KR101977728B1 - A ptc heater - Google Patents

Abstract

More particularly, the present invention relates to a Pittsi heater capable of reducing the width, simplifying the structure, increasing the space efficiency, and improving the heating performance by further improving the heat exchange performance .

Description

{PTC HEATER}

More particularly, the present invention relates to a Pittsi heater capable of reducing the width, simplifying the structure, increasing the space efficiency, and improving the heating performance by further improving the heat exchange performance .

The heating means is used for raising the temperature of the outside, and means using various methods have been proposed and are also used for various purposes.

Particularly, among the heating means provided in the vehicle engine room, the heating means for heating the room is configured to heat the outside of the vehicle by heating the outside air while circulating the heater core through the heat exchange medium for lowering the temperature of the engine.

However, since the diesel engine has a high heat exchange rate, it takes a long time to heat the heat exchanging medium for cooling the engine at the initial start of the automobile, compared to the gasoline engine.

Therefore, in a vehicle equipped with a diesel engine in the winter, the heating of the heat exchange medium is delayed after the initial startup and the initial indoor heating performance is deteriorated.

In order to solve the above-mentioned problems, there has been proposed a vehicular air heater which directly heats air blown to a room side by various means.

Such an air heating type heater is advantageous in that the heating performance can be further improved by directly heating the air. However, due to the trend of miniaturization and high efficiency, it takes a space equal to the size of the heater in a situation where it is difficult to secure sufficient space in the engine room Which may cause the miniaturization to be hindered.

Particularly, in the case of a cartridge heater using a nichrome wire, it is difficult to control the temperature, and when air is not blown to the heater side, there is a fear of overheat, insulation problem due to high voltage may occur, There is a problem.

A vehicle air conditioner using a PTC (Positive Temperature Coefficient) heater has been proposed in Japanese Patent Application Laid-Open No. 2009-255739, and a conventional PTC heater is shown in Fig.

1, the PTC heater shown in FIG. 1 includes a heat source unit 11 formed of a PTC device, a heat radiation unit 11 for effectively releasing heat while being in contact with the heat source unit 11, And a housing 20 that covers and protects the terminal unit, the heat source unit 11, and the heat radiation unit 12.

The conventional PTC heater may have some differences in detail, but since the heat source portion is formed in parallel with the air flow direction, the formation area of the heat source portion directly affects the heat generating performance and accordingly, the thickness of the PTC heater There is a limit to reducing the number

Particularly, in the case of a PTC heater, since an electrical problem may occur when the heat radiation condition is poor, a heat dissipation part (generally, a heat dissipation fin) must be formed. Therefore, manufacturing and assembly processes of the heat dissipation part are troublesome, There is a problem that the durability of the entire PTC heater may deteriorate.

Fig. 2 shows an example of a vehicle air conditioner using a PTC heater.

2 includes a floor vent 31, a defrost vent 32, and a face vent 33, which are opened by respective doors 31d, 32d, and 33d, ); An evaporator 41 provided in the air conditioning case 30 to cool air; A heater core 42 for heating the air by flowing high-temperature cooling water, and a PTC heater 43 provided on the rear side of the heater core 42 in the air flow direction.

At this time, the PTC heater is provided to maintain a certain distance from the heater core, which occupies a space inside the air conditioner case, thereby hindering the space efficiency.

In addition, in many cases, the PTC heater is located in the central region of the heater core in the height direction in order to prevent the pressure drop of the air and to reduce the cost, and the air having passed through the upper and lower regions, So that the heating performance is inevitably lowered.

(The flow of air that is not properly heated is shown by the dotted arrow.)

Accordingly, it is an object of the present invention to provide a heater that can heat-exchange directly with air, improve the heating performance by further improving heat exchange performance, can be downsized, can be easily controlled, Development is required.

