KR101499365B1 - Recirculating Heat Exchanger for High Voltage Motor - Google Patents

Abstract

The present invention relates to a re-circulating heat exchanger for a high voltage motor. For this, the present invention includes: a heat exchanger body, an outer air inlet which is formed on one side of the heat exchanger body to input outer air, an outer air discharge part which is formed on the other side of the heat exchanger body to discharge the outer air whose heat is exchanged, a heat exchanging part which is formed in the heat exchanger body to exchange heat, and a re-circulating guide part which is connected to the outer discharge part and an inner air inlet and outlet formed on both sides of the bottom of the heat exchanger body with the heat exchanger and surrounds the surface of the heat exchanger body. Therefore, the present invention improves an overall heat exchange rate and maximally reduces an output noise discharged to the air and an input noise generated when the outer air is inputted.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a recirculating heat exchanger for a high-

The present invention relates to a recirculating heat exchanger of a high-voltage electric motor, and more particularly, it relates to a recirculating heat exchanger for a high-voltage electric motor in which heat is exchanged in a heat exchanger body, and then the air discharged into the atmosphere is discharged via a surface of a heat exchanger body.

Generally, in order to prevent overheating of the high-voltage motor, an inner / outer fan is installed on the motor shaft to cool the rotor core and the stator core, which generate heat, so that an air flow is generated due to a pressure difference generated during rotation.

In a high-voltage motor, a shaft is inserted into a center of a motor frame by a load-side bearing and a half-load-side bearing, and a rotor bar and a stator coil are fixed to the outside of the shaft.

A stator core and a rotor core are provided inside the frame, a heat exchanging housing is provided on the outside, and an internal fan is provided on an upper part of the frame to generate air volume required for cooling the high voltage electric motor.

As shown in the drawing, the heat exchange housing 90 of the conventional high-voltage electric motor is provided with an outside air inlet 911 through which the outside air flows into one side of the housing body 91, A corresponding outside air outlet 912 is formed on the other side of the housing body 91 and a plurality of heat exchange pipes 92 are provided in the housing body 91 in the longitudinal direction.

A lower portion of the housing body 91 provided with the heat exchange pipe 92 is provided with an inflow inlet 913 through which the increased temperature air flows and an inflow outflow outlet 914 through which the cooled inside air flows down.

A noise reduction unit 93 is provided on the inner side of the outside air inlet 911 formed on the housing body 91 and on the outside of the outside air outlet 912.

The high-voltage electric motor 70 is configured such that the internal air whose temperature has been raised as the rotor core 71 is rotated is rotated by the rotation of the internal fan 72 to flow into the internal air inlet port 913 and then circulated through the inside air outlet 914 via the heat exchange pipe 92. [

In this process, the outside air flows into the housing body 91 through the outside air inlet 911 and then exchanges heat in the course of passing through the heat exchange pipe 92 to cool the air having the increased temperature. The noise is reduced by the noise reduction unit 93 in the process of being discharged through the outside air outlet 912.

Meanwhile, in the process of entering the outside air through the outside air inlet 911, since the inside shape of the outside air inlet 911 is close to a nearly right angle, it is easy to manufacture but is directly related to the cooling performance due to the inflow resistance of the heat exchange pipe 92 There is a problem that the flow rate of the outside air is reduced.

In addition, the outside air outlet 912 also has a problem in that the outflow noise is not reduced by colliding at a right angle in the process of flowing out to the atmosphere after the heat exchange.

Since the heat exchanging is performed only in the interior of the housing body 91, that is, the portion where the heat exchange pipe 92 is provided, the inside of the housing body 91 is still kept in contact with the air whose temperature is raised, There was another problem of losing.

The present invention reduces the inflow resistance of the outside air to reduce the inflow noise generated during the inflow, and also minimizes the outflow noise discharged to the atmosphere. Further, the surface of the heat exchanger body can be cooled, So that the rate can be increased.

The present invention relates to a heat exchanger comprising: a heat exchanger body (10); An outside air inlet 20 through which outside air flows into one side of the heat exchanger body 10; An outside air discharge port 30 provided at the other side of the heat exchanger body 10 so as to discharge heat-exchanged outside air; A heat exchanging part 40 provided inside the heat exchanger body 10 so as to be heat-exchanged; (50) (51) provided on both lower sides of the heat exchanger body (10) provided with the heat exchanging part (40); And a recirculating guide unit 60 connected to the outside air outlet 30 and surrounding the surface of the heat exchanger body 10.

The flow path resistance reducing portion 21 is formed in a curved shape and the flow path resistance reducing portion 21 is formed in a curved shape. 21 is provided with an imprint material 22 inside.

The outside air outlet 30 is formed in the outer space 12 partitioned by the partition 11 inside the body 10 of the heat exchanger.

