KR101695519B1 - Holding device of temperature sensor for automobile-evaporator - Google Patents

Abstract

The present invention relates to a temperature sensor holding device for fixing a thermistor sensor to an evaporator for a vehicle, and more particularly to a temperature sensor holding device for fixing a temperature sensor holding device for fixing to a thermally conductive pin case (5) And a contact piece 20 which is integrally coupled to the holder 10 and which connects the temperature sensor 2 and the thermally conductive pin case 5 of the evaporator in contact with each other, 20 is provided with a sensor coupling portion for coupling the temperature sensor 2 at a position spaced apart from the thermally conductive pin case 5 so that the temperature sensor 2 performs both direct and indirect sensing operations by convection and contact, It is easy to disassemble and assemble the sensor during A / S, and it is possible to provide both direct and indirect temperature sensing, thus providing excellent sensing capability of the temperature sensor.

Description

TECHNICAL FIELD [0001] The present invention relates to a temperature sensor holding device for a vehicle evaporator,

The present invention relates to a temperature sensor holding device for fixing a thermistor sensor to an evaporator for a vehicle, and more particularly, to a temperature sensor holding device for holding a temperature sensor in a holder and fixing the holder to an evaporator The contact piece is brought into direct contact with the thermally conductive pin case of the evaporator and the contact piece is brought into direct contact with the thermal conductive pin case through the convection, And a temperature sensor holding device for a vehicle evaporator, which is capable of sensing temperature by direct contact with the temperature sensor.

2. Description of the Related Art Generally, in an air conditioning system of an air conditioner for a vehicle, a compressor, a condenser, a receiver dryer, an expansion valve, and an evaporator are sequentially connected by a refrigerant pipe, and the compressor is driven by the engine to circulate the refrigerant.

In this air conditioner system, refrigerant compressed at a high temperature and a high pressure in a compressor passes through a condenser and is heat-exchanged with a surrounding convection to change into a liquid state. The liquefied refrigerant passes through a receiver dryer to remove impurities, While changing to low temperature gas. The low-temperature refrigerant passes through the evaporator and is cooled while being heat-exchanged with the surrounding convection. The cooled convection is discharged to the inside of the vehicle by the blower. The refrigerant in the low-temperature gaseous state passing through the evaporator is again sent to the compressor, , And the refrigerant compressed by the high pressure is circulated.

During the circulation of the refrigerant, the condensation water is frozen due to the difference between the evaporation temperature and the external temperature difference on the surface of the evaporator, thereby lowering the heat exchange efficiency of the evaporator.

Accordingly, when a temperature sensor is installed in the evaporator and the sensed temperature falls below a predetermined value (0 ° C), the operation of the compressor and the air conditioning system is stopped. If the sensed temperature rises again to a set value (about 4 ° C) The air conditioning system is operated so that the evaporator does not freeze after operation, thereby preventing the surface of the evaporator from freezing in advance.

The temperature sensor is attached to the evaporator. Since the temperature sensor is directly inserted into the thermally conductive pin case of the evaporator and the temperature sensor is attached to the holder and mounted to the thermally conductive pin case, the temperature sensor is separated from the thermally conductive pin case There was a way.

However, in the above-mentioned electronic system, there is a problem in that the temperature sensor can not be easily disassembled and assembled at the time of A / S, and the latter system has an advantage of easy disassembly and assembly at the time of A / S of the temperature sensor, Since the sensing is performed indirectly by the convection in the non-contact state, there is a problem that the temperature sensing ability is greatly deteriorated and the sensor operates.

Public utility model room 2000-0002961 Patent Document 1:

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a heat- The contact piece is brought into direct contact with the thermally conductive pin case of the evaporator and the contact piece is brought into direct contact with the holder so that both the indirect temperature sensing through the convection and the direct temperature sensing by the contact are possible, The purpose is to provide excellent ability.

An object of the present invention is to provide a temperature sensor capable of being constantly coupled to a fixed position by simply inserting a temperature sensor into a sensor coupling portion of a holder and a contact piece, thereby providing excellent coupling workability.

