KR101596768B1 - Integrated pump unit for heat pump system - Google Patents

Abstract

A pump integrated unit for a heat pump system used in a heat pump system including a heat pump, a heat storage tank and an indoor unit, comprising: a housing; At least two sets of piping installed inside the housing; The piping set of each of the groups includes a pump for flowing water in a downward direction, a check valve provided on the lower side of the pump, a strainer provided on the lower side of the check valve, an expansion tank provided on the upper side of the pump, A transfer pipe to which a sensor and a pressure sensor are installed, and a circulation pipe which is a path through which water flowing outward through the transfer pipe is circulated and flows back; And a controller for receiving signals from the temperature sensor and the pressure sensor and controlling the pump.

Description

[0001] INTEGRATED PUMP UNIT FOR HEAT PUMP SYSTEM [0002]

The present invention relates to a pump integrated unit for a heat pump system, and more particularly, to a pump integrated unit for a heat pump system that is connected to a heat pump such as a geothermal heat pump or an air heat pump, so that the heat pump system can be easily installed.

The heat pump means a device that transfers a low-temperature heat source to a high temperature or a high-temperature heat source to a low temperature by using heat of a refrigerant or condensation heat. The heat pump has the same structure as the refrigeration cycle. Generally, the refrigeration cycle consists of a compressor, a condenser, an expansion valve, and an evaporator, so that the refrigerant boils in the evaporator and absorbs heat from the outside. Gas is sent to the condenser, and heat is released from the condenser to the outside, so that the high-pressure refrigerant gas is condensed and liquefied to reach a low-temperature, high-pressure liquid state. The refrigerant condensed as described above throttles and expands through the expansion valve, and a part of the refrigerant liquid evaporates. Through the absorption of the latent heat, the refrigerant liquid becomes an abnormal state in which the liquid phase and the vapor phase of the low temperature and low pressure coexist It boils through the evaporator. As described above, the refrigeration cycle can be regarded as a pump that has both a portion that absorbs heat and a portion that releases heat, and that the heat is absorbed by the evaporator and arranged in the condenser, that is, the heat is transferred. The heat pump constitutes the condenser and the evaporator as a heat exchanger capable of functioning in such a refrigeration cycle. For example, the heat pump functions as a condenser at the time of heating, and functions as an evaporator at the time of cooling the heat exchanger.

The heat pump includes a heat pump for air heat, which obtains the required heat in the air, a geothermal heat pump for obtaining the required heat in the ground, and a heat pump for the heat from the waste heat source.

Such a heat pump system using a heat pump requires a plurality of additional devices such as a pump for integrated operation and control of each device including a heat pump, a heat storage tank, and an indoor unit. The connection method and the control method are different from each other.

It is an object of the present invention to provide a pump integrated unit for a heat pump system that can easily install a heat pump system using a heat pump.

To achieve the above object, the present invention provides a pump integrated unit for a heat pump system used in a heat pump system including a heat pump, a heat storage tank and an indoor unit, comprising: a housing; At least two sets of piping installed inside the housing; The piping set of each of the groups includes a pump for flowing water in a downward direction, a check valve provided on the lower side of the pump, a strainer provided on the lower side of the check valve, an expansion tank provided on the upper side of the pump, A transfer pipe to which a sensor and a pressure sensor are installed, and a circulation pipe which is a path through which water flowing outward through the transfer pipe is circulated and flows back; And a piping coupler for connecting each of both ends of the transfer piping and the circulation piping to an external piping; And a controller for receiving signals from the temperature sensor and the pressure sensor and controlling the pump.

According to the present invention, there is further provided an auxiliary pump integrating unit including a set of the above-described pipe sets inside the housing, wherein the auxiliary pump integrating unit is connected to the controller of the pump integrating unit and is integrally controllable.

According to the pump integrated unit of the present invention, the heat pump system can be simply and efficiently installed only by arranging the heat pump, the heat storage tank, the indoor unit, and the like at the installation position, Can be configured.

FIG. 1 is a view showing the appearance of a pump integrated unit according to the present invention.
FIG. 2 is a view for explaining the internal configuration of the pump integrated unit shown in FIG. 1. FIG.
3 and 4 are an external view and a structural view of the auxiliary pump integrated unit according to the present invention.
FIG. 5 illustrates an example of a configuration of a heat pump system using a pump integrated unit according to the present invention.
FIG. 6 shows an example of a geothermal heat pump system using a pump integrated unit according to the present invention.

Hereinafter, a pump integrating unit according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a view showing the appearance of a pump integrated unit according to the present invention. A controller 108 is provided on one side of the outer surface of the housing 101 of the pump integrating unit 100 and a piping coupler 102 is provided on both sides.

The piping couplers 102a, 103a, 102b, and 103b are connected to the respective ends of the pipes installed inside the housing, so that each pipe installed inside the housing can be connected to pipes extended from other devices.