Patent 1) Japanese Laid-Open Patent Application No. 2009-255739 (Title of Invention: Air Conditioning Apparatus for Vehicle, Release Date: 2009.11.05)

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the problems as described above, and it is an object of the present invention to provide a Pitty seed heater capable of improving the space efficiency, the heat exchange performance, .

The Pittsi heaters 200 of the present invention are plate-shaped and have a first heating region A210-1 and a first air flow region A210-2 in which a plurality of first hollow portions 211 hollow are formed, A first support portion 210 including a first support portion 210; An insulative support (not shown) having a positive temperature coefficient (PTC) element and a hollow space 223 formed to correspond to the first heat generating area A210-1 and hollowed to receive the Pitts' And a first electrode 226 supporting the first electrode 226 and at least one first hole 228a being hollow. The first electrode 226 is electrically connected to the first electrode 226, A heat generating part 220 including a plurality of heaters 228; And a housing 240 for supporting and fixing one end portion of the first support portion 210 and the heat generating portion 220.

At this time, the first heating part 220 is formed with the first seating part 224 such that the surface of the insulating support 222 corresponding to the first heating area A210-1 is stepped toward the space part 223 The first electrode 226 is seated in the first seating portion 224 of the insulative support 222 and the first insulative portion 228 is formed in a size corresponding to the insulative support 222 .

The heating unit 220 further includes a second electrode 227 on the opposite side of the insulating support 222 on which the first electrode 226 is located.

A second seating part 225 is formed in the heat generating part 220 such that the opposite surface of the insulating supporting body 222 to the first seating part 224 is stepped toward the space part 223, And the electrode 227 is seated on the second seating part 225 of the insulative support body 222.

In addition, the Pettish heater 200 includes a second air flow area A230-2 having a second heat generating area A230-1 and a plurality of second hollow parts 231 having a predetermined hollow area, And a second support part 230 including the first support part 210 and the second support part 230 is provided on the opposite side of the first support part 210 of the heat generating part 220.

The heat generating unit 220 is formed on the side where the second support unit 230 is formed to correspond to the second heat generating area A230-1 and the at least one second through hole 229a is hollow, (229).

The heat generating unit 220 may be disposed inside the heat generating tube 201 and the heat generating tube 201 may be connected to the first heat generating region 210 of the first supporting unit 210 using an adhesive, (A210-1) of the second support portion (230) and the second heat generation region (A230-1) of the second support portion (230).

Accordingly, the heat sink of the present invention uses a plate-like first support portion and a second support portion which are positioned perpendicular to the air flow direction, and the heat dissipation member is supported by the insulator support. It is possible to reduce the thickness while being easy to manufacture, and thus it is possible to miniaturize the heat exchanger, and the heating performance can be improved by increasing the heat exchanging performance.

Particularly, since the first through-hole (and the second through-hole in the second insulating portion) is formed in the first insulating portion of the present invention, the heat transfer can be easily performed while securing the insulating property, have.

In addition, the heat dissipation part of the present invention is advantageous in that the heat generating part is supported on both sides by the first supporting part and the second supporting part, thereby improving the structural stability.

In the present invention, the first hollow portion formed on the first support portion and the second hollow portion formed on the second support portion are formed to overlap with each other in a certain region in the air flow direction, thereby making the air flow turbulent, There is an advantage that performance can be improved.

1 is a view showing a conventional PTC heater.
2 is a view showing a general automotive air conditioner.
FIGS. 3 to 5 are a perspective view, an exploded perspective view and a cross-sectional view in the AA 'direction of a Pittsy seed heater according to the present invention. FIG.
6 is another cross-sectional view of a Pittsy seed heater according to the present invention.
7 to 9 are another perspective view, an exploded perspective view and a cross-sectional view in BB 'direction of the Pittsi heaters according to the present invention.
10 and 11 are still another cross-sectional view and partially exploded perspective view of a PTFE heater according to the present invention;
12 is a view showing an example of an insulating portion of a Pittsy ' heater according to the present invention.
13 is a view showing various examples of the Pittsy heaters according to the present invention.
FIG. 14 is a schematic view showing a vehicle air conditioner provided with a Pittsi heater according to the present invention. FIG.