The heat exchanging unit 40 includes a heat exchanger body 10 and a plurality of hollow pipes 41 arranged horizontally from one side to the other side of the heat exchanger body 10, (43) is formed between the upper end of the support partition wall (42) provided in the middle of the hollow pipe (41) and the upper inner side of the heat exchanger body (10) do.

The recirculation guide portion 60 is formed by an inner partition wall 61 and an outer partition wall 62 spaced apart from the other side surface of the heat exchanger body 10 and the side surface, 64 are formed on the outer peripheral surface of the inner partition wall 61. A portion of the inner partition wall 61 is removed to form a U-turn flow path 65 connecting the outer flow path 64 and an outer air discharge opening 30 is formed at the end of the outer flow path 64 .

And a plurality of cooling fins 66 having a longitudinal direction are formed on the surface of the heat exchanger body 10 positioned inside the inner flow path 63. [

In the present invention, after the heat exchange is performed inside the heat exchanger body, the outside air discharged to the atmosphere is discharged through the surface of the heat exchanger body, thereby achieving an effect of increasing the heat exchange rate as a whole.

In addition, it is possible to reduce the leakage noise emitted to the atmosphere to the utmost.

In addition, a curved passage resistance reducing portion is formed in the inlet port, so that the inflow noise generated during the inflow of the outside air can be further reduced.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing an example of a recirculation heat exchanger of a high-voltage electric motor according to the prior art; FIG.
2 is a perspective view illustrating a recirculation heat exchanger of a high-voltage electric motor according to the present invention.
3 is a bottom perspective view showing a recirculating heat exchanger of a high-voltage electric motor according to the present invention.
FIG. 4 is an exploded perspective view showing a part of a recirculating heat exchanger of a high-voltage electric motor according to the present invention, inside and outside. FIG.
4 is a longitudinal sectional view showing a recirculating heat exchanger of a high-voltage electric motor according to the present invention,
5 is a cross-sectional view illustrating a recirculation heat exchanger of a high-voltage electric motor according to the present invention,

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described with reference to the accompanying drawings.

2 to 5, the recirculation heat exchanger of the high-voltage electric motor according to the present invention includes a heat exchanger body 10, an outside air inlet 20, an outside air outlet 30, a heat exchanger 40, (50) (51) and a recirculating guide portion (60).

The recirculation type heat exchanger includes an outside air inlet 20 through which the outside air is introduced into one side of the heat exchanger body 10 and an outside air outlet 30 through which heat exchanged outside air is discharged to the other side of the heat exchanger body 10, And is provided so as to correspond to the outside air inlet 20.

The outside air inlet 20 is formed to have a curved shape with a function of reducing the noise due to resistance reduction by forming the passage resistance reducing portion 21 on the inner side surface of the corner where the outside air flows and the direction is changed.

The channel resistance reducing portion 21 is provided with a sound damper 22 so as to further reduce noises.

The outside air discharge port 30 is formed in the outer space portion 12 partitioned by the partition 11 inside the heat exchanger body 10 so that the outside air exchanged through the heat exchanging portion 40 is discharged to the atmosphere So that exhaust noise is also reduced.

A heat exchange unit 40 is provided to heat exchange inside the heat exchanger body 10 and an inlet 50 and an outlet 50 are provided on both sides of a lower portion of the heat exchanger body 10 having the heat exchange unit 40 51 so that the high-temperature internal air can easily flow into the heat exchanger body 10 and can be discharged while being cooled.

The heat exchanging part 40 is arranged inside the heat exchanger body 10 so that the cross-sectional area of the heat exchanging part 40 can be maintained as wide as possible by horizontally arranging the hollow pipes 41 horizontally from one side of the heat exchanger body 10 to the other side. And flows in the form of a jig jig in the process of moving the inflowing air toward the air outlet 51 so as to increase the heat exchange rate.

Both end portions of the hollow pipe 41 are supported so as to be exposed through the heat exchanger body 10 and a supporting partition wall 42 is provided in the middle of the hollow pipe 41 so that the plurality of hollow pipes 41 are stable And the upper end of the support partition wall 42 is removed between the upper end of the support partition wall 42 and the upper inner side of the heat exchanger body 10, The heated inside air introduced through the inlet port 50 can be moved toward the outlet port 51 toward the inside of the heat exchanger body 10. [

The recirculation guide unit 60 is connected to the outside air discharge port 30 and is provided to surround the surface of the heat exchanger body 10 so that the circulation guide unit 60 can be cooled by delaying the discharged outside air.

The recirculating guide unit 60 is connected to the inner partition wall 61 by the inner partition wall 61 and the outer partition wall 62 which are spaced apart from the other surface of the heat exchanger body 10 and the side surface, An inner passage 63 is formed between the side surfaces of the base body 10 and an outer passage 64 is formed between the inner partition wall 61 and the outer partition wall 62.

