KR100945200B1 - Panel type electric heater - Google Patents

Abstract

The present invention relates to a flat plate heat transfer device comprising a power supply unit for supplying power, a heat transfer unit for generating heat by receiving power from the power supply unit, a metal wire and a lead wire connecting the power supply unit and the heat transfer unit, and a metal plate. A flat plate heat transfer apparatus covering a heat transfer part and a lead wire and including a heat generation part for transferring heat generated from the heat transfer part to the outside, wherein a through hole penetrates in a longitudinal direction is formed and the lead wire is inserted into the through hole. Absence; A ceramic insulating material filled in the protective member to prevent the lead wire from contacting the protective member, and further comprising a heat insulating device to prevent deformation or breakage of the insulating material generated by heat generated from the heat transfer part and external impact. There is an effect that can improve the reliability.

Flat Plate Ceramic Insulated Lead Wire

Description

Flat type electric heater

The present invention relates to a flat plate heat transfer device, and more particularly, to insert a lead connected to a heating wire inside the heat transfer device in a protection member filled with ceramic insulation to insulate the lead, and to combine the reinforcing rod with the heat generation unit. It is about.

As shown in FIG. 1, a general heating device includes a power supply unit 10 for supplying power and a heat transfer unit 20 that generates heat when electricity flows (generally, a heating wire such as nichrome wire), a power supply unit 10, and a heat transfer unit. The lead wire 30 connecting the 20, the heat generating portion 40 for transferring the heat generated from the heat transfer portion 20 to the outside.

By the way, in recent years, when it is possible to reduce the thickness of the heating device as much as possible, it is difficult to insulate the lead wire, and in particular, when the heating device is made into a thin flat plate, there is a problem that the metal plate forming the heat generating part is bent by heat.

Conventional methods for insulating lead wires include Korean Utility Model Registration No. 0171999 "Lead wire connector of electric ondol heater". In the above design, the moisture-proof cap having a space part is coupled to the connection part of the lead wire and the heating wire, and after the silicon is injected into the space part, the outside has a structure of fixing by hitting the metal binding tube in a state of being coupled.

However, such a structure has a problem that the leakage may occur due to the penetration of moisture is not completely sealed.

In order to solve this problem, Korea Utility Model Registration No. 251441, "Connecting Structure of Heating Wire and Lead Wire", removes the insulation coating of the lead wire and heating wire, fixes it with a clamp, and combines an insulation coating material made of PVC, synthetic resin, rubber, and silicone rubber to the outside. This prevents the penetration of moisture.

In addition, the Republic of Korea Publication No. 2003-0087254 "connection structure of the heating mat for electric mats and its connection method" is fixed to the clamp and then covered with an insulating tube and the heat-shrink tube is coupled to the outside is configured to insulate.

As described above, the conventional insulation method uses a method of coating a coating material made of a polymer. However, the lead wire is not only exposed to the external high temperature generated in the heat transfer part, but the heating wire and the lead wire of the heat transfer part are directly connected, so that the heat generated from the heat transfer wire is transferred directly to the lead wire, thereby causing the polymer coating material to carbonize. It has become a factor to reduce the reliability of the heat transfer device.

In order to prevent such a problem, a coating wire made of a ceramic material may be used, but there is a problem in that brittleness occurs due to external impact due to brittleness of the ceramic itself.

SUMMARY OF THE INVENTION The present invention has been invented to solve the above problems, and it is a main object of the present invention to provide a highly reliable plate type heat transfer device capable of maintaining insulation of lead wires even when heat and impact applied to the lead wires.

In addition, another object of the present invention is to provide a flat plate type heat transfer device capable of preventing the metal plate constituting the heat generating portion from bending by heat generated in the heat transfer unit.

The present invention consists of a power supply unit for supplying power, a heat transfer unit for generating heat by receiving power from the power supply unit, a lead wire for connecting the power supply unit and the heat transfer unit, and a metal plate to achieve the above object A flat plate heat transfer apparatus covering a heat transfer part and a lead wire and including a heat generation part for transferring heat generated from the heat transfer part to the outside, wherein a through hole penetrates in a longitudinal direction is formed and the lead wire is inserted into the through hole. Absence; It is a technical gist of the flat plate heat transfer device, characterized in that it further comprises a; ceramic insulating material filled in the protective member to prevent the lead wire from contacting the protective member.

According to a preferred embodiment the ceramic insulating material is characterized in that the magnesium oxide (MgO) powder.

According to a preferred embodiment, the protective member is characterized in that the silicon binder is filled at both ends to prevent the ceramic insulating material from flowing out to the outside.

According to a preferred embodiment, the heat generating portion is bent at the end to form a "-" or "c" shape.

According to a preferred embodiment the heat generating unit is characterized in that it is coupled to one or more parallel reinforcing rods to suppress the bending.

