KR101340886B1 - Spacer flange for tightening the booster system - Google Patents

Abstract

The present invention relates to a spacer flange for fastening a booster system, wherein the spacer flange is capable of reducing the area of a booster pump. The spacer flange for fastening the booster system is for coupling the booster pump and a pressure control valve in the booster system comprising: a suction header fed with fluid; a discharge header from which the fluid fed into the suction header is discharged; the booster pumps positioned between the suction header and the discharge header, and discharging fluid to the discharge header after increasing the pressure of the fluid in the suction header; and the pressure control valves installed either or both between the booster pumps and the suction header, and between the booster pumps and the discharge header. The spacer flange comprises: a plate-shaped flange part positioned between the pump flange of the booster pump and the pressure control valve; and a fastening part formed at the flange part, and to which a first bolt and a second bolt are fastened respectively or along with each other, wherein the first bolt is coupled at the side of the pump flange and the second bolt is coupled at the side of the pressure control valve. Therefore, present invention allows a short pipe to be replaced with the flange part, thereby reducing manufacturing costs with a relatively simple structure, shortening working hours due to manufacturing the short pipe, and reducing the area occupied by the booster pump.

Description

Spacer flange for tightening booster system {Spacer flange for tightening the booster system}

The present invention relates to a booster system for supplying increased pressure to a water supply line of a building.

In general, the booster system is a water supply facility of a building, and a plurality of booster pumps are installed in the middle of a fluid circulation system to increase the lost pressure and automatically operate in conjunction with a load.

The conventional booster pump is connected to a suction pipe to which a fluid is supplied as disclosed in "Booster Pump" of Korean Patent Registration No. 10-1250985 (registered on March 29, 2013), and a suction header into which the fluid supplied from the suction pipe flows, the suction header A booster pump including a discharge header connected to a discharge pipe through which the fluid introduced into the discharge pipe is connected, and a pump unit 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. The pump unit may include a driving pump for sucking and discharging fluid from the suction header to the discharge header, and positioned between the driving pump and the suction header to supply or shut off the fluid flowing into the driving pump from the suction header. Intake gate valve, located between the drive pump and the discharge header is discharged from the drive pump A discharge valve for discharging or blocking the discharged fluid to a discharge valve, a check valve positioned between the driving pump and the discharge header to prevent a backflow of the fluid discharged from the driving pump to the discharge header, and the check valve and the It is located between the drive pump includes a leakage check unit is provided with a blocking plate for reducing the initial pressure of the fluid discharged from the drive pump to the check valve, the discharge header is provided in the portion that the discharge pipe is connected to the drive It is configured to include a flexible joint bent flexibly to prevent the impact of the fluid generated by the operation of the pump to the discharge pipe.

The booster pump of this configuration can reduce the impact of the fluid by the leak check unit to prevent damage to the check valve, extend the life of the booster pump, and the discharge pipe is coupled by the flexible joint part to prevent the impact of the fluid. Could absorb.

However, in the conventional booster pump, since a single pipe is installed between the flow control valve and the check valve, when the booster pump fails, the booster pump can be repaired only by removing the check valve from the single pipe. If there is no single pipe, the booster pump can be repaired by stopping the system and then separating the flow control valve and check valve.

As a result, it takes a long time for the repair of the booster pump, and the space for installing the booster pump was wasted due to the length occupied by the short pipe.

In addition, the single pipe has a problem in that the production cost is increased because the flanges to which the flow control valve and the check valve are coupled to each side, and the resistance of the fluid is increased due to the length of the short pipe, thereby reducing the efficiency of the booster pump.

The present invention is to solve the problems as described above, the problem to be solved by the present invention is to minimize the installation space of the booster system, to reduce the manufacturing cost with a relatively simple structure, while reducing the work time and the resistance of the fluid It is to provide a spacer flange for fastening the booster system to increase the efficiency of the pump by reducing the.

