KR20180009621A - Apparatus for cooling a pump actuation motor - Google Patents

Abstract

The present invention relates to an apparatus to efficiently cool a motor to drive a pump installed on a fluid cycle and to realize a compact pump-motor assembly. According to the present invention, the apparatus to cool the motor to drive the pump, which cools a motor to drive a pump installed on a circulation path of a fluid cycle, comprises: a cooling block which has a cooling flow path, through which a fluid circulating on a circulation path of the fluid cycle passes, to cool the motor to drive the pump through the fluid passing through the cooling flow path; and a storage tank connected to the cooling flow path of the cooling block to supply the fluid. The cooling flow path of the cooling block may be connected to the pump to communicate.

Description

[0001] APPARATUS FOR COOLING A PUMP ACTUATION MOTOR [0002]

The present invention relates to a pump-driving motor cooling apparatus, and more particularly to a pump-driving motor cooling apparatus for efficiently driving a pump driving motor for driving a pump installed in a fluid cycle such as a refrigeration cycle, a Rankine cycle, The present invention relates to a motor cooling apparatus capable of realizing a motor cooling apparatus.

The motor receives electric power and generates rotational force on the output shaft. Heat may be generated according to the efficiency of the motor when the motor is operated.

In case of general motor, when it is used under 30% of maximum torque, it is possible to discharge the heat of motor by natural cooling without forced cooling system. However, since the heat generated when the motor operates continuously for a long time and the load condition is high is not released by natural cooling, the heat can accumulate. When the accumulated heat exceeds 110 ° C, So that the motor can not be operated. The size of the motor is designed to be fluidly sized according to the magnitude of the torque required, and a separate forced cooling system such as a cooling fan is used.

For example, in a fluid cycle such as a refrigerant cycle having a pump, a Rankine cycle of a waste heat recovery system, etc., a pump for circulating a fluid such as a refrigerant or a working fluid is installed on the fluid passage. A motor is connected to the pump, By operation, the pump is driven so that the refrigerant or working fluid can circulate along the circulation path of each cycle.

However, when a separate forced cooling system is installed on the motor side, the size and weight of the motor are increased, and the cost is increased. In addition, since the forced cooling system is installed adjacent to the motor, installation and assembly of the pump-motor assembly can not be easily performed.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a pump driving motor cooling apparatus capable of effectively cooling a pump driving motor without requiring a separate forced cooling system, .

According to an aspect of the present invention, there is provided a pump driving motor cooling apparatus for cooling a pump driving motor for driving a pump installed on a circulation path of a fluid cycle,

A cooling block for cooling the pump driving motor;

A cooling passage formed in the cooling block, through which the fluid circulating on the circulation path of the fluid cycle passes; And

And a storage tank connected to supply a fluid to the cooling channel,

The cooling channel may be connected to communicate with the pump.

The cooling block may be installed to surround at least a part of the outer surface of the pump driving motor.

The cooling passage may be formed between the cooling block and the pump driving motor.

The storage tank may be installed on the circulation path of the fluid cycle to store the fluid circulating the circulation path.

The cooling block may have at least one partition wall defining a flow direction of the fluid in the cooling passage.

A supply hose may be connected between the inlet of the cooling block and the outlet of the storage tank.

A discharge hose may be connected between the outlet of the cooling block and the inlet of the pump.

Wherein the pump and the pump driving motor are arranged in a line so as to constitute a pump-motor assembly.

According to the present invention, it is possible to provide a separate forced cooling system by directly exchanging heat between the pump driving motor for driving the fluid circulating pump and the fluid in the fluid cycle on the fluid cycle in which the fluid circulates, such as a refrigerant cycle and a Rankine cycle There is an advantage that cooling of the pump driving motor can be efficiently performed without necessity.

The present invention also has the advantage that the pump-motor assembly can be modularized into a compact structure on the storage tank side by implementing a structure that directly transfers the fluid from the storage tank of the fluid cycle to the cooling channel side of the cooling block.

