the flow path 151a. The jig release groove 152b may be formed, and the fixing jig 157 may fix the blocking plate 152 in a form in which the plate insertion groove 157a is fitted to the top of the jig release groove 152b. .

 When the fixing mechanism 155 configured as described above rotates the handle 156, the fixing jig 157 positioned at the upper portion of the blocking plate 152 by the screw rod 158 is screwed with the fastening hole to block the blocking plate 152. ), The fixing mechanism 155 may fix the blocking plate 152 in a form in which the upper end portion of the blocking plate 152 is inserted into the plate insertion groove 157a of the fixing jig 157. .

On the contrary, when the handle 156 rotates in the opposite direction to fix the blocking plate 152, the fixing jig 157 moves upward by the screwing of the screw rod 158 and the fastening hole, and the fixing jig moves upward. As the blocking plate 152 is separated from the plate insertion groove 157a of the 157, the fixing of the blocking plate 152 may be released.

In addition, in the booster pump according to the embodiment of the present invention, a plurality of pump units 100 are installed in parallel between the suction header 210 and the discharge header 310 positioned side by side, and the pump unit 100 installed in parallel. The driving pump 110 may be alternately driven or the fluid of the suction header 210 to the discharge header 310 in the form of driving together.

The operation and effect between the above-described respective constitutions will be described.

In the booster pump according to the embodiment of the present invention, the suction header 210 is coupled to the suction pipe 200 to which the fluid is supplied, and the discharge header 310 is provided in parallel with the suction header 210, and the discharge header 310 is provided. Is coupled to the discharge pipe 300 for discharging the fluid supplied to the suction header 210.

At this time, the discharge header 310 and the discharge pipe 300 is connected to the flexible flexible joint 320, the strainer 220 and strainer 220 for filtering foreign matter between the suction pipe 200 and the suction header 210. The first pressure sensor 221 and the second pressure sensor 222 are installed on both sides of the) to measure the pressure of the fluid before passing the strainer 220 and the pressure of the fluid after passing the strainer 220.

Here, a plurality of pump units 100 may be provided in parallel between the suction header 210 and the discharge header 310.

In addition, the pump unit 100 has a driving pump 110 positioned between the discharge header 310 and the suction header 210, and the suction gate valve 120 between the suction header 210 and the pump unit 100. ) Is provided, and the discharge gate valve 130 is provided between the driving pump 110 and the discharge header 310.

In addition, a check valve 140 is installed between the driving pump 110 and the discharge gate valve 130 to prevent a back flow of the fluid, and a check valve 140 between the check valve 140 and the driving pump 110. The leakage check unit 150 is installed to determine the failure of the or to reduce the pressure applied to the check valve 140.

At this time, the leakage check unit 150 is installed so that the blocking plate 152 for opening or closing the flow path 151a is rotatable about a horizontal axis in the center of the blocking plate 152, and the leakage checking unit 150 The blocking plate 152 is further provided with a fixing mechanism 155 that can be fixed in a closed state of the flow path (151a).

In the booster pump having the above-described configuration, when the pressure of the fluid discharged to the discharge pipe 300 is required to be higher than a predetermined pressure, the driving pump 110 of the pump unit 100 is operated to suck the header from the suction pipe 200. The pressure of the fluid supplied to the 210 is discharged by increasing the pressure of the fluid to the discharge pipe 300 connected to the discharge header 310 through the pump unit (100).

At this time, before the fluid is discharged to the check valve 140 at a high pressure due to the start of the driving pump 110, the blocking plate 152 of the leakage check unit 150 is impacted by reducing the impact force to the pressure of the fluid. By opening the blocking plate 152 is discharged to the check valve 140, it is discharged to the discharge pipe 300 through the discharge header 310.

Here, the blocking plate 152 is located in a state in which the flow path 151a is closed by its own weight, so that the fluid located between the driving pump 110 and the blocking plate 152 even when the driving pump 110 is stopped. Can be prevented from being easily discharged in the direction in which the check valve 140 is located.

That is, since the driving pump 110 is operated when it is determined that the flow rate discharged to the discharge header 310 is small, the fluid between the check valve 140 and the blocking plate 152 is immediately discharged by the blocking plate 152. By gradually discharging, the electric power consumption due to frequent starting of the driving pump 110 can be minimized, and the life of the driving pump 110 can be extended.

In addition, the shock of the fluid due to the operation of the drive pump 110 may be absorbed by the flexible joint 320 to prevent breakage of the discharge pipe 300 due to the impact of the fluid.

In addition, when the driving pump 110 is started, the fluid supplied from the suction pipe 200 to the suction header 210 is filtered out by the strainer 220, and the first pressure sensor 221 and the second pressure sensor ( The pressure before the 222 is introduced into the strainer 220 and the pressure after passing through the strainer 220 are measured and determined by the control module, and if an abnormal pressure difference occurs, the start of the driving pump 110 is stopped.

When the abnormality of the check valve 140 is determined, the suction gate valve 120 is locked while the driving pump 110 is stopped to shut off the fluid supplied from the suction header 210 to the pump unit 100. .

Then, the handle 156 of the fixing mechanism 155 is turned to fix the blocking plate 152 to the fixing jig 157 in a state where the flow path 151a is blocked.

In this state, the drain valve 153a is opened to discharge the fluid located between the leak check unit 150, more specifically, the blocking plate 152 and the check valve 140 from the drain hole 153 to the outside. .

In this case, when the fluid continuously flows out of the drain hole 153, the check valve 140 may be leaked, that is, the failure of the check valve 140 may be determined, so that the discharge gate valve 130 is locked to the check valve 140. ) Or perform repairs.