The present invention is characterized in that it comprises a holder having a fixing part for fixing to a thermally conductive pin case of an evaporator, a contact piece integrally coupled to the holder and contacting the thermally conductive pin case of the evaporator with the temperature sensor, And a sensor coupling portion for coupling the temperature sensor to the thermal conductive pin case at a spaced apart position is formed so that the temperature sensor performs both direct and indirect sensing operations by convection and contact.

The sensor coupling portion is formed as a sensor insertion hole for inserting a temperature sensor into an upper portion of the contact piece to be brought into contact with the sensor, and a sensor assembly for forming a tapered hole for inserting and inserting a temperature sensor into and from the sensor insertion hole, And the guide and the stopper for stopping the tip of the temperature sensor are formed opposite to each other.

The sensor connecting part is integrally formed with a sensor inserting hole formed on an upper portion of the contact piece and a sensor assembling guide formed by cutting and bending the inserting hole to taper outwardly in front of the sensor inserting hole and inserting and guiding a temperature sensor, And a stop hole for inserting and supporting the tip end of the temperature sensor by a smaller diameter than the sensor inserting hole is formed in the rear.

The present invention is not only easy to disassemble and assemble the temperature sensor at the time of A / S by connecting the temperature sensor to the holder and mounting the holder to the heat conductive pin case of the evaporator by the joint fixing part, The contact piece is brought into direct contact with the thermally conductive pin case of the temperature sensor and the evaporator so that both the indirect temperature sensing through the convection and the direct temperature sensing by the contact are possible.

It is also an object of the present invention to provide an excellent coupling workability since the temperature sensor can be uniformly inserted into the sensor body by simply inserting the temperature sensor into the sensor coupling portion of the contact piece.

1 is a front perspective view showing an embodiment of a holding device according to the present invention;
Figure 2 is a front view of Figure 1;
3 is a side view of Fig.
4 is an exploded view of Fig.
Fig. 5 is an installation view of Fig. 1; Fig.
6 is an enlarged cross-sectional view of the main part of Fig. 5;
7 is a front perspective view showing another embodiment of the holding device of the present invention.
8 is a side view of Fig.
Fig. 9 is a front view of the state in which the temperature sensor is coupled to Fig. 7; Fig.

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

1 to 6, a temperature sensor holding apparatus for a vehicle evaporator according to the present invention includes a holder 10 having a fixed mounting portion 12 for coupling to a thermally conductive pin case 5 of an evaporator,

And a contact piece 20 which is integrally coupled to the holder 10 and which connects the temperature sensor 2 and the thermally conductive pin case 5 of the evaporator in a contact manner and the contact piece 20 is provided with a thermally conductive pin case 5 So that the temperature sensor 2 performs both the direct and indirect sensing operations by the convection and the contact.

At this time, the holder 10 and the contact piece 20 may be integrally formed by an assembly method or integrally formed by an insert molding method.

The fixing part 12 of the holder 10 is formed in the form of a wedge 13 so as to be inserted into the evaporator thermally conductive pin case 5 and has a plurality of latching protrusions 13a for latching in both sides of the wedge. And a cutting groove (not shown) is formed on the tip of the wedge so as to perform a tension operation in the width direction.

The contact piece 20 is preferably made of a copper material having a high thermal conductivity for heat transfer.

The sensor engaging portion 30 is formed as a sensor inserting hole 21 for inserting and connecting the temperature sensor 2 to the upper portion of the contact piece 20, The sensor assembly guide 15 for forming the taper hole 15a and the stopper 16 for stopping and supporting the tip of the temperature sensor 2 are formed opposite to each other so as to guide the temperature sensor 2 before and after the sensor insertion hole 21, .

The upper sensor insertion hole 21 of the contact piece 20 is formed by opening a notched portion 21a cut in the upper and lower sides in a semicircular shape so as to be opposed to both sides and the lower portion is formed to have elastic contact with the thermally conductive pin case 5 of the evaporator And is configured to form a contact portion 22 that protrudes and forms a tension contact projection 22a that is laterally opened in a state of being vertically cut.

