KR100498750B1 - PTC Heater and Heat Sink Structure for Electronic Products - Google Patents

Abstract

The present invention relates to a PTC heater and a heat sink structure for an electric product, the upper portion is provided with a plurality of heat dissipation fins 11 in the upright direction at regular intervals, and the heat dissipation plate integrally formed with the mounting portion 12 as the body bottom portion ( 10);

A PTC heater 20 installed at the mounting portion 12 of the heat sink 10 and configured to generate a constant temperature at a predetermined temperature when power is supplied;

Fixing plate 30 is installed on the bottom surface of the PTC heater 20, the support plate 31 is formed on the upper surface of the body so that the PTC heater 20 is fixed to the mounting portion 12 of the heat sink 10 and ;

In the mounting portion (12) consisting of an installation groove (15) for receiving the PTC heater (20) from the inside toward the upper portion of the access groove (13) open to both sides of the heat sink (10);

Concentrates the thermal conductivity radiated to the heat dissipation fin 11 in the installation groove 15, so as to block the heat dissipation to the outside, within the range not to escape the heat dissipation fin 11 from the bottom of the heat dissipation fin 11 of the heat sink 10 By setting the stepped portion 16, it is possible to maximize the ease of assembly, the stability of the coupling and the heat dissipation characteristics.

Therefore, it is a very useful invention that can improve the reliability of the product.

Description

PTC Heater and Heat Sink Structure for Electrical Appliances

The present invention relates to a PTC heater and a heat sink structure for an electric product, and more particularly, to form a mounting portion integrally with the bottom surface of the body of the heat sink, and to install the PTC heater sealed insulated film to the outside of the mounting portion, and close to the body By using the fixing plate provided with the support means to assemble the heat sink and the PTC heater, it is invented to maximize the ease of assembly and stability of the coupling and heat dissipation characteristics.

In general, PTC (Positive Temperature Coefficient), which is used for heaters such as electric appliances and electronics, is a semiconducting ceramic element having a directly proportional temperature coefficient.

And, before the critical temperature (Tc), PTC lowers the electrical resistance as the ambient temperature increases, and while the temperature reaches the melting point from the critical temperature, the electrical resistance increases significantly as the temperature increases, which is a PTC effect.

In addition, by using the PTC effect, it is possible to produce a PTC element heating element for different uses according to different temperature coefficients.

Therefore, PTC device has advantages such as high reliability, easy to use, safe and electricity saving, and is applied to a wide range of fields such as home appliances, electric power facilities, electronic facilities, and automobile business fields. Depending on the characteristics, it can be classified into three types: application of electrical resistance-temperature characteristics, application of current-time characteristics, and application of voltage-current characteristics (apparent power characteristics).

On the other hand, the combination structure of the PTC heater and the heat dissipation plate which is typically used for heaters, such as electrical appliances is formed on the surface of the plate is formed with a plurality of thin, constant intervals and widths of the heat dissipation fin (FIN) protruding vertically. A thin plate-like insulator is inserted between the plate-shaped heat dissipation fin and the PTC ceramic heater to prevent electric shock due to electric leakage. The PTC ceramic heater has a disc-shaped PTC heater inside the ceramic case, which is an insulating material, forms a protruding terminal so that the PTC ceramic heater can be supplied with electricity, and the electrode comes to one side of the ceramic case. Electrical heating by connecting one or more PTC ceramic heaters in series by connecting electric wires and shielding between the PTC ceramic heater and the electrode plate inside the ceramic case with an insulator and fixing them with a metal case. It is configured to generate heat.

However, in the combination configuration of the PTC heater and the heat sink, which is applied to the heater of the conventional electric appliance, the heater is a structure that fixes the PTC heater to the heat sink with screws, and the heat sink is a method of erecting blades by cutting a ductile metal plate. Although the heat radiation efficiency is good as the scoving heat sink, the processing is not only very demanding, but also the productivity is low and the processing cost is high.

In addition, the PTC heater is fastened and attached to the lower part of the heat sink, and a plurality of PTC heaters are connected in series, and the PTC heater is exposed to the outside, so there is a risk of electric shock. There was a closed end that must be covered separately and electrically insulated.