FIG. 1 is a perspective view showing a state in which a pump driving motor cooling apparatus according to various embodiments of the present invention is viewed from one side.
2 is a perspective view showing a state in which the pump-driving motor cooling apparatus according to various embodiments of the present invention is viewed from the other side.
3 is an exploded perspective view showing a state in which a cooling block is disassembled from an outer surface of a pump driving motor of a pump driving motor cooling apparatus according to various embodiments of the present invention.
4 is a front sectional view showing a structure in which a cooling passage is formed between an outer surface of a pump driving motor and an inner surface of a cooling block of the pump driving motor cooling apparatus according to the present invention.
Fig. 5 is a partially cutaway perspective view showing a cooling block of a pump driving motor according to the present invention. Fig.
6 is a diagram showing a structure in which a pump-driving motor cooling apparatus according to the present invention is applied to a Rankine cycle of a waste heat recovery system.
7 is a view showing a structure in which a pump-driving motor cooling apparatus according to the present invention is applied to a refrigerant cycle.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. For the sake of convenience, the size, line thickness, and the like of the components shown in the drawings referenced in the description of the present invention may be exaggerated somewhat. The terms used in the description of the present invention are defined in consideration of the functions of the present invention, and thus may be changed depending on the user, the intention of the operator, customs, and the like. Therefore, the definition of this term should be based on the contents of this specification as a whole.

1, a motor cooling apparatus for driving a pump according to various embodiments of the present invention includes a pump 5 for circulating fluid on a fluid cycle, a pump driving motor 10 for driving the pump 5, A cooling block 15 installed to cool the pump driving motor 10 and a storage tank 40 connected to supply the fluid to the cooling block 15 side.

The pump 5 may be arranged on the circulation paths 51 and 61 of the fluid cycle such as the Rankine cycle 50 (see FIG. 6), the refrigerant cycle 60 (see FIG. 7)

The pump 5 has an inlet 6 and an outlet 7 and can be configured to discharge the fluid into the outlet 7 side by pumping operation of the fluid introduced through the inlet 6. [

The pump drive motor 10 has a drive shaft for driving the pump 5, and can drive the pump 5 by rotating the drive shaft as the power source is applied. 1 and 2, the driving shaft of the pump driving motor 10 is connected in series to the rotating shaft of the pump 5, and in particular, the case of the pump driving motor 10 and the case of the pump 5 Are arranged in a line so as to constitute a pump-motor assembly.

A cooling block 15 is provided on the outer surface of the pump driving motor 10 and the cooling block 15 can surround the outer surface of at least a part of the case of the pump driving motor 10. [

The cooling block 15 is provided with a cooling passage 17 through which the fluid circulating through the circulation paths 51 and 16 of the fluid cycle passes. And can be disposed adjacent to the outer surface of the motor 10. Thus, the pump driving motor 10 can be cooled by heat exchange with the pump driving motor 10 while the fluid passes through the cooling flow passage 17. [

According to one embodiment, the cooling passage 17 may be formed between the inner surface of the cooling block 15 and the outer surface of the pump driving motor 10 as shown in Figs. 3 and 4.

3, a sealing wall 16 is formed at the edge of the cooling block 15, and the sealing wall 16 is formed to have a large thickness of the cooling block 15, and the sealing wall 16 The thickness of the cooling passage 17 can be determined. By providing the sealing wall 16 in close contact with the outer surface of the pump driving motor 10, the cooling passage 17 can be sealed to the outside. The cooling block 15 may be curved so as to correspond to the outer surface of the case of the pump driving motor 10. The fluid can pass through the cooling passage 17 while being in direct contact with the outer surface of the pump driving motor 10 to perform heat exchange so that the pump driving motor 10 can be efficiently cooled.

