KR101146313B1 - Ptc heater that use heater module and this - Google Patents

Abstract

PURPOSE: A heat module and a PTC(Positive Temperature Coefficient) heater using the same are provided to improve a quality of the PTC heater by maintaining pressures acted on an inner side of a radiant heat unit and the heat module for a long time. CONSTITUTION: A heat module comprises PTC elements, an insulating structure(12), a ceramic insulator, an anode terminal plate(13), and a cover plate(13). The insulating structure comprises a plurality of mounting holes. The PTX elements are inserted into the insulating structure from one side of the mounting holes. The ceramic insulator is inserted correspondently to the PTC elements from the other side of the mounting holes. The ceramic insulator secludes a contact of the cover plate with the anode terminal plate. The anode terminal plate is connected to the insulating structure in a longitudinal direction. The anode terminal plate is contacted with a single-side of the ceramic insulator and the PTC elements. The anode terminal plate transfers power source(+) to the PTC elements. The cover plate surrounds the PTC elements, the ceramic insulator, and the insulating structure. The cover plate transfers power source (-) with being contacted with the other side of the PTC elements.

Description

Heater module and PTC heater using the same {PTC heater that use heater module and this}

The present invention relates to a heater using a Positive Temperature Coefficient (PTC) element, and more particularly, a heater module and a heater module pressurized structure which improves the coupling reliability by improving the coupling structure of the PTC heater, and using the same. It relates to a PTC heater.

In general, the PTC heater using the PTC element may be used as an auxiliary means of the heater unit constituting the vehicle air conditioner, or may be configured as a separate heating device alone.

In particular, diesel vehicles have a lot of problems in winter driving due to poor initial heating performance when the engine is heated by heat of the engine. Recently, PTC heaters can be heated from the beginning of startup using PTC heaters. 1 includes a heater module 100, a heat dissipation unit 200, a side frame 300, and an end holder 400 as shown in FIG. 1.

The heater module 100 is a U-shaped fixed frame 101, the insulating frame 102 is coupled in the longitudinal direction in the fixed frame 101, fixed in the longitudinal direction of the insulating frame 102 and the power (+) A positive electrode terminal plate 103 for providing a, PTC element 104 coupled to the insulating frame 102 via the positive electrode terminal plate 103, the cover portion coupled to the open side of the fixed frame 101 105.

In addition, the heat dissipation unit 200 includes a heat dissipation fin 201 and a support plate 202 for supporting the heat dissipation fin 201.

On the other hand, the heater module 100 and the heat dissipation unit 200 together with the negative electrode terminal plate 106 for providing a power (-) to the PTC element 104 to form a side by side arrangement without a separate fixing means, an example Assuming that three heater modules 100 are arranged as, the heater modules 100 are arranged side by side with a plurality of (or single) heat dissipating parts 200 and a plurality of negative electrode terminal plates 500. As described above, the heater module 100 and the heat dissipation unit 200 and the negative electrode terminal plate 500 which are arranged side by side without a separate fixing means are fixed by the side frame 300 and the end holder 400. .

That is, the side frame 300 and the end holder 400 supports the heater module 100 and the heat dissipation unit 200 and the negative electrode terminal plate 500 which are arranged side by side to prevent separation, as well as the side by side The structure pressurizes the heater module 100, the heat dissipation unit 200, and the negative electrode terminal plate 500, which are arranged, and supplies the positive and negative powers to the PTC device 104 to the end holder 400. The common terminal (not shown) for the configuration, and the side frame 300 is typically composed of a bar-shaped structure.

However, since both ends of the side frame 300 applied to the conventional PTC heater are coupled to the end holder 400, the heater module 100 and the heat dissipation unit 200 and the negative electrode terminal plate 500 are arranged side by side. Since the pressing force does not act inward, the arrangement of the heater module 100, the heat dissipation unit 200, and the negative electrode terminal plate 500 may not be maintained firmly, and a problem may occur.

In addition, the insulating frame 102 constituting the heater module 100, the positive electrode terminal plate 103 and the PTC element 104 is coupled in the fixed frame 101 of the U-shape of the fixed frame 101 Since the opening side is covered by the cover part 105, there is a problem that the coupling force between the insulating frame 102, the positive electrode terminal plate 103, and the PTC element 104 is also poor.