In addition, the plate-shaped insulator provided between the PTC ceramic heater and the ground plane of the heat sink is formed of a material having both heat resistance and insulation resistance, but the insulating film sticks or hardens over time in a heating state at a temperature higher than the heat resistance temperature of the insulator. Therefore, there is a problem in that breakdown of insulation occurs and a risk of leakage of electric current remains.

In addition, as the fastening structure of PTC heater and heat sink is relatively complicated, the labor cost increases and the manufacturing cost is high, and productivity is low. In particular, when the heat generated from the heater is radiated through the heat sink, the thermal conductivity is very low, which leads to high thermal efficiency. There was a problem of deterioration.

 An object of the present invention is to form a mounting portion integrally with the bottom of the body of the heat sink, and to install the PTC heater with the insulation film sealed to the outside of the mounting portion, the heat sink and PTC heater using a fixed plate provided with a close support means on the body It is to provide a PTC heater and heat sink structure for electrical appliances that can be assembled to maximize the ease of assembly, the stability of the coupling and the heat dissipation characteristics.

Another object of the present invention is to provide a PTC heater and a heat sink structure for an electric product, which can improve the reliability and commerciality of the product.

A plurality of heat dissipation fins 11 are provided in the upright direction at regular intervals in the upper portion, and a heat dissipation plate 10 in which the mounting portion 12 is integrally formed as the body bottom portion; and in the mounting portion 12 of the heat dissipation plate 10. A PTC heater 20 installed at a predetermined temperature when the power is supplied; and the PTC heater 20 can be fixed to the mounting portion 12 of the heat sink 10 while being installed at the bottom of the PTC heater 20. A fixing plate 30 having a close support body 31 formed on the upper surface of the body; and accommodating the PTC heater 20 from the inside toward an upper portion of the access groove 13 open to both sides of the heat sink 10. In the mounting portion 12 of the installation groove 15; The heat radiation fin of the heat sink 10 to concentrate the heat conductivity radiated to the heat radiation fin 11 portion in the installation groove 15, to block heat radiation to the outside (11) the stepped portion 16 is formed to be set within the range not to escape the heat dissipation fin 11 in the lower portion is achieved .

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Therefore, the present invention PTC heater and heat sink structure for the present invention, unlike the conventional assembly configuration, after the PTC heater 20 is installed in the mounting portion 12 composed of the lower body of the heat sink 10, the close support means 31 Since it is fixed using the fixing plate 30 formed in the body, it is possible to maximize the ease of assembly and stability of the coupling and heat dissipation characteristics.

  Therefore, the reliability of the product can be improved.

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

1 is an exploded perspective view showing a state in which the PTC heater is installed in the mounting portion consisting of the bottom portion of the heat sink in the configuration of the present invention and then assembled together using a fixing plate having a close support means formed on the body.

Figure 2 is a front sectional view showing a state in which the PTC heater is assembled with the heat sink in the present invention.

3 is a front sectional view showing a state in which the PTC heater is bent inward to the side of the mounting portion in a state where the PTC heater is mutually assembled with the heat sink by the configuration of the present invention.

That is, as shown in Figures 1 to 3, the heat dissipation plate 10 in the PTC heater and heat dissipation structure for the electric product of the present invention is provided with a plurality of heat dissipation fins 11 are formed in the upright direction at regular intervals to the upper body The body 12 is integrally formed with the mounting portion 12.

In addition, the mounting portion 12 integrally formed at the bottom of the body of the heat dissipation plate 10 has an open access groove 13 formed at the center of the body as shown in the drawing, and is provided at both sides of the access groove 13. Is provided with an access groove 13 to be bent from the inside to the outside, the upper inside of the access groove 13 is composed of an installation groove 15 for accommodating the PTC heater 20 from the inside.

Therefore, the PTC heater 20, which will be described later in the state where the installation groove 15 is placed in the PTC heater 20 in the state in which the access groove 13 is opened in the bottom surface of the heat sink 10, PTC heater 20 In the state in close contact with the bottom of the) it can be firmly supported in the mounting portion 12 of the heat sink 10 by the access groove (13).