Hereinafter, a Peltier heater 200 according to the present invention having the above-described characteristics will be described in detail with reference to the accompanying drawings.

First, the Peltier heater 200 of the present invention includes a first support part 210, a heat generating part 220, and a housing 240.

The first support part 210 is in the form of a plate, and is positioned perpendicular to the air flow direction.

More specifically, the first supporting portion 210 is in the form of a plate including a first heating region A210-1 and a first airflow region A210-2, and the first heating region A210-1 is a plate- The first air flow area A210-2 is a region in which the first heating unit 220 is provided and the first air flow area A210-2 is a region in which a plurality of first hollows 211 are hollow.

The first hollow portion 211 may be formed in various shapes such as a circular shape, a square shape and a slanted shape, and the number of the first hollow portions 211 may be variously formed.

The heating unit 220 is configured to generate heat by a power source and is provided in the first heating region A210-1 of the first supporting unit 210. [

The housing 240 supports and fixes one end of the first supporting part 210 and the heat generating part 220.

At this time, the housing 240 may have a built-in structure for supplying power to the heat generating unit 220.

More specifically, the detailed configuration of the heat generating unit 220 will be described.

4 and 5, the heat generating unit 220 includes a Pettis device 221, an insulating support 222, a first electrode 226, and a second insulating member 229 .

The insulating support body 222 is a basic body for forming the heat generating part 220, and a hollow part 223 is formed to hollow the element body 221.

The first electrode 226 is configured to apply power to the Pitts' device 221.

The first insulation portion 228 is in the form of a plate for supporting the first electrode 226, and at least one first through hole 228a is formed.

The first insulating portion 228 may be formed of an insulating material, and a plurality of first through holes 228a may be formed to reduce a material for forming the first insulating portion 228, The heat of the Pettis device 221 can be easily transferred to the first support part 210 through the one through hole 228a, thereby heating the air more effectively.

6, the surface of the insulating support body 222 corresponding to the first heat generating region A210-1 is connected to the space portion 223 side And the first electrode 226 may be seated in the first seating portion 224 of the insulative support 222. The first seating portion 224 may be formed as a stepped portion.

That is, the insulative support body 222 has the first electrode 226 on the first seating portion 224 on one side of the Pettis device 221, Respectively.

At this time, the first insulation portion 228 is formed to have a size corresponding to the insulation support 222.

7 to 9 are a perspective view, an exploded perspective view, and a BB 'sectional view of another example of the heat sink 200 according to the present invention. In the heat sink 200 of the present invention, And the second electrode 227 may be further provided on the opposite side of the insulating support body 222 where the first electrode 226 is located.

In this case, similarly to the first seating part 224, the insulating supporting body 222 is formed with a seating part such that the opposite surface of the first seating part 224 is stepped toward the space part 223, The two electrodes 227 may be seated on the second seating portion 225 of the insulative support 222.

7 to 9, the second support portion 230 is further provided on the heat generating portion 220 on the opposite side where the first support portion 210 is formed.

The second support part 230 includes a second air flow area A230-2 having a plate shape and including a second heat generating area A230-1 and a plurality of second hollow parts 231 having a predetermined hollow area .

At this time, the first supporting portion 210 and the second supporting portion 230 are formed to have the same overall size, and the first heating region A210-1 and the first air flowing region A210-2 are formed to correspond to the second heating region A230-1 and the second air flow region A230-2 of the second support portion 230. [

The heat generating unit 220 is formed on the side where the second support unit 230 is formed to correspond to the second heat generating area A230-1 and the at least one second through hole 229a is hollow, (229).