Accordingly, in the related art, a pressing protrusion (or hook) is applied to the side frame 300 so as to apply a pressing force to the inside of the heater module 100 and the heat dissipating unit 200 and the negative electrode terminal plate 500 which are arranged side by side. To form.

However, a method of providing a pressing force to the inside of the heater module 100, the heat dissipation unit 200 and the negative electrode terminal plate 500 by forming a pressing protrusion (or hook) in the side frame 300 as described above is a side frame ( 300 is a structure in which the protrusion is bent by bending the section cut in the c-shape, and this also causes a change in the height of the protrusion according to the use period of the pressing protrusion (or hook), and thus the above-described problem In particular, the pressing protrusion may have a different effect on the coupling force between the insulating frame 102, the positive electrode terminal plate 103, and the PTC device 104, which are protected by the fixing frame 101 and the cover part 105. Since it does not give, the limit is bound to increase the bonding force of the heater module 100.

That is, the method of pressing the heater module 100, the heat dissipating unit 200, and the negative electrode terminal plate 500, which are arranged side by side, at both sides to prevent the structure from being separated, has no appropriate countermeasure when the pressure structures are deformed. Therefore, the solution is to replace the parts frequently, the frequent replacement method of these parts will act as a factor to reduce the quality satisfaction of the product.

On the other hand, each component constituting the conventional heater module 100 is also a way that the arrangement state is fixed by the pressing force provided from the side frame 300 in the absence of a separate fixing means, this also the side frame ( If the pressing force of 300 is reduced, there is a problem in that connection failure occurs while the reliability of the fixing force is weakened.

Accordingly, the present invention is to improve the conventional problems raised as described above, to provide a heater module to increase the bonding force of the components constituting the heater module to prevent the occurrence of electrical connection failure occurs. will be.

In addition, the present invention is another object to improve the overall quality satisfaction of the PTC heater by allowing the pressing force applied to the inner side of the heater module and the heat dissipation unit arranged side by side to be kept constant for a long time.

PTC heater heater module of the present invention for achieving the above object is a PTC element which is a heating element; A tubular insulating structure forming a plurality of mounting holes and allowing the PTC device to be mounted in one direction of the mounting holes; A ceramic insulator mounted corresponding to the PTC element in the other direction of the mounting hole and blocking contact between the positive electrode terminal plate and the cover plate which will be described later; A positive electrode terminal plate coupled in a length direction in the insulating structure, making contact with one surface of the PTC element and the ceramic insulator, and transmitting a power (+) to the PTC element; And a cover plate coupled to the PTC device, the ceramic insulator, and the insulating structure to surround the PTC device, and to contact the other surface of the PTC device to transmit power (−). It will include.

On the other hand, the PTC heater of the present invention comprises a heater module arranged at a predetermined interval; Radiating parts arranged side by side on the left and right sides of the heater module; A plurality of negative electrode terminal plates arranged side by side between the heat dissipating parts and applying power (−) to the heater module; A side frame configured to pressurize and fix the heater module, the heat dissipation unit, and the negative electrode terminal plate arranged side by side; And an end holder fixing the side frame. Including, but the heater module PTC element that is a heating element; A tubular insulating structure forming a plurality of mounting holes and allowing the PTC device to be mounted in one direction of the mounting holes; A ceramic insulator mounted corresponding to the PTC element in the other direction of the mounting hole and blocking contact between the anode terminal plate and the cover plate which will be described later; A positive electrode terminal plate coupled in a length direction in the insulating structure, making contact with one surface of the PTC element and the ceramic insulator, and transmitting a power (+) to the PTC element; And a cover plate coupled to the PTC element, the ceramic insulator, and the insulating structure to surround the PTC element, and to contact the other surface of the PTC element to transmit power (-) applied from the negative electrode terminal plate to the PTC element. It will include.

In addition, the insulating structure is formed with a coupling groove and a locking step at a predetermined interval along the longitudinal direction to guide the coupling of the cover plate.

In addition, the cover plate may include a first plate closely coupled to a surface on which the ceramic insulator is mounted; Second and third plates fixed to the PTC element while being in contact with each other on one surface of the insulating structure on which the PTC element is mounted; And connecting the first plate and the second plate, and the first plate and the third plate, and when the PTC device and the insulating structure are wrapped through the first to third plates, the coupling groove of the insulating structure. Bent portion that is fitted fitting; It will include.