On the other hand, the cooling block 15 may have a plurality of partitions 17a forming the flow direction of the fluid in the cooling flow path 17, and the plurality of partitions 17a may be formed in a rib shape on the inner surface of the cooling block 15 . Particularly, since the plurality of partition walls 17a are disposed in a staggered configuration, the flow length of the fluid in the cooling channel 17 can be greatly extended, and the cooling block 15 can increase the contact area with the fluid, There is an advantage to increase.

The cooling block 15 has an inlet 18 and an outlet 19 in communication with the cooling channel 17 and allows the fluid to flow in through the inlet 18 and flows out through the outlet 19. [ .

According to another embodiment, the cooling block 15 may have a certain thickness and the inner surface of the cooling block 15 may be set in contact with the outer surface of the pump driving motor 10. The cooling passage 15 is formed between the inner surface and the outer surface of the cooling block 15 so that the cooling block 15 may be in the form of a water jacket. The fluid passing through the cooling channel of the cooling block 15 can indirectly exchange heat with the outer surface of the pump driving motor 10. [

The pump drive motor 10 may be installed adjacent to a storage tank 40 in which the fluid is stored and the storage tank 40 may be connected to a fluid cycle (Rankine cycle 50 in FIG. 6 or a refrigerant cycle 60 The storage tank 40 has an inlet 41 through which the fluid flows and an outlet through which the fluid flows out.

The outlet 42 of the storage tank 40 and the inlet 18 of the cooling block 15 are connected via a supply hose 81 and the fluid from the storage tank 40 is cooled Can be supplied to the cooling channel (17) side of the block (15).

On the other hand, since the storage tank 40 is disposed on the downstream side of the condenser 52, 62 of the fluid cycle as illustrated in FIGS. 6 and 7, a relatively low temperature fluid is stored in the storage tank 40 . Accordingly, as the fluid in the storage tank 40 passes through the cooling passage 17 of the cooling block 15, the heat generated in the pump driving motor 10 can be adequately cooled.

The cooling passage 17 of the cooling block 15 and the pump 5 are communicably connected to each other so that the fluid having passed through the cooling passage 17 of the cooling block 15 flows through the pump 5 Can be circulated on the circulation path (51, 61) of the fluid cycle (50, 60). 2, the outlet 19 of the cooling block 15 and the inlet 6 of the pump 5 are connected through a discharge hose 82, The fluid that has passed through the cooling passage 17 of the pump 5 flows into the inlet 6 of the pump 5 and is discharged through the outlet 7 of the pump 5 by the pumping operation of the pump 5, , 60 on the circulation path (51, 61).

As such, the present invention can be used before the fluid is pumped by the pump 5 that circulates the fluid on the circulation path 51, 61 of the fluid cycle 50, 60 (before the fluid is supplied to the inlet of the pump 5) ) By passing the fluid through the cooling passage 17, the pump driving motor 10 can be appropriately cooled and the heat generated during the pump driving motor 10 driving the pump 5 can be appropriately cooled Therefore, the driving efficiency of the pump 5 is improved and the circulation performance of the fluid can be improved. The fluid passing through the cooling channel 17 can be introduced into the inlet 6 of the pump 5 in a state of receiving heat from the pump driving motor 10 and then being supplied to the pump 5, 61 disposed on the downstream side of the pump 5 on the circulation paths 51, 61 of the fluid cycles 50, 60 as circulated along the circulation path 52, 62 of the fluid cycle by the pumping action of the evaporator 53, 63 and the like can be greatly improved.

A pump driving motor 10 and a pump 5 are provided in the receiving space 43 of the storage tank 40. The pump driving motor 10 and the pump 5 An integrated pump-motor assembly can be received and installed. As the pump-motor assembly is received in the receiving space 43 of the storage tank 40, the pump-motor assembly is advantageous in that it can be modularized into a very compact structure with respect to the storage tank 40.

6 is a view showing a structure in which the pump driving motor 10 according to the present invention is applied to the Rankine cycle 50 of a waste heat recovery system for a vehicle.