On the other hand, the installation groove 15 is formed inside the bottom surface of the heat sink 10 is to maximize the heat conductivity is radiated to the heat radiation fin 11 portion formed in the upper body as shown in the figure, the heat radiation to the outside Step 16 is formed so that it can also serve to block the.

The stepped portion 16 is set within a range not to deviate from the heat radiating fins 11 at the bottom of the heat radiating fins 11 of the heat sink 10. The PTC heater is installed in the installation groove 15 substantially formed with the stepped portion 16. 20 is installed in close contact.

Here, the height of the stepped portion 16 formed on both sides of the mounting portion 12 of the heat sink 10 may vary the set height according to the product thickness of the PTC heater 20 to be installed, such a configuration also the present invention Included in the configuration.

2 and 3, the PTC heater 20 is bent inwardly by the stepped portion 16 in the state where the primary installation is completed by the fixing plate 30 after the installation groove 15 is positioned. PTC heater 20 located in the installation groove 15 can be fixed more stably for a long time.

As a result, as shown in the figure, since the bent groove 17 is formed at the inner right angle of the stepped portion 16 so that the stepped portion 16 can be more easily bent inward, the PTC heater 20 and In connection with this it is possible to minimize the heat dissipation to the outside due to the stability of the contact while bending the stepped portion 16 inwardly after the installation of the fixing plate 30, it is also possible to maximize the fixing force.

On the other hand, the insulating film portion which is installed on the mounting portion 12 of the heat sink 10, and is wrapped around the outer side of the PTC heater 20 to the outside of the PTC heater 20 that generates heat at a predetermined temperature when the power supply ( 40) is installed.

The insulating film portion 40 is installed to be wrapped around the outside of the PTC heater 20, as shown in the figure, one side is fused and sealed in the form of a bag and the other side is formed so that the wire connected to the heater electrode comes out .

Therefore, since the insulating film portion 40 is installed to be wrapped around the outside of the PTC heater 20 as described above, it is excellent in insulation resistance, heat resistance and thermal conductivity without the installation of a separate insulation case, thereby maximizing the heat dissipation effect It is possible to have a stable structure without fear of breaking the heat resistance and insulation resistance of the film with the short circuit and the passage of a long time.

On the other hand, the bottom of the PTC heater 20 installed in the mounting portion 12 of the heat sink 10 in a state that is positioned so that the PTC heater 20 more firmly supported and fixed to the mounting portion 12 fixed plate ( 30) is installed.

As shown in the drawing, the fixing plate 30 is formed to have an inner diameter size of the stepped portion 16 that is configured as both sides of the mounting portion 12, and a close support means 31 is formed on the upper surface of the body.

In addition, the close support means 31 is cut in both sides so as to strongly support the PTC heater 20 as the upper installation groove 15 in a state located inside the stepped portion 16 of the heat sink 10. It is composed of a saddle-shaped bead 32 in the form of a leaf spring that protrudes upward and maintains a predetermined tension.

In addition, the beads 32 may be formed in plural numbers at predetermined intervals and arrangements rather than one as shown in the drawing to improve the close support effect of the PTC heater 20.

In this case, it is preferable that a plurality of PTC heaters 20 are formed so as to easily support the PTC heaters 20 even in a configuration in which a plurality of applications of the PTC heaters 20 are installed.

On the other hand, the embossed portion 33, which is a close support means 31 is formed on the front and rear surfaces of the bead 32 formed to have a predetermined tension to the body upper center portion of the fixing plate 30.

Since the embossing portion 33 is formed to more firmly support the front and rear surfaces of the heater electrode of the PTC heater 20 and the PTC heater 20, the bead 32 and the front and rear of the body center portion Through the protruding embossed portion 33, the PTC heater 20 can be firmly fixed to the inside of the mounting portion 12 of the heat sink 10 while being firm.

Therefore, although the conventional assembly structure of the heat sink and the PTC heater is relatively complicated and there is a problem that the thermal efficiency is lowered even after installation, the present invention provides the heat sink 10 and the PTC heater 20 in the mounting portion 12 in the stepped portion 16. Using a fixed plate 30 and simple yet firmly fixed, the heat radiation effect will be maximized.