The second insulating portion 229 may be formed of an insulating material, and a plurality of second through holes 229a may be formed to reduce the material for forming the second insulating portion 229, The heat of the Pettis device 221 can be easily transferred to the second support part 230 through the two through holes 229a, thereby heating the air more effectively.

10 and 11 are still another cross-sectional view and partially exploded perspective view of the heat dissipation unit 200 according to the present invention. The heat generation unit 220 is configured as described above, and the heat generation unit 220 The heat generating tube 201 is disposed inside the heat generating tube 201 and the heat generating tube 201 is attached to the first heat generating region A210-1 of the first supporting portion 210 and the second heat generating region A210-1 of the second supporting portion 230, (A230-1).

10 and 11 show an example in which the heat generating part 220 of the type shown in FIGS. 7 to 9 is provided inside the heat generating tube 201. As shown in FIG.

12 shows various examples of the first insulating portion 228 and the second insulating portion 229 of the Peltier heater 200 according to the present invention. The first insulating portion 228a of the first insulating portion 228 And the second through hole 229a of the second insulating portion 229 may be formed in various shapes.

12A shows an example in which a circular first through hole 228a and a second through hole 229a are formed in the first insulating portion 228 and the second insulating portion 229. Fig. A first through hole 228a and a second through hole 229a are formed in the first insulating portion 228 and the second insulating portion 229 and FIG. An example where the first through hole 228a and the second through hole 229a are formed in the first insulating portion 228 and the second insulating portion 229 is shown.

The first through hole 228a and the second through hole 229a are formed in such a size that the first insulating portion 228 and the second insulating portion 229 can support the Pitts'i element 221, 12 (a) to 12 (c).

3 and 4, the plurality of heat generating portions 220 are formed on one of the first supporting portions 210 (and the second supporting portions 230) As shown in FIGS. 7 and 8, a plurality of heat generating units 220 may be provided in the form of a single module in the first supporting unit 210 (and the second supporting unit 230) .

FIG. 13 shows various examples of the first support part 210, the heat generating part 220, and the second support part 230 in the form of a single module.

13A shows that the first support part 210 and the second support part 230 are both formed in the same size and shape and the first hollow part 211 and the second hollow part 231 are formed at the same angle An example in which an inclination is formed is shown.

13 (b) is the same as that shown in FIG. 13 (a), except that the first hollow portion 211 and the second hollow portion 231 are formed at different angles to form the first hollow portion 211 And the second hollow portion 231 are overlapped only in a certain region.

13 (c) is the same as that shown in FIG. 13 (b), except that a first louver fin 212 is attached to the first hollow portion 211 of the first support portion 210, And the second louver pins 232 are formed on the second hollow portion 231 of the first louver 231.

The first louver fin 212 and the second louver pin 232 are respectively cut into a predetermined area corresponding to the first hollow portion 211 and the second hollow portion 231, do.

That is, the first louver fin 212 and the second louver pin 232 are integrally formed with the first support portion 210 and the second support portion 230, And the second hollow portion 231, as shown in Fig.

The first louver fin 212 and the second louver pin 232 are formed by cutting only the remaining portion except for the specific portion in the process for forming the first hollow portion 211 and the second hollow portion 231 The first supporting part 210, and the second supporting part 230. In this case, as shown in FIG.

In other words, the Pettish heater 200 of the present invention can be manufactured by using the region that was removed to form the first hollow portion 211 and the second hollow portion 231 and the first louver fin 212 and the second louver 231, By forming the pin 232, it can be manufactured by a simple method, the contact area with air can be further increased, and thus the entire heat exchange performance can be improved.

The protruding direction of the first louver fin 212 and the second louver fin 232 is parallel to the direction of the air flow so as not to interfere with the assembling property with other heat exchangers such as the heater core 100, And may be formed to be bent in the opposite direction of the engagement.

Accordingly, the thickness of the PTFE heater 200 of the present invention can be reduced in the width direction (in the direction of the air flow). By using the first support portion 210 and the second support portion 230, Can be reduced.