In addition, the side frame is a U-shaped fixed frame; A U-shaped pressurizing frame coupled to the fixed frame and pressurizing the heater module, the heat dissipating unit, and the negative electrode terminal plate arranged in parallel with each other in an inward direction; It consists of.

In addition, the fixing frame is configured to be curved rather than straight so as to press the heater module and the heat dissipation unit and the negative electrode terminal plate arranged side by side inward with the pressing frame.

In addition, the pressing frame is the first and second frames; A pressing unit arranged in multiple stages with a predetermined interval to connect the first and second frames; It will include.

The heat dissipation unit may further include a heat dissipation fin; It comprises a support plate for supporting the heat dissipation fin, the support plate is to form a locking step for preventing the separation of the heat dissipation fin.

Thus, the present invention is to increase the bonding force of the components constituting the heater module, as well as configured to maintain a constant pressure applied to the heater module and the heat radiating portion arranged side by side for a long time, thereby preventing the electrical connection failure of the heater module. It can be expected to improve the overall quality satisfaction of PTC heaters.

1 is a conventional PTC heater structure diagram.
2 is an exploded view of a heater module in a first embodiment of the present invention.
3 is a coupling diagram of the heater module in the first embodiment of the present invention.
4 is a cross-sectional view taken along line AA of FIG. 3 as a first embodiment of the present invention;
5 is a cross-sectional view taken along line BB of FIG. 3 as a first embodiment of the present invention;
FIG. 6 is a cross-sectional view taken along line CC of FIG. 3 as a first embodiment of the present invention; FIG.
7 is an exploded view of a PTC heater in a second embodiment of the present invention.
8 is a coupling diagram of a PTC heater in a second embodiment of the present invention.
9 is a plan view of a PTC heater in a second embodiment of the present invention;
10 is a sectional view taken along the line DD of FIG. 9 according to a second embodiment of the present invention;
11 is a cross-sectional view showing a pressing state of the side frame in a second embodiment of the present invention.
12 is an exploded view of a PTC heater in a third embodiment of the present invention.
13 is a coupling diagram of a PTC heater in a third embodiment of the present invention.

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

2 is an exploded view of a heater module in the first embodiment of the present invention, FIG. 3 is a coupling diagram of the heater module in the first embodiment of the present invention, and FIG. 4 is a first embodiment of the present invention. AA line cross section is shown.

5 is a cross-sectional view taken along line B-B of FIG. 3 as a first embodiment of the present invention, and FIG. 6 is a cross-sectional view taken along line C-C of FIG. 3 as a first embodiment of the present invention.

3 to 6, the heater module 10 according to the first embodiment of the present invention is a PTC element 11, an insulating structure 12, an anode terminal plate 13, a cover plate (heating element) 14), and the ceramic insulator 15 is a structure that is bonded.

The PTC element 11 is electrically connected to the cover plate 14 through the insulating structure 12 at a predetermined number of intervals.

The ceramic insulator 15 is a number corresponding to the PTC element 11 and is configured to block the contact between the positive electrode terminal plate 13 and the cover plate 14.

The insulating structure 12 is a tubular structure that forms a mounting hole 12a in which the PTC element 11 and the ceramic insulator 15 are mounted in different directions with the anode terminal plate 13 interposed therebetween. In addition, the insulating structure 12 is formed with a coupling groove 12b and a locking jaw portion 12c for guiding the coupling of the cover plate 14 at a predetermined interval in the longitudinal direction.

That is, the coupling groove 12b is formed at both sides between the mounting holes 12a formed at predetermined intervals along the longitudinal direction of the insulating structure 12.

The locking jaw portion 12c is configured to protrude to a predetermined thickness along the longitudinal direction of the insulating structure 12 forming the coupling groove portion 12b, the protruding thickness is designed to be thicker than the thickness of the cover plate 14 This is to prevent the flow and departure of the cover plate 14 which surrounds the insulating structure 12.