Reference numeral 3 denotes a cap coupled to the front of the temperature sensor.

Hereinafter, the operation and operation of the present invention will be described.

The temperature sensor 2 is first coupled to the sensor coupling portion 30 on the contact piece 20 integrally coupled to the holder 10 of the present invention.

That is, since the temperature sensor 2 is inserted and guided into the tapered hole 15a of the sensor assembly guide 15, the temperature sensor 2 is guided by the sensor insertion hole 21 located above the contact piece 20 positioned in front of the sensor assembly guide 15, Insert the sensor (2).

At this time, the stopper 16 of the holder is positioned in front of the sensor insertion hole 21 to stop the temperature sensor 2, thereby coupling the temperature sensor 2 to a predetermined position.

In this way, the temperature sensor 2 is attached to the thermally conductive pin case 5 of the evaporator in a state where the temperature sensor 2 is engaged.

A wedge 13 formed by protruding a plurality of locking protrusions 13a which engage with both sides of the fixed mounting portion 12 of the holder 10 is provided on the heat conducting pin case 5 And inserts them.

At this time, the contact portion 22 of the lower part of the contact piece 20 integrally coupled to the holder 10 is connected to the thermally conductive pin case 5 by contact.

Particularly, the contact portion 22 protrudes laterally from the upper surface of the thermal conductive pin case 5 in a state where the thermal conductive pin case 5 is cut away.

The present invention thus mounted is mounted on the thermally conductive pin case 5 by the fixing portion 12 of the holder 10 and the temperature sensor 2 is inserted into the sensor insertion hole 21 of the holder 10 The temperature sensor 2 can be easily detached from the sensor insertion hole 21 during the A / S operation of the temperature sensor, and can be easily reassembled as described above during reassembly. will be.

In addition, the temperature sensor 2 can be installed so as to be spaced apart from the thermally conductive pin case 5 to allow indirect sensing through convection, and the temperature sensor 2 and the thermally conductive pin case 5 can be directly Since direct temperature sensing can be performed by direct contact and indirect temperature sensing, the temperature sensing capability of the temperature sensor 2 is superior to that of the conventional art.

7 to 9, in the same manner as in the above-described embodiment, the holder 10 and the contact piece 20 are formed in the holder 10, And the upper part of the contact piece 20 is assembled.

A sensor coupling portion 30 'for coupling the temperature sensor 2 is formed on the contact piece 20 so that the temperature sensor 2 performs both direct and indirect sensing operations by convection and contact.

Particularly, the sensor engaging portion 30 'is formed on the contact piece 20 in such a manner that the sensor inserting hole 21' and the sensor inserting hole 21 ' 2 is formed integrally with the holder 10 and the temperature sensor 2 is formed in the holder 10 in a size smaller than the sensor inserting hole 21 'in the rear of the sensor inserting hole 21' And a stop hole 16 'for inserting and supporting the tip end of the stopper 16'.

A contact portion 22 'is formed on the lower portion of the contact piece 20 so as to protrude and form tension contact protrusions 24 and 24 which are cut out on both sides and protrude outward so as to contact the thermally conductive pin case 5 of the evaporator. ).

The fixing part 11 of the holder 10 is structured so as to form locking protrusions 14 and 14 instead of a wedge so as to engage with the thermally conductive pin case 5 of the evaporator.

The present invention is characterized in that a temperature sensor 2 is attached to a sensor engaging portion 30 'on a contact piece 20 integrally coupled to a holder 10 and the temperature sensor 2 is disposed outside the sensor inserting hole Inserted and guided by the tapered sensor assembly guide 23 and inserted into the sensor insertion hole 21 '.

At this time, a stop hole 16 'having a smaller diameter than the sensor inserting hole is formed in the rear of the sensor inserting hole 21' so that the temperature sensor 2 is partly inserted and fixed in the inserted state.