In addition, expansion tanks 140a and 140b are installed on one side of the outer surface of the housing 101 and on the upper side thereof.

FIG. 2 is a view for explaining the internal configuration of the pump integrated unit shown in FIG. 1. FIG.

Referring to FIG. 2, the housing 101 of the pump integrating unit 100 includes two sets of pipes 110a and 110b. Each set of tubing pipes 110a and 110b includes transfer pipes 120a and 120b and circulation pipes 150a and 150b.

The transfer pipes 120a and 120b are paths for transferring the water to the other apparatuses of the water of the one apparatus using the pump pressure and the circulating pipes 150a and 150b are the paths for transferring the water introduced into the other apparatus through the transfer pipes 120a and 120a And returns to the one-side apparatus via the inside of the other apparatus.

The transfer piping 120 is provided with pumps 130a and 130b for flowing water to the rear side and check valves 132a and 132b installed on the rear sides of the pumps 130a and 130b and the rear side of the check valves 132a and 132b And strainer 134a or 134b installed in the case. In this specification, the upper side and the lower side are related to the direction along the water flow, and the side on which the water flows is defined as the front side and the side on which the water flows is defined as the rear side.

For example, when a set of piping sets 110a is connected to one side of a heat storage tank and the other side is connected to a heat pump, water in the heat storage tank is transferred to the heat pump through the transfer piping 120a using the pressure of the pump 130a , And the water of the heat pump is circulated through the circulation pipe (150a) while returning to the heat storage tank. The pumps 130a and 130b function to provide a conveying force to the circulation path through which water is circulated.

The check valves 132a and 132b are provided below the pumps 130a and 130b to ensure that water is circulated in one direction while preventing backflow of water.

The strainer 134a or 134b installed below the check valves 132a and 132b can collect and remove foreign substances in the flowing water.

The transfer pipes 120a and 120b are provided with expansion tanks 140a and 140b. The expansion tanks 140a and 140b function to absorb the volume change due to the temperature change of the water circulating through the transfer pipes 120a and 120b and the circulation pipes 150a and 150b.

Pressure sensors 141a, 141b, 142a and 142b are provided on the front and rear sides of the pumps 130a and 130b respectively and temperature sensors 145a and 145b are installed on the front sides of the pumps 130a and 130b. The pressure sensors 141a, 141b, 142a and 142b and the temperature sensors 145a and 145b sense the temperature and pressure of water flowing along the transfer piping 120a and 120b and provide them to the controller 108. [

The circulation pipes 150a and 150b are used as return paths for water flowing through the transfer pipes 120a and 120b and simplify the circulation pipe 150 by concentrating the accessories in the transfer pipes 120a and 120b.

The two sets of piping sets 110a and 110b of the pump integrating unit 100 have the same configuration.

3 and 4 are an external view and a structural view of the auxiliary pump integrated unit according to the present invention. The auxiliary pump integrating unit 160 includes a set of piping 110c connected to the outside of the housing 161 via piping couplers 102c and 103c and a piping set 110a And includes a pump 130c, a check valve 132c, a strainer 134c, an expansion tank 140c, pressure sensors 141c and 142c, and a temperature sensor 145c.

The auxiliary pump integrated unit 160 has a pump 140c installed therein, pressure sensors 141c and 142c, and terminals 148 of the temperature sensor 145c. The terminals 148 drawn out of the auxiliary pump integrating unit 160 are connected to the controller 108 of the pump integrating unit 100 and are configured to be integrally controlled.

The controller 108 of the pump integration unit 100 is connected to the central controller to control the operation of the pumps 140a, 140b and 140c of the pump integration unit 100 or the auxiliary pump integration unit 160, 145b, 145c, and temperature sensors 145a, 145b, 145c to the central controller to be used to control the overall operation of the heat pump system, The sensed values of the pressure sensors 141a, 142a, 141b, 142b, 141c and 142c and the temperature sensors 145a, 145b and 145c can be directly used to control the operation of the pumps 140a, 140b and 140c.

FIG. 5 illustrates an example of a configuration of a heat pump system using a pump integrated unit according to the present invention.

5, the air heat heat pump system includes a heat pump unit 200, a pump unit 100, a heat storage tank 300, and an indoor unit 400 and a central controller 500.

A set of pipes 110a of the pump integrated unit 100 is connected to circulate water between the air heat pump 200 and the thermal storage tank 300 while the other set of pipes 110b is connected to the thermal storage tank 120. [ And the indoor unit (400).

The central controller 500 controls the overall operation of the heat pump system.