The anode terminal plate 13 is a bar-shaped structure, which is coupled along the length direction in the insulating structure 12 which is the tubular structure, and has a PTC device (12) in the mounting hole 12a of the insulating structure 12. 11) and when the ceramic insulator 15 is mounted, it is configured to apply power (+) supplied through a common terminal (not shown) to one surface of the PTC element 11 to the PTC element 11. will be.

Here, the method of coupling the positive electrode terminal plate 13 in the insulating structure 12 in the longitudinal direction is most preferably insert injection, but is not necessarily limited thereto.

The cover plate 14 is coupled to surround the PTC element 11, the ceramic insulator 15, and the insulating structure 12. The cover plate 14 is in contact with the PTC element 11 in common terminal (not shown). It is configured to deliver the power (-) supplied through the PTC element 11, and consists of the first to third plates 14a, 14b, 14c and the bent portion 14d.

The first plate 14a may be in close contact with the surface on which the ceramic insulator 15 is mounted so that the ceramic insulator 15 may be fixed in the mounting hole 12a. The ceramic insulator 15 It will not be in contact with the positive electrode terminal plate 13 through.

The second and third plates 14b and 14c are in close contact with each other on one surface of the insulating structure 12 on which the PTC element 11 is mounted, and thus the PTC element 11 is attached to the mounting hole 12a. It is configured to be fixed in position.

Here, the thickness of the first plate 14a and the second and third plates 14b and 14c may be such that the locking step 12c does not leave the locking step 12c of the insulating structure 12 as described above. It was made smaller than the protrusion thickness of.

The bent portion 14d is a structure that connects the first plate 14a and the second plate 14b, and the first plate 14a and the third plate 14c, and is capable of bending deformation (bending). When the PTC element 11, the ceramic insulator 15, and the insulation structure 12 are wrapped through the first to third plates 14a, 14b and 14c, the coupling groove of the insulation structure 12 is formed. Fit to the (12b) is made to prevent the first to third plates 14a, 14b, 14c constituting the cover plate 14 from being separated from the insulating structure (12).

That is, the heater module 10 according to the first embodiment of the present invention, as shown in Figures 2 to 6 attached to the coupling of the positive electrode terminal plate 13 along the longitudinal direction in the insulating structure 12 On the other hand, a plurality of PTC elements 11 are mounted in the mounting holes 12a on one surface of the insulating structure 12, and the PTC elements 11 are mounted in the mounting holes 12a on the other surface of the insulating structure 12. After the corresponding number is mounted, the cover plate 14 having the bent portion 14d surrounds the PTC element 11, the ceramic insulator 15, and the insulating structure 12.

Then, the heater module 10 forms a unit assembly. Accordingly, when the heater module 10 according to the first embodiment of the present invention is applied to a vehicle PTC heater, the heater module 10 is formed of a side frame. It is possible to maintain a solid state regardless of the pressing force.

On the other hand, Figures 7 to 11 is a second embodiment of the present invention, which is the heater module 10 and the heat dissipation unit 20 is arranged side by side, the heater module 10 and the heat dissipation unit 20 are arranged side by side ) By pressing a constant pressure at both sides, and relates to a PTC heater to maintain a constant coupling force according to the arrangement.

That is, the PTC heater according to the second embodiment of the present invention, the heater module 10 is arranged at a predetermined interval, the heat dissipation unit 20 is arranged side by side on the left and right sides of the heater module 10, respectively, A plurality of cathode terminal plates 50 arranged side by side between the heat dissipation unit 20 and applying power (−) to the heater module 10, and the heater module 10 and the heat dissipation unit 20 arranged side by side. And a side frame 30 for pressing and fixing the negative electrode terminal plate 50 and an end holder 40 for fixing the side frame 30, the side frame 30 is fixed to the side frame 30. It consists of 31 and the pressing frame 32.

The fixed frame 31 is made of a U-shaped structure to accommodate the pressing frame 32, both ends of the longitudinal direction is configured to be fixed by the end holder 40 .

At this time, the fixing frame 31 has a straightness so as to press the heater module 10 and the heat dissipation unit 20 and the negative electrode terminal plate 50 arranged in parallel with the pressing frame 32 in the inward direction. It was not configured to curve.