When the temperature sensor 2 is coupled to the holder 10, the holder 10 is attached to the thermally conductive pin case 5 of the evaporator by the fixing part 11 in the form of the locking projections 14 and 14 of the holder 10, The contact portion 22 'under the integrally coupled contact piece 20 is in contact with the thermally conductive pin case 5.

Particularly, the contact portion 22 'is such that the tension contact protrusions 24 and 24, which are formed by bending and protruding outward on both sides, are elastically contacted with the thermally conductive pin case 5 of the evaporator.

The present invention to be mounted as described above is mounted on the thermally conductive pin case 5 by the fixed mounting portion 12 of the holder 10 and the sensor insertion hole 21 ' The temperature sensor 2 can be easily detached from the sensor inserting hole 21 'during A / S of the temperature sensor, and can be easily reassembled as described above during reassembly. It will be possible.

In addition, the temperature sensor 2 can be installed so as to be spaced apart from the thermally conductive pin case 5 to allow indirect sensing through convection, and the temperature sensor 2 and the thermally conductive pin case 5 can be directly Since direct temperature sensing can be performed by direct contact and indirect temperature sensing, the temperature sensing capability of the temperature sensor 2 is superior to that of the conventional art.

2: temperature sensor 5: thermally conductive pin case
10: Holder 15, 23: Sensor assembly guide
15a: taper hole 16: stopper
16 ': stop ball 20: contact piece
21 and 21 ': sensor insertion holes 22 and 22'
22a, 24: a tension contact protrusion 30, 30 '

Claims (5)

A holder 10 having a fixed mounting portion 12 for coupling to a thermally conductive pin case 5 of the evaporator,
And a contact piece 20 which is integrally coupled to the holder 10 and which connects the temperature sensor 2 and the thermally conductive pin case 5 of the evaporator in a contact manner and the contact piece 20 is provided with a thermally conductive pin case 5 And the temperature sensor 2 is configured to perform both the direct and indirect sensing operations by the convection and the contact,
The sensor connecting part is formed as a sensor inserting hole 21 for inserting a temperature sensor 2 into an upper portion of the contact piece 20 to be brought into contact with the inserting hole 21. The holder 10 is provided with a temperature sensor A sensor assembly guide 15 for forming a taper hole 15a for guiding the sensor 2 into the sensor insertion hole 21 and a stopper 16 for stopping and supporting the tip of the temperature sensor 2,
The upper sensor insertion hole 21 of the contact piece 20 is formed by vertically cutting the notched portion 21a in a semicircular shape so as to oppose to the both sides of the upper sensor insertion hole 21. The lower portion of the upper sensor insertion hole 21 is vertically and downwardly engaged with the thermally conductive pin case 5 of the evaporator And a contact portion (22) for protruding and forming a tension contact protrusion (22a) that is laterally opened in the cutaway state is formed. delete delete delete A holder (10) having a fixing part (11) for fixing to a thermally conductive pin case (5) of an evaporator,
And a contact piece 20 which is integrally coupled to the holder 10 and which connects the temperature sensor 2 and the thermally conductive pin case 5 of the evaporator in a contact manner and the contact piece 20 is provided with a thermally conductive pin case 5 And the temperature sensor 2 is configured to perform both the direct and indirect sensing operations by the convection and the contact,
The sensor connecting portion is cut out and bent so as to taper outwardly in front of the sensor inserting hole 21 'and the sensor inserting hole 21' above the contact piece 20 to insert and guide the temperature sensor 2 The sensor assembly guide 23 is integrally formed in the holder 10 and the tip of the temperature sensor 2 is inserted into and supported by the holder 10 in a size smaller than the sensor insertion hole 21 ' And a stop hole 16 '
A contact portion 22 'protruding and forming the tension contact protrusions 24 and 24, which protrude from both sides of the contact piece 20 so as to protrude and protrude outward from both sides and contact the thermally conductive pin case 5 of the evaporator, And the temperature sensor holding device is configured to form the temperature sensor holding device.

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