In addition, since the assembly labor and work labor is reduced as described above, it is possible to improve the reliability and price competitiveness of the overall product.

On the other hand, the PTC heater and heat sink structure for the present invention described so far can be applied to both the heat dissipation unit and the heater unit configuration in the general electrical and electronic components group, depending on the scope of application to all the various product groups Since it can be used, for example, it can be applied to all the products that require the heat dissipation unit and the heater unit, such as the configuration of the heater unit required for hot air drying of the food waste treatment apparatus, it will be found that it is included in the configuration of the present invention.

According to the configuration of the present invention, first, it is possible to see a high temperature heat dissipation effect with low energy consumption due to maintaining adhesion and stability when mutual assembly of the PTC heater and the heat sink.

Second, it is possible to improve productivity and secure stable quality.

Third, a plurality of PTC heaters can be easily adjusted and used according to their capacity.

Fourth, by using the PTC heater built in the insulation film, it is possible to maximize the thermal conductivity efficiency.

Fifth, it is possible to ensure the stability of the ground electrode of the PTC heater, thereby improving the durability of the product.

Sixth, it is possible to improve the price competitiveness for improving productivity due to the reduction of parts labor.

Seventh, since the PTC heater electrode portion and the wiring portion are inserted into the bag-shaped insulating film portion, it is possible to block the risk of short circuit and electric shock.

In addition, since it is applicable to both the energy consumption and the heater and the heat dissipation part of the electrical and electronic products, it is possible to maximize the utilization of the product.

Therefore, it is a very useful invention that can increase the reliability of the product.

1 is an exploded perspective view showing a configuration of the present invention.

Figure 2 is a front sectional view showing a state in which the PTC heater is assembled with the heat sink in the present invention.

Figure 3 is a front sectional view showing a state in which the PTC heater is mutually assembled with the heat sink by the configuration of the present invention.

* Description of the major symbols in the drawings *

10-heat sink 11-heat sink

12-Mounting 13-Entry groove

14-Jam Jaw 15-Mounting Groove

16-Step 17-Bending Groove

20-PTC Heater 30-Mounting Plate

31-support means 32-beads

33-embossing part 40-insulating film part

Claims (6)

delete delete A heat dissipation plate 10 having a plurality of heat dissipation fins 11 in an upright direction at regular intervals, and having a mounting portion 12 integrally formed at the bottom of the body; A PTC heater 20 installed at the mounting portion 12 of the heat sink 10 and configured to generate a constant temperature at a predetermined temperature when power is supplied; Fixing plate 30 is installed on the bottom surface of the PTC heater 20, the support plate 31 is formed on the upper surface of the body so that the PTC heater 20 is fixed to the mounting portion 12 of the heat sink 10 and ; In the mounting portion (12) consisting of an installation groove (15) for receiving the PTC heater (20) from the inside toward the upper portion of the access groove (13) open to both sides of the heat sink (10); Concentrates the thermal conductivity radiated to the heat dissipation fin 11 in the installation groove 15, so as to block the heat dissipation to the outside, within the range not to escape the heat dissipation fin 11 from the bottom of the heat dissipation fin 11 of the heat sink 10 PTC heater and heat sink structure for an electrical appliance, characterized in that the stepped portion 16 is formed. The method according to claim 3, characterized in that the insulating film portion 40 is installed on the mounting portion 12 of the heat sink 10, wrapped around the outside of the PTC heater 20 is heated to a predetermined temperature at the time of power supply PTC heater and heat sink structure for electrical appliances. The method according to claim 3, wherein the close support means 31 of the fixing plate 30 is characterized in that it consists of a leaf spring-shaped saddle-shaped beads 32 which can maintain a predetermined tension while projecting upward while cutting both sides in the upper portion of the body PTC heater and heat sink structure for electrical appliances. The method according to claim 3, PTC support and heat sink structure for electrical appliances, characterized in that the close support means 31 of the fixing plate 30 is composed of an embossed portion 33 formed in front and rear of the bead 32.