The pressurizing frame 32 is a U-shaped structure, which couples the heater module 10 and the heat dissipating unit 20 and the negative electrode terminal plate 50 which are coupled and arranged side by side in the fixing frame 31 inward. The first and second frames 32a and 32b and the pressing portion 32c are included.

The first and second frames 32a and 32b are designed to have a length equal to or slightly smaller than the length of the fixed frame 31, and the pressing part 32c is the first and second frames 32a and 32b. It is curved as being arranged in multiple stages with a predetermined interval while connecting the, the pressing portion 32c is to press the heater module 10, the heat dissipating portion 20 and the negative electrode terminal plate 50 in the inward direction will be.

The heat dissipation unit 20 includes a heat dissipation fin 21 and a support plate 22 supporting the heat dissipation fin 21, and the support plate 22 is configured to prevent the heat dissipation fin 21 from being separated. The locking jaw portion 22a is formed.

Here, the heater module 10 is composed of components that are combined into one assembly unit as disclosed in the first embodiment of the present invention, or side by side without having a separate coupling force described in the prior art of the present invention. The heater module 10 may be radiated by a portion protruding from the curving process of the fixing frame 31 as well as the pressing force applied by the pressing part 22c. The close contact with the part 20 and the negative electrode terminal plate 50 may be maintained firmly, and the coupling force of the components constituting the heater module 10 may be prevented from being lowered.

That is, the curved surface of the pressing portion 32c included in the pressing frame 32 is supported by the first and second frames 32a and 32b to apply pressure to the heat dissipating portion 20 at both sides of the PTC heater. Therefore, the pressure is transmitted to the heater module 10 and the negative electrode terminal plate 50 which are arranged side by side with the heat radiating unit 20 as well as the heat radiating unit 20. Coupling force according to the side-by-side arrangement of the heat dissipation unit 20 and the negative electrode terminal plate 50 is to be firmly maintained without separation or loose.

12 and 13 are attached to the third embodiment of the present invention, which is arranged side by side when the heater module 10 and the heat dissipation unit 20 and the negative electrode terminal plate 50 are arranged side by side. Pressing the module 10, the heat dissipation unit 20 and the negative electrode terminal plate 50 at a constant pressure on both sides, so that the coupling force according to the arrangement state can be kept constant, while the heater module 10 It relates to a PTC heater composed of the same structure as the first embodiment of the present invention.

That is, the PTC heater according to the third embodiment of the present invention, the heater module 10 is arranged at a predetermined interval, the heat dissipation unit 20 is arranged in parallel to the left and right sides of the heater module 10, and The plurality of cathode terminal plates 50 arranged side by side between the heat dissipation unit 20 and applying a power (−) to the heater module 10, and arranged side by side on one side of the heat dissipation unit 20 and the heater A side frame (30) for pressing and fixing the module (10), the heat dissipation unit (20) and the negative electrode terminal plate (50), and an end holder (40) for fixing the side frame (30); In the PTC heater comprising a, the heater module 100 is configured in the same manner as the first embodiment of the present invention, the side frame 30 is configured in the same manner as the second embodiment of the present invention.

That is, the heater module 10 has a PTC element 11 which is a heating element, a plurality of mounting holes 12a, and a tubular shape for mounting the PTC element 11 in one direction of the mounting hole 12a. The insulating structure 12 and the ceramic insulator 15 mounted correspondingly to the PTC element 11 in the other direction of the mounting hole 12a and blocking contact between the positive electrode terminal plate 13 and the cover plate 14. ) Is coupled along the longitudinal direction in the insulating structure 12 to make contact with one surface of the PTC element 11 and the ceramic insulator 15 to transfer power (+) to the PTC element 11. The cathode terminal plate 13 having a bar shape and the PTC element 11, the ceramic insulator 15, and the insulating structure 12 are combined to surround each other, and come in contact with the other surface of the PTC element 11 to contact the cathode terminal. The cover plate 14 for transmitting the power (-) applied from the plate 50 to the PTC element 11 It will hamhan.