The spacer flange for fastening the booster system according to the embodiment of the present invention for achieving the above object is a suction header, the fluid is supplied to the discharge header, the discharge header is discharged from the suction header, between the suction header and the discharge header A plurality of booster pumps positioned to increase the pressure of the fluid of the suction header and discharge the discharge header to the discharge header, and between one or both of the booster pump and the suction header or between the booster pump and the discharge header. In the booster system including a pressure control valve as a spacer flange for fastening the booster system for coupling the booster pump and the pressure control valve,

A plate-shaped flange portion located between the pump flange of the booster pump and the pressure control valve, and the first bolt provided at the flange portion coupled to the pump flange side and the second bolt coupled to the pressure control valve side Includes fastenings each fastened together or together.

The fastening part may be formed in a hollow cylindrical shape, a screw thread may be formed on an inner circumference thereof to fasten a first bolt to one side, and to fasten the second bolt to the other side.

The fastening part is formed in a cylindrical shape, the thread is formed on the outer surface, the through-hole is formed in the flange portion is formed screw thread formed on the outer surface of the fastening portion may be coupled in the form of screwing each other in the through hole.

The pressure control valve may be a butterfly valve capable of pressure control from the outside.

A check valve may be positioned between the flange of the pump flange and the flange portion of the booster pump, and the check valve may be coupled by a coupling force of the first bolt coupling the pump flange and the flange portion. .

The second bolt may be fastened to the fastening part through the header flange of the suction header or the header flange of the discharge header, and the pressure control valve.

According to the present invention, by connecting the discharge header and the booster pump using a spacer flange for fastening the booster system, the manufacturing cost can be lowered with a relatively simple structure, and the repair time can be shortened when the booster system breaks down. It is formed with a length shorter than the length of the booster system can be minimized.

In addition, since the length of the booster pump and the suction header or the booster pump and the discharge header is shortened, it is possible to increase the efficiency of the pump by reducing the resistance of the fluid.

Figure 1 is a schematic diagram showing the configuration of a booster pump according to the prior art.
2 is a perspective view of a booster system having a spacer flange for fastening a booster system according to an embodiment of the present invention.
3 is a plan view of a booster system having a spacer flange for fastening a booster system according to an embodiment of the present invention.
4 is a side view of a booster system having a spacer flange for fastening a booster system according to an embodiment of the present invention.
5 is a perspective view schematically showing a suction header and a suction port of a booster system having a spacer flange for fastening a booster system according to an exemplary embodiment of the present invention.
FIG. 6 is a perspective view schematically illustrating a discharge header and an outlet of a booster system having a spacer flange for fastening a booster system according to an exemplary embodiment of the present invention.
7 is a perspective view of a spacer flange for fastening a booster system according to an embodiment of the present invention.
8 is a schematic side cross-sectional view of a spacer flange for fastening a booster system according to an embodiment of the present invention.

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

First, the booster system of the present invention is a pump and a pump driving device manufactured to automatically operate by interlocking one or more booster pumps according to the load.

As shown in FIG. 2 to FIG. 6, the booster system 100 in which the booster system fastening spacer flange 160 is installed according to an embodiment of the present invention may include a suction header 120.

The suction header 120 may supply a fluid to the booster pump 110 to be described below.

On the other hand, the suction header 120 may be formed in the shape of a tube to move the fluid, one side is sealed and the other side may be configured in an open form, the fluid may be supplied from the outside to the other open.

In addition, a plurality of suction pipes 121 may be formed in a direction orthogonal to the side of the suction header 120.

The suction pipe 121 may supply the fluid introduced from the suction header 120 to the booster pump 110, may be formed in a cylindrical shape, and suction suction flanges 125 may be formed at ends of the suction pipes 121. Can be formed.

At this time, the suction header flange 125 is formed with a bolt fastening hole for fastening a plurality of bolts along the circumference may be coupled to the pressure control valve 140 by the bolt.

The booster system 100 in which the booster system fastening spacer flange 160 is installed according to an embodiment of the present invention may include a discharge header 130.

The discharge header 130 may discharge the fluid supplied through the suction header 120.

On the other hand, the discharge header 130 may be formed in the shape of a tube to move the fluid, one side is sealed and the other side may be configured in an open form, the fluid may be supplied to the other open.