According to the embodiment of Fig. 6, the pump driving motor 10 can be applied to the Rankine cycle 50 of the waste heat recovery system, and the pump 5 for circulating the working fluid of the Rankine cycle 50 is connected to the pump driving motor 10, and the pump driving motor 10 can be adequately cooled by the working fluid before it is introduced into the pump 5. [

6, the Rankine cycle 50 includes a circulation path 51 through which the working fluid circulates, and the circulation path 51 is connected to the circulation path 51 by waste heat of the engine (heat of the exhaust gas and / or heat of the EGR gas) A boiler 53 for heating and evaporating the working fluid, an inflator 54 for expanding the working fluid supplied from the boil furnace 53 to generate rotational energy, a condenser 54 for condensing the working fluid discharged from the inflator 54, A storage tank 40 for storing the working fluid condensed in the condenser 52 and a pump 5 installed at the downstream side of the storage tank 40 for circulating the working fluid may be installed .

The pump 5 may be coupled to the pump driving motor 10 to constitute a pump-motor assembly. The pump-motor assembly including the pump driving motor 10 is disposed at the lower portion of the storage tank 40 so that the working fluid in the storage tank 40 is discharged to the cooling block 15 side of the pump driving motor 10 by its own weight It can be supplied smoothly.

With this configuration, the low-temperature working fluid condensed in the condenser 52 is stored in the storage tank 40, and the low-temperature working fluid stored in the storage tank 40 by the driving of the pump driving motor 10 is supplied Can be discharged through the outlet 19 of the cooling block 15 after flowing into the cooling channel 17 of the cooling block 15 through the hose 81 and then passing through the cooling channel 17. [ As the pump 5 is pumped by the driving of the pump driving motor 10, the working fluid flows into the inlet 6 of the pump 5 through the discharge hose 82, Can be discharged to the boiler (53) through the outlet (7) of the pump (5) by the pumping operation of the pump (5).

As the low temperature working fluid stored in the storage tank 40 passes through the cooling passage 17 and exchanges heat with the pump driving motor 10, the pump driving motor 10 can be cooled appropriately, while at the same time, The heating fluid can be heated by receiving heat from the pump driving motor 10 and the working fluid is supplied to the boiler 53 in a state in which the working fluid has been heated up in advance so that the heating and evaporating action in the boiler 53 can be performed more efficiently have.

Particularly, since the working fluid of the storage tank 40 is pumped by the pump 5 after passing through the cooling block 15 of the pump driving motor 10, the heat generation tendency of the pump driving motor 10 The flow rate of the working fluid passing through the cooling block 15 of the pump driving motor 10 can also be changed in proportion to the heating tendency in response to the flow rate of the working fluid, The flow rate of the working fluid passing through the flow path 17 can be automatically controlled without requiring a separate control mechanism.

For example, when the number of rotations of the pump driving motor 10 increases, the amount of heat generated by the pump driving motor 10 can be increased along with the flow rate of the working fluid due to the pumping operation of the pump 5, The pump driving motor 10 can be properly cooled in accordance with the increased calorific power. When the number of revolutions of the pump driving motor 10 is reduced, the amount of heat generated by the pump driving motor 10 can be reduced along with the flow rate of the working fluid due to the pumping operation of the pump 5, The flow rate of the working fluid passing therethrough is also reduced, so that the pump driving motor 10 can be cooled appropriately in accordance with the reduced heating value.

7 is a view showing a structure in which a pump driving motor 10 according to the present invention is applied to a refrigerant cycle 60 having a pump.

According to the embodiment of Fig. 7, the pump driving motor 10 can be applied to the refrigerant cycle 60, and the pump 5 for circulating the refrigerant in the refrigerant cycle 60 is driven by the pump driving motor 10 And the pump driving motor 10 can be appropriately cooled by the refrigerant before it is introduced into the pump 5. [

7, the refrigerant cycle 60 includes a circulation path 61 through which the refrigerant circulates. The circulation path 61 includes an evaporator 63 for heating and evaporating the refrigerant, A condenser 62 for condensing the refrigerant discharged from the compressor 64; a storage tank 40 for storing the refrigerant condensed in the condenser 62; a storage tank 40 for storing the refrigerant condensed in the condenser 62; A pump 5 installed on the downstream side of the refrigerant circulating the refrigerant, and the like.