In addition, the insulating structure 12 is to form a coupling groove 12b and a locking jaw portion 12c at a predetermined interval along the longitudinal direction to guide the coupling of the cover plate 14, the cover plate 14 Is the first plate 14a which is tightly coupled to the surface on which the ceramic insulator 15 is mounted, and is tightly coupled to one surface of the insulating structure 12 on which the PTC element 11 is mounted. The second and third plates 14b and 14c for fixing 11, the first plate 14a and the second plate 14b, and the first plate 14a and the third plate 14c. Coupling the insulating structure 12 when the PTC element 11, the insulating structure 12, and the ceramic insulator 15 are wrapped through the first to third plates 14a, 14b, and 14c. It is comprised including the bending part 14d in which the fitting engagement is carried out in the groove part 12b.

At this time, the thickness of the first plate 14a and the second and third plates 14b and 14c is smaller than the protruding length of the locking step 12b so as not to escape the locking step 12b of the insulating structure 12. It is preferable to configure, which is to prevent the phenomenon of the separation as well as the flow of the cover plate (14).

The side frame 30 is a U-shaped fixed frame 31 curved in the longitudinal direction, and coupled to the fixed frame 31, the heater module 10 and the heat dissipation unit 20 and arranged side by side Composed of a U-shaped pressing frame 32 for pressing the negative electrode terminal plate 50 in the inward direction, the pressing frame 32 is the first and second frames 32a, 32b and the first and second frames It comprises a pressing portion 32c which is arranged in multiple stages at regular intervals so as to connect the 32a and 32b.

The heat dissipation unit 20 includes a heat dissipation fin 21 and a support plate 22 supporting the heat dissipation fin 21, and the support plate 22 is configured to prevent the heat dissipation fin 21 from being separated. The locking jaw portion 22a is formed.

That is, in the third embodiment of the present invention, as shown in FIGS. 12 and 13, the heater module 10 is coupled to one assembly unit, and the heat dissipation unit 20 and the cathode terminal are arranged side by side on the left and right sides thereof. Place the plate 50.

Then, after arranging the side frame 30 to one side of the heat dissipation unit 20, when both ends are fixed by combining the end holder 40 in the longitudinal direction of the side frame 30, the side frame ( The curved portion of the fixed frame 31 and the pressing portion 32c of the pressing frame 32 applied to the heat dissipating portion 20 apply a predetermined pressure to the heat dissipating portion 20, and thus the heater module is a unit assembly arranged side by side. 10 and the heat dissipation unit 20 and the negative electrode terminal plate 50 will be able to maintain a tight close coupling state.

Therefore, when the heater module 10, the heat dissipation unit 20, and the negative electrode terminal plate 50 maintain the tightly coupled state by the side frame 30 and the end holder 40 as described above, the heater module 10 When the power (+) (-) is applied to the PTC element 11 included in the heat generating operation of the PTC element 11 is increased, the heat generation efficiency is increased, as well as the heat radiation efficiency of the heat dissipation unit 20 It can be increased.

Hereinafter, in the third embodiment of the present invention, the overlapping description of the same effect as in the first and second embodiments is omitted.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It is to be understood that such changes and modifications are within the scope of the claims.

10; Heater module 11; PTC device
12; Insulating structure 12a; Mounting hole
12b; Coupling groove 12c; Hanging jaw
13; Anode terminal plate 14; Cover plate
14a; First plates 14b, 14c; Second, third plate
14d; Bend 15; Ceramic insulator
20; Heat dissipation 21; Heat sink fin
22; Support plate 22a; Hanging jaw
30; Sideframe 31; Fixed frame
32; Pressing frames 32a and 32b; 1st and 2nd frame
32c; Pressing unit 40; End holder
50; Negative Terminal Plate

Claims (13)

