KR20150065429A - Booster pump system - Google Patents

Abstract

The present invention relates to a booster pump system. The booster pump system comprises: an air intake manifold having an inner passage through which fluid flows; a plurality of pumps installed in the air intake manifold to discharge the fluid existed in the inner passage to a discharge manifold; and an air collection unit installed in the rear end of the air intake manifold based on the flowing direction of the fluid and collecting air to prevent the inflow of the air flowing in the inner passage into the pumps. The ceiling surface of the air intake manifold is obliquely formed such that the rear end of the ceiling surface can be higher than the front end of the ceiling surface based on the flowing direction of the fluid to flow the air into the air collection unit. According to the present invention, the booster pump system can prevent the inflow of the air, received in the manifold when initially operated, to the pumps by having the air collection unit to collect and discharge the air existing in the air intake manifold; thereby improving the pumping efficiency of the pumps.

Description

[0001] Booster pump system [0002]

The present invention relates to a booster pump system, and more particularly to a booster pump system having an air collecting means for discharging air introduced into a suction manifold through which a fluid is supplied by a pump.

Typically, the cooling and heating system of a multi-storey building or apartment house includes a water tank provided in the basement, a heat source facility for heating or cooling the heating medium stored in the water tank, i.e., water, and water heated or cooled by the heat source facility And the pressurized water is conveyed through the main water pipe, and the cooling and heating is performed as the lower and upper portions of the building circulate.

A booster pump is mainly used as a means for pressurizing water in the cooling and heating system. A plurality of booster pumps are generally connected in parallel to press water discharged from the water reservoir to a preset pressure and discharge the water to the main water pipe. The plurality of booster pumps are controlled to maintain a constant water supply pressure as the number of rotations is controlled mainly by the inverter. Hereinafter, a system including the booster pump and the inverter for controlling the booster pump will be briefly referred to as a booster pump system.

However, in the conventional booster pump system, the air contained in the manifold flows into the pump at the time of initial operation, causing the idling of the pump, thereby reducing the pumping efficiency of the pump.

Patent Publication No. 10-2009-0040002: Energy-saving booster pump system

SUMMARY OF THE INVENTION It is an object of the present invention to provide a booster pump system having an air collecting unit capable of collecting and discharging air introduced into a suction manifold.

According to an aspect of the present invention, there is provided a booster pump system including: a suction manifold having an internal flow path for a fluid to be introduced therein; and a discharge pump installed in the suction manifold for discharging the fluid in the internal flow path to a discharge manifold And an air collecting unit for collecting the air to prevent the air introduced into the internal flow path from being introduced into the pump, wherein the air collecting unit is provided at a rear end of the intake manifold with respect to the flow direction of the fluid, And the intake manifold is formed such that a ceiling surface is inclined such that a rear end ceiling surface is located above the front ceiling surface with respect to a flow direction of the fluid so that the air can be introduced into the air collecting unit.

Wherein the air collecting unit includes a collecting container provided on an upper outer peripheral surface of a rear end portion of the intake manifold so as to communicate with the internal flow path and having a chamber therein so that the air inside the intake manifold can be received, And a discharge pipe connected to the collecting container to discharge the air accommodated in the collecting container to the outside.

In the meantime, the air collecting unit according to the present invention is provided with a chamber at the rear end of the intake manifold so as to communicate with the internal passage, and a chamber in which the air in the intake manifold can be introduced, And a discharge pipe connected to the collecting container for discharging the air accommodated in the collecting container to the outside.

In addition, the booster pump system according to the present invention includes an exhaust pipe provided in the housing of the pump for discharging the air introduced into the housing of the pump communicated with the suction manifold to the outside, An exhaust manifold for collecting the air introduced through the exhaust pipe and the discharge pipe and discharging the air to the outside, a first valve installed in the exhaust pipe to open and close the exhaust pipe, and a second valve installed in the exhaust pipe, An inverter installed in the motor of the pump for rotating the impeller installed in the housing and controlling the motor; and a controller for detecting the magnitude of the current output from the inverter and detecting the magnitude of the current in the idle state of the pump The operation of the motor is stopped, and the exhaust pipe and the discharge pipe are opened And a control unit controlling the first and second valves to discharge the air.

The booster pump system according to the present invention is provided with an air collecting unit capable of collecting and discharging the air introduced into the intake manifold so that the air contained in the manifold is prevented from flowing into the pump during the initial operation, .