In addition, a plurality of discharge pipes 131 may be formed in a direction orthogonal to the side of the discharge header 130.

The discharge pipe 131 may discharge the fluid discharged from the booster pump 110 to the discharge header 130, may be formed in the shape of a cylinder, the discharge header flange 135 at the end of the discharge pipe 131 Can be formed.

At this time, the discharge header flange 135 is formed with a bolt fastening hole is a plurality of bolts are fastened along the circumference may be coupled to the pressure control valve 140 by the bolt.

In addition, the discharge header 130 may be disposed side by side with the suction header 120 spaced apart from each other.

The booster system 100 in which the booster system fastening spacer flange 160 is installed according to an embodiment of the present invention may include a booster pump 110.

The booster pump 110 may be configured to suck and discharge fluid, and may include an impeller 111 in the booster pump 110.

The impeller 111 can suck and discharge fluid by rotating centrifugal force.

Meanwhile, the impeller 111 may be configured such that a plurality of blades are radially arranged in a circumferential direction about a rotating shaft, and various types of known impellers may be applied.

In addition, the booster pump 110 may include a motor 112.

The motor 112 can provide a driving force for rotating the impeller 111.

On the other hand, the motor 112 is composed of a stator and a rotor provided with a drive shaft inside the stator, and the rotor is configured to rotate by the electric magnetic force inside the stator to rotate the drive shaft.

Here, the motor 112 may be implemented as an electric motor operated by electricity, and since the electric motor is a known configuration, further detailed description thereof will be omitted.

In addition, the booster pump 110 may include a suction port 116.

The fluid introduced from the suction header 120 may be sucked into the booster pump 110 through the suction port 116.

Meanwhile, the suction port 116 may include a pump flange 115.

Here, the pump flange 115 may be formed at the end of the inlet 116, the pump flange 115 may be formed in the shape of a plate so as to overlap with the pressure control valve 140, the pump flange 115 A plurality of bolt fastening holes may be formed around the periphery so as to be coupled by bolts.

The booster pump 110 may include an outlet 118.

The outlet 118 may discharge the fluid sucked through the inlet 116 to the discharge header 130, and the outlet 118 may be configured in the same manner as the pump flange 115 formed in the inlet 116. Can be. The booster system 100 in which the booster system fastening spacer flange 160 is installed according to an embodiment of the present invention may include a check valve 150.

The check valve 150 is installed between the pump flange 115 of the outlet 118 and the flange 161 to be described below, and the fluid discharged from the booster pump 110 toward the discharge header 130 is again boosted. The pump 110 can be prevented from flowing back in the direction in which it is located.

On the other hand, the check valve 150 is composed of an opening and closing plate, and the elastic member fitted to the shaft of the opening and closing plate may be configured to support the opening and closing plate in the interior of the check valve.

Here, the check valve 150 may be implemented with a known plate check valve, and the plate check valve is a known configuration, and thus detailed description thereof will be omitted.

The booster system 100 in which the booster system fastening spacer flange 160 is installed according to an embodiment of the present invention may include a pressure control valve 140.

The pressure control valve 140 may block the fluid by opening and closing the flow path.

On the other hand, the pressure control valve 140 may be located between the suction header 120 and the pump flange 115 or between the discharge header 230 and the pump flange 115.

Pressure control valve 140 is installed between the suction header 120 and the booster pump 110 may supply or block the fluid supplied from the suction header 120 to the booster pump 110, the booster pump 110 Installed between and the discharge header 130 may supply or block the fluid discharged from the booster pump 110 to the discharge header (130).

In this configuration, the pressure control valve 140 locks the pressure control valve 140 when a failure occurs in the booster pump 110, and the fluid and discharge header 130 supplied from the suction header 120 to the booster pump 110. In the booster pump 110 may block the flow of fluid.

In this case, the spacer flange 160 and the suction header flange 125 or the discharge header flange 135 may be coupled to one side and the other side of the pressure control valve 140, that is, the side end at which the fluid is introduced and discharged.