PTC element that is a heating element; A tubular insulating structure forming a plurality of mounting holes and allowing the PTC device to be mounted in one direction of the mounting holes; A ceramic insulator mounted corresponding to the PTC element in the other direction of the mounting hole and blocking contact between the anode terminal plate and the cover plate which will be described later; A positive electrode terminal plate coupled in a length direction in the insulating structure, making contact with one surface of the PTC element and the ceramic insulator, and transmitting a power (+) to the PTC element; And a cover plate coupled to the PTC device, the ceramic insulator, and the insulating structure to surround the PTC device, and to contact the other surface of the PTC device to transmit power (−). And including
Heater module, characterized in that the insulating structure to form a coupling groove and the locking step at a predetermined interval along the longitudinal direction to guide the coupling of the cover plate. delete The method of claim 1, wherein the cover plate,
A first plate tightly coupled to a surface on which the ceramic insulator is mounted;
Second and third plates fixed to the PTC element while being in contact with each other on one surface of the insulating structure on which the PTC element is mounted; And,
The first plate and the second plate and the first plate and the third plate are connected to each other, and are fitted into the coupling groove of the insulating structure when the PTC device and the insulating structure are wrapped through the first to third plates. A bending portion formed; Heater module, characterized in that comprising a. A heater module arranged at a predetermined interval; Radiating parts arranged side by side on the left and right sides of the heater module; A plurality of negative electrode terminal plates arranged side by side between the heat dissipating parts and applying power (−) to the heater module; A side frame configured to pressurize and fix the heater module, the heat dissipation unit, and the negative electrode terminal plate arranged side by side; And an end holder fixing the side frame. In constructing a PTC heater comprising:
The heater module includes a PTC element that is a heating element; A tubular insulating structure forming a plurality of mounting holes and allowing the PTC device to be mounted in one direction of the mounting holes; A ceramic insulator mounted corresponding to the PTC element in the other direction of the mounting hole and blocking contact between the anode terminal plate and the cover plate which will be described later; A positive electrode terminal plate coupled in a length direction in the insulating structure, making contact with one surface of the PTC element and the ceramic insulator, and transmitting a power (+) to the PTC element; And a cover plate coupled to the PTC element, the ceramic insulator, and the insulating structure to surround the PTC element, and to contact the other surface of the PTC element to transmit power (-) applied from the negative electrode terminal plate to the PTC element. And including
PTC heater, characterized in that the insulating structure to form a coupling groove and a locking step at a predetermined interval along the longitudinal direction to guide the coupling of the cover plate. delete The method of claim 4, wherein the cover plate,
A first plate tightly coupled to a surface on which the ceramic insulator is mounted;
Second and third plates fixed to the PTC element while being in contact with each other on one surface of the insulating structure on which the PTC element is mounted; And,
The first plate and the second plate and the first plate and the third plate are connected to each other, and are fitted into the coupling groove of the insulating structure when the PTC device and the insulating structure are wrapped through the first to third plates. A bending portion formed; PTC heater comprising a. The method of claim 4, wherein the side frame,
C-shaped fixed frame;
A U-shaped pressurizing frame coupled to the fixed frame and pressurizing the heater module, the heat dissipating unit and the negative electrode terminal plate arranged in parallel to the inner side; PTC heater, characterized in that consisting of. The method of claim 7, wherein the fixing frame PTC heater, characterized in that configured to be curved rather than straight so as to press the heater module and the heat dissipation unit and the negative electrode terminal plate arranged side by side inward with the pressing frame. The method of claim 7 or 8, wherein the pressing frame,
First and second frames;
A pressing unit arranged in multiple stages with a predetermined interval to connect the first and second frames; PTC heater comprising a. The method of claim 4, wherein the heat dissipation unit,
Heat dissipation fins;
It comprises a support plate for supporting the heat dissipation fins,
PTC support, characterized in that the support plate to form a locking step for preventing the separation of the heat radiation fins. A heater module arranged at a predetermined interval; Radiating parts arranged side by side on the left and right sides of the heater module; A plurality of negative electrode terminal plates arranged side by side between the heat dissipating parts and applying power (−) to the heater module; A side frame configured to pressurize and fix the heater module, the heat dissipating unit, and the negative electrode terminal plate arranged in parallel; And an end holder fixing the side frame. In constructing a PTC heater comprising:
The side frame is a U-shaped fixed frame; A U-shaped pressing frame coupled to the fixing frame and pressing the heater module, the heat dissipating unit, and the negative electrode terminal plate in an inward direction; PTC heater, characterized in that consisting of. 12. The PTC heater according to claim 11, wherein the fixing frame is configured such that the heater module, the heat dissipation unit, and the negative electrode terminal plate, which are arranged in parallel, are curved in a straight line rather than straight so as to press inwardly together with the pressing frame. The method of claim 11 or 12, wherein the pressure frame,
First and second frames;
A pressing unit arranged in multiple stages with a predetermined interval to connect the first and second frames; PTC heater comprising a.

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