A pump-motor assembly can be configured by coupling the pump drive motor 10 to the pump 5. The pump-motor assembly including the pump driving motor 10 is disposed at the lower portion of the storage tank 40 so that the refrigerant in the storage tank 40 is smoothly moved toward the cooling block 15 side of the pump driving motor 10 by its own weight. .

With this configuration, the low-temperature refrigerant condensed by the condenser 62 is stored in the storage tank 40, and the low-temperature refrigerant stored in the storage tank 40 is discharged from the supply hose 40 by driving the pump- The refrigerant can be discharged through the outlet 19 of the cooling block 15 after passing through the cooling passage 17 after the refrigerant flows into the cooling passage 17 of the cooling block 15 through the passage 81 . As the pump 5 is driven by the operation of the pump driving motor 10, the refrigerant flows into the inlet 6 of the pump 5 through the discharge hose 82 and the pump 5 Through the outlet 7 of the pump 5 and can be supplied to the evaporator 63.

As the working fluid of low temperature stored in the storage tank 40 passes through the cooling passage 17 and exchanges heat with the pump driving motor 10, the pump driving motor 10 can be cooled appropriately, As the refrigerant is supplied to the evaporator 63 in a state where the temperature of the refrigerant has been raised in advance, the heating and evaporating action in the evaporator 63 can be more efficiently performed.

Particularly, since the refrigerant of the storage tank 40 is pumped by the pump 5 after passing through the cooling block 15 of the pump driving motor 10, the heat generation tendency of the pump driving motor 10 The flow rate of the refrigerant passing through the cooling block 15 of the pump driving motor 10 may be changed in proportion to the heat generation tendency in proportion to the flow rate of the refrigerant, ) Can be automatically controlled without requiring a separate control mechanism.

For example, if the number of revolutions of the pump driving motor 10 increases, the amount of heat generated by the pump driving motor 10 can be increased together with the flow rate of the refrigerant due to the pumping operation of the pump 5, The pump drive motor 10 can be properly cooled in accordance with the increased calorific value. When the number of revolutions of the pump driving motor 10 decreases, the amount of heat generated by the pump driving motor 10 can be reduced along with the flow rate of the refrigerant due to the pumping operation of the pump 5, The pump driving motor 10 can be cooled appropriately in accordance with the reduced heating value.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. .

5: Pump 10: Motor for pump drive
15: cooling block 17: cooling channel
40: Storage tank 43: Storage space

Claims (8)

A pump drive motor cooling apparatus for cooling a pump drive motor for driving a pump installed on a circulation path of a fluid cycle,
A cooling block for cooling the pump driving motor;
A cooling passage formed in the cooling block, through which the fluid circulating on the circulation path of the fluid cycle passes; And
And a storage tank connected to supply a fluid to the cooling channel,
And the cooling channel is communicatively connected to the pump. The method according to claim 1,
And the cooling block is installed so as to surround at least a part of the outer surface of the pump driving motor. The method according to claim 1,
Wherein the cooling passage is formed between the cooling block and the pump driving motor. The method according to claim 1,
Wherein the storage tank is installed on a circulation path of the fluid cycle to store a fluid circulating the circulation path. The method according to claim 1,
Wherein the cooling block has at least one partition wall forming a flow direction of the fluid in the cooling passage. The method according to claim 1,
And a supply hose is connected between an inlet of the cooling block and an outlet of the storage tank. The method according to claim 1,
And a discharge hose is connected between the outlet of the cooling block and the inlet of the pump. The method according to claim 1,
Wherein the pump and the pump driving motor are arranged in a line so as to constitute a pump-motor assembly.

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