If the fluid is no longer discharged from the drain hole 153, the check valve 140 is determined to be normal, and the air drain valve 154a is closed after closing the drain valve 153a to seal the drain hole 153. ) To open the air outlet (154).

Then, the suction gate valve 120 is opened, and the driving pump 110 is operated to check the gap between the check valve 140 and the leak check unit 150, more specifically, the check valve 140 and the blocking plate 152. By supplying a fluid to the space between the, the air located between the check valve 140 and the blocking plate 152 is discharged to the outside through the air outlet 154.

At this time, when the fluid supplied from the driving pump 110 is discharged to the outside through the air outlet 154, the air outlet 154 is closed by the air discharge valve 154a.

In this case, when the air of the check valve 140 and the blocking plate 152 is not discharged to the outside, air is introduced into the discharge header 310 and the discharge pipe 300, and when the booster driving pump 110 is started, Since the impact is generated, by removing the air located between the check valve 140 and the blocking plate 152 in advance, it is possible to reduce the noise and impact when the booster pump is started.

Therefore, the booster pump according to the embodiment of the present invention may be installed with a leak check unit 150 to minimize the consumption of electricity due to frequent startup of the booster pump to reduce the maintenance cost, it is possible to extend the life of the pump. .

In addition, the leakage check unit 150 may block the shock of the fluid applied to the check valve 140 when the booster pump is started, thereby preventing damage to the check valve 140, and also causing a failure of the check valve 140. Can be easily identified and repaired.

In addition, the discharge pipe 300 may be connected to the flexible joint 320 to prevent the discharge pipe 300 from being damaged due to an impact caused by the start of the booster pump.

In addition, the strainer 220 is provided to prevent the failure of the booster pump due to the foreign matter, the first pressure sensor 221 and the second pressure sensor 222 is provided to remove the foreign matter caught by the strainer 220 It can be easily grasped, it is possible to prevent the breakage of the drive pump 110 generated by driving the drive pump 110 in a state in which the suction header 210 is low water, that is no fluid.

Although the embodiments of the present invention have been described above, the scope of the present invention is not limited thereto, and the present invention is easily changed and equivalent to those of ordinary skill in the art to which the present invention pertains. Includes all changes and modifications to the scope of the matter.

100: pump 110: drive pump
120: suction gate valve 130: discharge gate valve
140: check valve 150: leak check unit
151: main body 151a: euro
152: blocking plate 152a: parts by weight
152b: Jig release groove 153: Drain hole
153a: drain valve 154: air outlet
154a: air discharge valve 155: fixing mechanism
156: handle 157: fixing jig
157a: plate insertion groove 158: screw rod
200: suction pipe 210: suction header
220: strainer 221: first pressure sensor
222: second pressure sensor 230: suction pressure sensor
250: filter network 300: discharge pipe
310: discharge header 320: flexible joint portion
330: water level sensor

Claims (10)

A suction header to which a fluid supplied from the suction pipe is connected to the suction pipe to which the fluid is supplied, a discharge header to which a discharge pipe to which the fluid introduced into the suction header is discharged is connected, and connected between the suction header and the discharge header to In the booster pump comprising a pump unit for increasing the pressure of the fluid supplied from the suction header to discharge to the discharge header,
The pump unit
A driving pump for sucking and discharging fluid from the suction header to the discharge header;
A suction gate valve positioned between the driving pump and the suction header to supply or block a fluid flowing from the suction header to the driving pump;
A discharge gate valve disposed between the driving pump and the discharge header to discharge or block the fluid discharged from the driving pump to the discharge header;
A check valve positioned between the drive pump and the discharge header to prevent backflow of fluid discharged from the drive pump to the discharge header;
It is located between the check valve and the drive pump includes a leak check unit having a blocking plate for reducing the initial pressure of the fluid discharged from the drive pump to the check valve,
The discharge header is
And a flexible joint part provided at a portion to which the discharge pipe is connected to be flexible to prevent the impact of the fluid generated by the operation of the driving pump from being transferred to the discharge pipe. The method according to claim 1,
The leak check unit is
A flow path through which the fluid passes, and the blocking plate is rotatably installed in the flow path to open or close the flow path by the pressure of the fluid passing through the flow path, and to discharge the air of the flow path to the outside; A main body having a drain hole for discharging the fluid in the flow path to the outside;
And a fixing mechanism provided in the main body to fix or release the blocking plate in a state in which the flow path is sealed. The method of claim 2,
The fixing mechanism
A handle having a fastening hole formed in the main body and screwed to the fastening hole, the handle having a screw rod moving up and down by screwing, and
Booster pump characterized in that it comprises a fixing jig formed in the plate insertion groove is coupled to the screw rod is inserted into the upper end of the blocking plate. The method of claim 2,
The lower part of the blocking plate
And a weight part for increasing the weight so that the blocking plate is rotated and positioned by its own weight in the direction of closing the flow path. The method of claim 2,
The air outlet is
Booster pump, characterized in that it comprises an air discharge valve for opening or closing the air outlet. The method of claim 2,
The drain hole
Booster pump, characterized in that it comprises a drain valve for opening or closing the drain hole. delete The method according to claim 1,
The suction header is
A strainer installed at a portion connected to the suction pipe to filter foreign substances;
A first pressure sensor installed at a portion at which the fluid of the strainer is sucked;
A second pressure sensor installed at a portion at which the fluid of the strainer is discharged;
And a control module for stopping the operation of the driving pump when a pressure differential arbitrarily set by comparing the pressures of the first pressure sensor and the second pressure sensor. The method of claim 8,
The strainer is
A booster pump, characterized in that the Y-type strainer is installed in the inclined direction of the filtering network to filter foreign matter in the path through which the fluid passes. The method according to claim 1,
The pump unit
Booster pump, characterized in that provided in plurality between the suction header and the discharge header in parallel.

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