Here, the pressure control valve 140 may be implemented as a butterfly valve, the butterfly valve is a known configuration, so further detailed description thereof will be omitted.

As shown in FIG. 7 or 8, the spacer flange 160 for fastening the booster system according to the embodiment of the present invention may connect the pump flange 115 and the pressure control valve 140.

In this case, a check valve 150 may be installed between the pump flange 115 and the pressure control valve 140 at the outlet 118.

On the other hand, the spacer flange 160 may include a flange portion 161, the flange portion 161 may be formed in the shape of a plate, the fluid movement hole 167 through which the fluid can move is formed in the center The plurality of through holes 163 may be formed around the spacer flange 160.

The through hole 163 may be formed with a screw thread, may be formed along the circumference of the flange portion 161, and a plurality of fastening portions 165 may be fastened.

In addition, the fastening part 165 may be formed in the shape of a hollow cylinder with a cylinder, and a thread is formed on the inner circumference thereof so that the first bolt 171 coupled to the pump flange 115 is fastened to one side, and the other The second bolt 175 coupled to the suction header flange 125 or the discharge header flange 135 may be fastened to the side.

In addition, a thread is formed on the outer surface of the fastening part 165 and may be coupled in a form in which a screw thread formed in the through hole 163 is screwed together.

The spacer flange 160 configured as described above has a fastening portion 165 coupled to the through hole 163 of the flange portion 161, and the suction port 116 is disposed between the pump flange 115 and the pressure control valve 140. The first bolt 171 and the second bolt 175 are coupled to each other.

 Outlet 118 is coupled between the pump flange 115 and the pressure control valve 140, the check valve 150 is fitted between the pump flange 115 and the pressure control valve 140, the first The bolt 171 is coupled to the second bolt 175.

At this time, when replacing the check valve 150, loosen the first bolt 171, and loosen a part of the second bolt 175 and the fastener 165, the check valve 150 can be separated and replaced, spacer The pressure control valve 140 and the discharge header flange 135 are coupled to each other by the flange 160, so that a water leak does not occur and can be replaced.

The operation and effect of each of the components described above will be described.

In the booster system 100 in which the booster system fastening spacer flange 160 is installed according to an embodiment of the present invention, the booster pump 110 may have an inlet 116 for sucking fluid and an outlet 118 for discharging the sucked fluid. Is installed, the booster pump 110 is installed inside the motor 112 for driving the impeller 111, the impeller 111 for discharging the fluid to the outlet 118 in combination with the drive shaft of the motor 112 is installed. .

At this time, the inlet 116 and the outlet 118 includes a pump flange 115, a plurality of bolt fastening holes (not shown) is formed around the pump flange 115 may be bolted.

In addition, the suction pipe 121 is formed in the direction orthogonal to the side of the suction header 120, the suction header flange 125 is formed at the end of the suction pipe 121, the direction perpendicular to the side of the discharge header 130 Discharge pipe 131 is formed in, and the discharge header flange 135 is formed at the end.

At this time, the suction header 120 and the discharge header 130 are provided side by side, the booster pump 110 is provided between the suction header 120 and the discharge header 130.

A pressure control valve 140 and a spacer flange 160 are provided between the suction header 120 and the booster pump 130, and a check valve is disposed between the discharge header 130 and the booster pump 110. 150, the spacer flange 160 and the pressure control valve 140 is configured in the form.

Then, the first bolt 171 is coupled to the pump flange 115 side of the booster pump 110 is fastened to one side of the fastening portion 165 of the spacer flange 160, the second bolt on the pressure control valve 140 side. 175 is coupled to the other side of the fastening portion 165 of the spacer flange 160.

At this time, the spacer flange 160 is coupled to the through-hole 163 formed in the flange portion 161 in the form of being screwed with the fastening portion 165.

In the booster system 100 according to the embodiment of the present invention configured as described above, when the motor 112 in the booster pump 110 operates, the impeller 111 coupled to the driving shaft rotates and the fluid in the suction header 120 is rotated. Is passed through the pressure control valve 140 is sucked into the booster pump 110 through the inlet 116.