1 is a perspective view of a booster pump system according to the present invention,
Figure 2 is a cross-sectional view of the booster pump system of Figure 1,
3 is a cross-sectional view of a booster pump system according to another embodiment of the present invention.

Hereinafter, a booster pump system according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 illustrate a booster pump system 100 in accordance with an embodiment of the present invention.

Referring to the drawings, the booster pump system 100 includes a suction manifold 110 provided with an internal flow path 111 through which fluid flows therein, and a suction pump 110 installed in the suction manifold 110, A plurality of pumps 120 for discharging the fluid to the discharge manifold 127 and a plurality of pumps 120 installed at a rear end of the intake manifold 110 on the basis of the flow direction of the fluid, And an air collecting unit (130) for collecting the air to prevent the air from being introduced into the pump (120).

The intake manifold 110 extends in the front-rear direction, and an internal flow path 111 is provided therein. A front end of the intake manifold 110 is connected to a fluid supply unit (not shown), and fluid flows into the intake manifold 110 through the fluid supply unit. The other end of the intake manifold 110 is closed.

At this time, the intake manifold 110 is moved in the direction of the flow of the fluid so as to allow the air to flow into the air collecting unit 130 so that the air can be easily introduced into the air collecting unit 130, The ceiling surface is inclined so that the end ceiling surface is located above the ceiling surface of the front end. That is, it is preferable that the intake manifold 110 is formed so that its inner diameter increases from the front end to the rear end.

The pump 120 is connected to the intake manifold 110 by a supply pipe and includes a housing 121 provided with a chamber into which fluid is introduced and an impeller rotatably installed in the housing 121 (Not shown) for controlling the motor 122 and an outlet (not shown) of the housing 121 through which the fluid is discharged by the rotation of the impeller. The motor 122 rotates the impeller And the other end is provided with a connection pipe (not shown) connected to the discharge manifold 127. Since the pump 120 is a conventional pump 120, a detailed description thereof will be omitted.

An exhaust pipe 124 is connected to the housing 121 so that one end of the air can be discharged to the outside of the housing 121 when the air flows into the chamber 121 in the housing 121 of the pump 120. [ Is installed. The exhaust pipe 124 is provided with a first valve 125 for opening and closing the exhaust pipe 124. Exhaust pipes 124 provided in the respective pumps 120 are installed in the intake manifold. The exhaust pipe 124 may be installed on the upper surface of the housing 121. The intake manifold collects the air discharged through the exhaust pipe 124 and discharges the collected air to the outside.

The pump 120 constructed as described above is installed in the suction manifold 110 such that a plurality of the pumps 120 are spaced apart from each other in the longitudinal direction.

The air collecting unit 130 is installed on the upper outer peripheral surface of the rear end of the intake manifold 110 so as to communicate with the internal flow path 111, And a discharge pipe 132 connected to the collecting container 131 for discharging the air stored in the collecting container 131 to the outside.

The collection container 131 is located on the upper side with respect to the intake manifold 110, and is formed to extend in the vertical direction by a predetermined length. The discharge pipe 132 has an end communicated with the exhaust manifold 126, and a second valve 133 is provided to open and close an internal flow path. At this time, the discharge pipe 132 is preferably installed on the upper surface of the collecting container 131.

The air flowing into the intake manifold 110 is moved to an upper portion of the intake manifold 110. Since the intake manifold 110 is inclined in a ceiling view, As shown in FIG. The air that moves to the rear end of the intake manifold 110 is collected in the collection container 131 and discharged to the exhaust manifold 126 through the discharge pipe 132.

The booster pump system 100 according to the present invention constructed as described above is provided with an air collecting unit 130 capable of collecting and discharging the air introduced into the intake manifold 110, The pumping efficiency of the pump 120 is improved because the pump 120 is prevented from flowing into the pump 120.

The booster pump system 100 according to the present invention includes a controller 140 for controlling the motors 122 of the pumps 120 and the first and second valves 125 and 133. The control unit 140 senses the magnitude of the current output from the inverter and stops the operation of the motor 122 when the magnitude of the current is detected as the idle state of the pump 120, The discharge pipe 132 is opened to discharge the air.