For example, the central controller 500 drives the pump 140a through the controller 108 to transfer the water in the heat storage tank 300 to the air heat pump 200 through the transfer pipe 120a, The heat pump 200 heats the transferred water through heat exchange inside and returns it to the heat storage tank 300 through the circulation pipe 150a. At this time, the operation of the air heat pump 200 and the pump 140a can be controlled by using the sensing values of the pressure sensors 141 and 142 and the temperature sensor 145 installed in the transfer pipe.

Meanwhile, the central controller 500 controls the driving of the pump 140b through the controller 108 to transfer the water in the storage tank 300 to the indoor unit 400 through the transfer pipe 120b, The water cooled through the heat exchange is returned to the heat storage tank 300 through the circulation pipe 150a. The operation of the pump 140b can be controlled by using the sensing values of the pressure sensors 141 and 142 and the temperature sensor 145 installed in the first pipe.

In the case where the pump integrated unit 100 according to the present invention is used, the air heat pump 200, the heat storage tank 300, and the indoor unit 400 are disposed at installation positions, And the controller 108 are connected to each other, the heat pump system can be configured simply and efficiently.

FIG. 6 shows an example of a geothermal heat pump system using a pump integrated unit according to the present invention.

6, the geothermal heat pump system includes a geothermal heat pump 600, a geothermal heat source 650, a pump integration unit 100, and an auxiliary pump integration unit 160. The geothermal heat pump 600 includes a geothermal heat pump 600, And a central controller 500. The geothermal heat source 650 is composed of an underground pipe 655 buried in the ground so that the circulation water circulates along the underground pipe 655 to perform heat exchange with the underground.

When additional circulation paths of water other than the circulation of water through the pump integrated unit 100 are required for the heat pump system configuration, the auxiliary pump integrated unit 160 is stacked on the pump integrated unit 100 to operate as one controller 108 A pump integrated unit can be constructed.

The piping set 110a of the pump integrated unit 100 is connected to circulate water between the geothermal circulation source 650 and the geothermal heat pump 600 and the other piping set 110b is connected to the geothermal heat pump 600, And the piping set 110c of the auxiliary pump tank unit 160 is connected to circulate the water between the heat storage tank 300 and the indoor unit 400. [

The central controller 500 drives the pump 140a through the controller 108 to heat the heated water in the geothermal circulation source 650 through the transfer pipeline 120a to the geothermal heat pump 600 And the geothermal heat pump 600 heats the water transferred from the heat storage tank through heat exchange inside. The water conveyed from the geothermal circulation source 650 is circulated through the circulation pipe 150a to return to the geothermal circulation source 650. The central controller 500 drives the pump 140b through the controller 108 to transfer the water in the storage tank 300 to the geothermal heat pump 600 through the transfer pipe 120a and the geothermal heat pump 600 heat the transferred water through heat exchange with the water supplied from the geothermal circulation source 650 inside and return it to the storage tank 300 through the circulation pipe 150b. At this time, the geothermal heat pump 600 and the pumps 140a and 140b are operated by using the sensing values of the pressure sensors 141a, 142a, 141b, and 142b and the temperature sensors 145a and 145b provided on the transfer pipes 120a and 120b .

Meanwhile, the central controller 500 controls the pump 140c of the auxiliary pump integrating unit 160 to control the water in the storage tank 300 to the indoor unit 400 through the transfer pipe 120c through the controller 108 And the water cooled through the heat exchange in the indoor unit 400 is returned to the heat storage tank 300 through the circulation pipe 150c. The operation of the pump 140c is controlled by using the sensing values of the pressure sensors 141c and 142c and the temperature sensor 145c provided in the transfer pipe 120c.

As described above, when the pump integrated unit 100 according to the present invention is used, it is possible to integrally install and control the auxiliary pump integrated unit 160 when an additional circulation line is required. The geothermal heat pump 600, The heat pump system can be configured simply and efficiently by connecting the circulator 650, the heat accumulation tank 300, and the indoor unit 400 via the pump integration unit 100 by piping and connecting the controllers to each other.

Claims (2)

1. A pump integrated unit for a heat pump system used in a heat pump system including a heat pump, a heat storage tank, and an indoor unit,
housing; And
And at least two sets of pipes installed inside the housing,
Each set of piping includes: a pump for flowing water in a downward direction; A check valve installed below the pump; A strainer disposed under the check valve; An expansion tank installed above the pump; A transfer pipe on which a temperature sensor and a pressure sensor are installed;
And a circulation pipe through which the water flowing out to the outside through the transfer pipe circulates and flows again,
And a controller for receiving signals from the temperature sensor and the pressure sensor and controlling the pump,
Wherein the pump, the check valve, the strainer, the expansion tank, the temperature sensor, and the pressure sensor are concentrated on the transfer pipe. The method according to claim 1,
Further comprising an auxiliary pump integration unit including a set of said tubing within said housing,
Wherein the auxiliary pump integrated unit is connected to the controller of the pump integrated unit and is integrally controllable.

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