Then, the fluid sucked into the booster pump 110 is discharged to the discharge header 130 by passing through the outlet 118, the check valve 150, the pressure control valve 140 and the discharge pipe 131 by the impeller 111. do.

If the booster pump 110 fails, the pressure control valve 140 on the suction header 120 and the booster pump 110 and the pressure control valve 140 on the discharge header 130 and the booster pump 110 side. ) And the booster pump 110 is removed by unscrewing the first bolt 171 coupled to the inlet 116 and the outlet 118, that is, the spacer flanges 160 on both sides.

Thereafter, after replacing the booster pump 110, the first bolt 171 is coupled to the spacer flange 160, and then the pressure control valve 140 is opened.

On the other hand, if the check valve 150 is broken, the pressure control valve 140 on the suction header 120 and the booster pump 110 and the pressure control valve 140 on the discharge header 130 and the booster pump 110 side. ), And after removing the booster pump 110 by loosening the first bolt 171 coupled to the spacer flange 160 on the outlet 118 side, the fastener 165 coupled to the spacer flange 160 and A part of the second bolt 175 is loosened to separate the check valve 150.

Thereafter, the second bolt 175 and the fastener 165 are coupled to the spacer flange 160 to insert the replaced check valve 150, the first bolt 171 is fastened, and then the pressure regulating valve ( 140).

Therefore, since the short pipe is replaced by the flange portion, the manufacturing cost can be reduced with a relatively simple structure, the working time according to the production of the short pipe can be shortened, and the area occupied by the booster pump can be narrowed.

In addition, since the length of the booster pump and the suction header or the booster pump and the discharge header is shortened, the resistance of the fluid is reduced, thereby increasing the efficiency of the pump.

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 scope.

100: booster system 110: booster pump
111: impeller 112: motor
115: pump flange 116: suction port
118: outlet 120: suction header
121: suction pipe 125: suction header flange
130: discharge header 131: discharge pipe
135: discharge header flange 140: pressure regulating valve
150: check valve 160: spacer flange
161: flange portion 163: through hole
165: fastening portion 167: fluid movement hole
171: first bolt 175: second bolt

Claims (6)

A plurality of boosters disposed between the suction header to which the fluid is supplied, the discharge header through which the fluid introduced into the suction header is discharged, and located between the suction header and the discharge header to increase the pressure of the fluid in the suction header and discharge the fluid to the discharge header Booster for coupling the booster pump and the pressure control valve in a booster system including a pressure control valve is installed between any one or both of the booster pump and the suction header or between the booster pump and the discharge header. Spacer flange for fastening the system,
Plate-shaped flange portion located between the pump flange of the booster pump and the pressure control valve, And
Spacer flange for fastening the booster system, characterized in that it comprises a fastening portion provided in the plate-shaped flange portion is coupled to the first bolt coupled to the pump flange side and the second bolt coupled to the pressure control valve side or together. . The method of claim 1,
The fastening portion
The inner flange is formed in a hollow shape, a thread is formed on the inner circumference of the first bolt is fastened to one side, the second bolt is fastened to the booster system, characterized in that the flange flange. 3. The method of claim 2,
The fastening portion
It is formed in a cylindrical shape, a thread is formed on the outer surface,
The plate-shaped flange portion is formed with a threaded through-hole is formed in the screw thread formed on the outer surface of the fastening portion is coupled to the through-hole in the form of being screwed to each other in the form of a spacer flange for fastening the booster system. The method of claim 1,
The pressure control valve is a spacer flange for fastening the booster system, characterized in that the butterfly valve capable of pressure control from the outside. The method of claim 1,
A check valve is positioned between the pump flange of the part where the fluid of the booster pump is discharged and the plate flange portion,
The check valve is coupled to the booster system spacer flange, characterized in that coupled by the coupling force of the first bolt coupling the pump flange and the plate-shaped flange. The method of claim 1,
The second bolt is
And a header flange of the suction header or a header flange of the discharge header and the pressure control valve to be fastened to the coupling part.

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