The control unit 140 is connected to the inverters through a communication line, and the control unit 140 transmits a control signal to the inverter through the communication line and senses a current from the inverter. At this time, the inverter supplies electric power to the motor 122 by the control signal. Accordingly, when the booster pump system 100 is operated, the control unit 140 gives a control signal to the inverter to obtain information on the output power from the inverter at predetermined intervals. Therefore, if the output power is rapidly increased beyond the normal output power, The pump 120 is stopped and the first and second valves 125 and 133 are controlled so that the exhaust pipe 124 and the discharge pipe 132 are opened.

The control unit 140 controls the first and second valves 125 and 133 so that the exhaust pipe 124 and the discharge pipe 132 are closed and then the exhaust pipe 132 and the exhaust pipe 132 are closed. Controls the motor 122 of the inverter 120 to operate. Although not shown in the figure, the control unit 140 has a timer for measuring the passage of time after the exhaust pipe 124 and the discharge pipe 132 are opened.

3, an air collecting unit 210 according to another embodiment of the present invention is shown.

Elements having the same functions as those in the previous drawings are denoted by the same reference numerals.

The air collecting unit 210 includes a collecting container 211 installed at the rear end of the intake manifold 110 and a discharge pipe 132 communicating with the collecting container 211.

A front end of the collecting container 211 is installed at the rear end of the intake manifold 110 and a chamber is provided in the intake manifold 110 to allow the air to flow therein. The collecting container 211 is formed such that the rear end thereof is closed and the ceiling surface is positioned above the rear end ceiling surface of the intake manifold 110. That is, the collection container 211 is formed so as to have an inner diameter larger than the inner diameter of the rear end of the intake manifold 110, so that the longitudinal center line of the intake manifold 110 is positioned above the longitudinal center line of the intake manifold 110 110).

One end of the discharge pipe 132 is connected to the upper surface of the collecting container 211 and the other end is connected to the exhaust manifold 126. The discharge pipe 132 is provided with a second valve 133 for opening and closing the inside of the discharge pipe 132 and the second valve 133 is controlled by the control unit 140.

The air flowing into the intake manifold 110 is moved to an upper portion of the intake manifold 110. Since the intake manifold 110 is inclined in a ceiling view, As shown in FIG. The air that is moved to the rear end of the intake manifold 110 is collected in the collection container 211 and discharged to the exhaust manifold 126 through the discharge pipe 132.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be appreciated that other embodiments are possible.

Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: Booster pump system
110: Suction manifold
111: Internal flow path
120: pump
121: Housing
122: motor
123: Inverter
124: Exhaust pipe
125: first valve
130: Air collecting unit
131: Collection container
132:
133: Second valve
140:

Claims (4)

A suction manifold provided with an internal flow path into which fluid flows;
A plurality of pumps installed in the intake manifold to discharge the fluid in the internal flow path to a discharge manifold;
And an air collecting unit installed on the suction manifold with reference to a flow direction of the fluid and collecting the air so as to prevent inflow of air introduced into the internal flow path into the pump, Booster pump system.
The method according to claim 1,
Wherein the suction manifold is formed such that the ceiling surface is inclined such that the rear end ceiling surface is located above the front ceiling surface with respect to the flow direction of the fluid so that the air can flow into the air collecting unit. .
3. The method of claim 2,
The air collecting unit
Wherein the intake manifold is provided at a rear end portion thereof with a chamber communicating with the internal flow path and having a chamber therein through which the air in the intake manifold can be introduced, wherein a ceiling surface is located above the rear end ceiling surface of the intake manifold, A collecting container formed to be positioned,
And a discharge pipe connected to the collecting container for discharging the air stored in the collecting container to the outside.
The method according to claim 2 or 3,
An exhaust pipe installed in the housing of the pump for discharging the air introduced into the housing of the pump communicated with the intake manifold to the outside;
An exhaust manifold installed to communicate with the exhaust pipe and the exhaust pipe and collecting the air introduced through the exhaust pipe and the exhaust pipe and discharging the collected air to the outside;
A first valve installed in the exhaust pipe to open and close the exhaust pipe;
A second valve installed in the discharge pipe to open and close the discharge pipe;
An inverter installed in a motor of the pump for rotating an impeller installed in the housing and controlling the motor;
Wherein the control unit controls the first and second valves to stop the operation of the motor when the magnitude of the current is detected as the idle state of the pump by sensing the magnitude of the current output from the inverter and to open the exhaust pipe and the discharge pipe, And a control unit for discharging air from the booster pump.

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