14 is an air conditioning apparatus 1000 using the Pittsy hearth 200 of the present invention.

14 includes a floor vent 310, a defrost vent 320, and a face vent 330, which are opened by respective doors 310d, 320d, and 330d, ); An evaporator 500 installed in the air conditioning case 300 to cool air; A heater core (100) provided in the air conditioning case (300) and heating air; And a tempeature door 400 for controlling the opening of the cold air passage and the warm air passage, wherein the heat sink 200 of the present invention is provided at the rear side of the heater core 100 to form the integrated heating device 1000 Respectively.

When the heat exchanger 200 according to the present invention heats the air together with the heater core 100, the heating performance can be further secured and miniaturization can be achieved.

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.

1000: Integrated heating system
100: heater core
200: Pitty Sea Heater
210: first support part 211: first hollow part
212: first louver pin
A210-1: first heating region A210-2: first air flow region
220: heat generating unit 201: heat generating tube
221:
222: insulative support 223:
224: first seat part 225: second seat part
226: first electrode 227: second electrode
228: first insulating portion 228a: first through hole
229: second insulating portion 229a: second through hole
230: second support portion 231: second hollow portion
232: second louver pin
A230-1: second heating region A230-2: second air flow region
240: Housing
300: Air conditioning case
310: Floor Vents 310d: Floor Vented Door
320: De-Frost Vent 320d: De-Frost Vent Door
330: Face Vent 330d: Face Vent Door
400: Temp door
500: Evaporator

Claims (7)

A first support portion 210 including a first air flow region A210-2 having a first heating region A210-1 and a plurality of first hollow portions 211 hollow in a predetermined region, in a plate form;
An insulative support (not shown) having a positive temperature coefficient (PTC) element and a hollow space 223 formed to correspond to the first heat generating area A210-1 and hollowed to receive the Pitts' A first electrode 226 for supporting the first electrode 226 and a second electrode 226 for supporting the first electrode 226 and at least one first through hole 228a for radiating heat, A heating portion 220 including an insulating portion 228;
And a housing 240 for supporting and fixing one end of the first supporting part 210 and the heat generating part 220,
Wherein the first electrode (226) is insulated by the insulating support (222) and the first insulation portion (228).
The method according to claim 1,
The heat generating unit 220
The first seating portion 224 is formed such that a surface corresponding to the first heating region A210-1 of the insulative support body 222 is stepped toward the space portion 223,
The first electrode 226 is seated on the first seating portion 224 of the insulative support 222,
Wherein the first insulation portion (228) is formed to have a size corresponding to the insulation support (222).
3. The method of claim 2,
The heat generating unit 220
Wherein a second electrode (227) is further provided on the opposite side of the insulating support body (222) on which the first electrode (226) is located.
The method of claim 3,
The heat generating unit 220
A second seating part 225 is formed so that the opposite surface of the insulating support body 222 to the first seating part 224 is stepped toward the space part 223,
Wherein the second electrode (227) is seated in the second seat (225) of the insulative support (222).
The method according to any one of claims 1 to 4,
The Pettishi heater (200)
A second support portion 230 including a second air flow region A230-2 in which a second heating region A230-1 and a plurality of second hollow portions 231 having a predetermined hollow are formed in a plate form, Wherein the first heating part (210) of the heat generating part (220) is formed on the opposite side of the first heating part (210).
6. The method of claim 5,
The heat generating part 220 is formed on the side where the second support part 230 is formed
Further comprising a second insulating portion (229) formed to correspond to the second heat generating region (A230-1) and at least one second through hole (229a) being hollow.
The method according to claim 6,
The Pettishi heater (200)
The heating unit 220 is provided inside the heating tube 201,
The heat generating tube 201 is bonded to the first heating region A210-1 of the first supporting unit 210 and the second heating region A230-1 of the second supporting unit 230 using an adhesive Featuring Pitty seed heater.

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