A portion of the inner partition wall 61, that is, a portion where the outside air inlet 20 is formed is removed to form a U-turn oil passage 65 connecting the inner passage 63 and the outer passage 64. The outer passage 64, The outside air discharge port 30 is formed at the end of the air discharge opening 30.

On the other hand, a plurality of cooling fins 66 having a longitudinal direction are formed on the surface of the heat exchanger body 10 positioned inside the inner flow path 63 to facilitate heat exchange on the surface of the heat exchanger body 10 .

The recirculated heat exchanger of the high-voltage electric motor is operated such that the air whose temperature is raised as the rotor core 71 of the high-voltage electric motor 70 is rotated is rotated by the rotation of the internal fan 72 to the lower portion of the heat exchanger body 10 Heat exchange is carried out while passing through the hollow pipe 41 of the heat exchanging part 40 in the course of flowing into the heat exchanger body 10 through the inflow inlet 50 formed in the heat exchanger 40 and moving toward the inflow outflow port 51 .

Next, the air cooled through the heat exchange is changed in the moving direction while passing through the partition-free space portion 43 formed at the upper end of the support partition wall 42, flows out through the internal air outlet port 51, It is possible to prevent the high-voltage electric motor 80 from being overheated.

At the same time, the air flow resistance is reduced by the flow path resistance reducing part 21 having a curved shape in the process of flowing the outside air through the outside air inlet 20 formed in the heat exchanger body 10, ), The noise generated during the inhalation process is minimized.

Next, the outside air flowing into the outside air inlet 20 is heat-exchanged in the course of passing through the inside of the hollow pipe 41 of the heat exchanger 40, and the outside air having undergone heat exchange is discharged through the end of the hollow pipe 41 Heat exchange is performed with the surface of the heat exchanger body 10 through the inner passage 63 provided by the inner partition wall 61 which is spaced from the other surface of the heat exchanger body 10 and the side surface, The outside of the base body 10 can be cooled. At this time, the cooling rate can be further increased by the plurality of cooling fins (66) having the longitudinal direction on the surface of the heat exchanger body (10) positioned inside the inner flow path (63).

The air that has cooled the surface of the heat exchanger body 10 flows in the flow direction toward the inlet side of the outer flow path 64 through the inner flow path 65 formed at the end of the inner flow path 63 after passing through the inner flow path 63 And is then discharged to the atmosphere through the outside air discharge port 30 formed at the end of the outer flow path 64. Thereby, the discharge noise is further reduced, and the cooling rate can be further increased do.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

10: heat exchanger body 11: partition wall
12: outer space part 20: outside air inlet
21: Reduced flow resistance part 22: Damaged sound
30: Outside air outlet 40: Heat exchanger
41: hollow pipe 42: support bulkhead
43: bulkhead-free space 50, 51: inflow and outflow
60: recirculation guide portion 61: inner barrier rib
62: outer barrier rib 63:
64: Outer channel 65: U-turn channel
66: cooling pin

Claims (6)

A heat exchanger body (10);
An outside air inlet 20 through which outside air flows into one side of the heat exchanger body 10;
An outside air discharge port 30 provided at the other side of the heat exchanger body 10 so as to discharge heat-exchanged outside air;
A heat exchanging part 40 provided inside the heat exchanger body 10 so as to be heat-exchanged;
(50) (51) provided on both lower sides of the heat exchanger body (10) provided with the heat exchanging part (40); And
And a recirculating guide unit (60) connected to the outside air outlet (30) and surrounding the surface of the heat exchanger body (10). The method according to claim 1,
The flow path resistance reducing portion 21 is formed in a curved shape and the flow path resistance reducing portion 21 is formed at a corner where the flow direction is changed. And a damper (22) is provided inside the high-voltage electric motor (10). The method according to claim 1,
Wherein the outside air discharge port (30) is formed in an outer space part (12) partitioned by a partition wall (11) inside a heat exchanger body (10). The method according to claim 1,
The heat exchanging unit 40 has a hollow pipe 41 arranged horizontally from one side of the heat exchanger body 10 to the other side and both ends of the hollow pipe 41 pass through the heat exchanger body 10 (43) is formed between the upper end of the support partition wall (42) provided in the middle of the hollow pipe (41) and the upper inside of the heat exchanger body (10) Recirculating heat exchanger of electric motor. The method according to claim 1,
The recirculating guide unit 60 is connected to the inner passage 63 and the outer passage 64 by an inner partition wall 61 and an outer partition wall 62 which are spaced apart from the other surface of the heat exchanger body 10 and the side surface, A portion of the inner partition wall 61 is removed to form a U-turn flow passage 65 to which the outer flow passage 64 is connected, and an outer air discharge opening 30 is formed at an end of the outer flow passage 64 Recirculating heat exchanger of high-voltage electric motor 6. The method of claim 5,
Wherein a plurality of cooling fins (66) having a longitudinal direction are formed on the surface of the heat exchanger body (10) positioned inside the inner flow path (63).

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