According to a preferred embodiment the lead wire is characterized in that to form a screw thread at the end to be screwed with the power supply or heat transfer.

According to a preferred embodiment, the ends of the lead wire and the heat transfer part are inserted into a thin sleeve made of the same material as the lead wire, and the lead wire and the heat transfer part are coupled by applying pressure to the sleeve.

According to the present invention, a lead wire is inserted into the protection member, and a ceramic insulating material is filled between the lead wire and the protection member, so that the insulation of the lead wire is maintained even when heat and impact are applied, thereby improving the lifespan and reliability of the heat transfer device. .

In addition, by bending the metal plate constituting the heat generating portion and by combining the reinforcing rod to prevent the metal plate is bent by heat has the effect of improving the durability of the product.

Hereinafter, with reference to the drawings will be described in detail with respect to the plate-type heat transfer apparatus according to an embodiment of the present invention. 2 is a perspective view of a protection member of a flat plate heat transfer apparatus according to an embodiment of the present invention, and FIG. 3 is a cross-sectional view of an insulated lead wire according to an embodiment of the present invention.

According to the drawings it can be seen that the plate-type heat transfer device according to an embodiment of the present invention includes a protective member 32 and a ceramic insulating material 34.

The protective member 32 and the ceramic insulating material 34 surround the lead wire 30 to insulate the lead wire 30 and to protect the lead wire.

First, the protective member 32 will be described. The protective member 32 surrounds the lead wire 30 to prevent the lead wire 30 from being damaged or deformed by an external impact or pressure. To this end, the protection member 32 has a circumferential shape as shown in FIG. 2, and a through hole 33 penetrates along the longitudinal direction. However, the present invention is not limited to the columnar form, and may be manufactured in various forms such as a columnar shape or a columnar shape having an elliptical cross section. The protective member 32 is formed to be shorter than the length of the lead wire 30 so that both ends of the lead wire 30 can be exposed to the outside.

Here, the protection member 32 uses a metal material such as SUS (stainless steel) having high strength to withstand the impact from the outside. However, it is also worth considering using a material resistant to heat and impact, such as engineering plastics instead of the metal protection member 32.

Next, the ceramic insulating material 34 will be described.

The ceramic insulating material 34 is filled in the protection member 32 to prevent the lead wire 30 from contacting the protection member 32 to cut off current from the lead wire 30 to the protection member 32 to insulate the insulation. To achieve. This is to prevent this because the protection member 32 is mainly made of a metal material such as stainless steel as in the embodiment of the present invention because the current flows when the lead wire 30 and the protection member 32 is in contact.

The ceramic insulating material 34 of the present invention uses magnesium oxide (MgO) powder. However, any ceramic powder may be used as long as it is an insulating component in addition to the above magnesium oxide (MgO).

At this time, in order to prevent the powder from leaking outside the protective member 32, both ends of the protective member 32 are sealed by adhesive or the like. In the embodiment of the present invention, the silicone binder 36 is used as the adhesive, but any polymer may be used as long as it is a heat-resistant and insulating component in addition to the silicone binder 36.

Accordingly, as shown in FIG. 3, the ceramic insulation 34 is positioned around the lead wire 30, and the protection member 32 surrounds the outside thereof.

Therefore, the protection member 32 prevents the breakage of the lead wire 30 due to an external shock, and the ceramic insulating material 34 filled therein insulates the electrical current and prevents a short circuit.

Hereinafter, with reference to the accompanying drawings will be described in detail the operation and effect of the flat plate heat transfer device according to an embodiment of the present invention.

Figure 4 is an exploded perspective view of a flat plate heat transfer apparatus according to an embodiment of the present invention.

In the flat plate type heating apparatus according to the embodiment of the present invention, as shown in FIG. 4, a mica plate 24 is disposed on an upper side of the heating unit 40 made of a metal plate, and a heating line 22 is disposed on the upper side. After connecting the lead wire 30 to the end of the heat transfer part 20, the mica plate is placed on the upper side of the heat transfer part 20, and the heating part 40 made of a metal plate is covered on the mica plate.

Here, the mica plate installed on the upper and lower sides of the heat generating unit 40 may have different thicknesses according to the purpose of the flat plate heating device. In other words, when the upper and lower surfaces are all heated, both sides use a thin mica plate, and when only one side is heated, the heating surface uses a thin mica plate and the opposite side uses a thick mica plate to block heat.

Here, the heat generating portion 40 made of the metal plate is bent the edge end of the "b" shape to suppress the deformation in the vertical direction. At this time, the "b" shape instead of the "b" shape may be bent.

In addition, the heating unit 40 is coupled to the reinforcing rod 44. The reinforcing rods 44 are coupled along the longitudinal direction of the heat generating unit 40, but are respectively coupled to each side edge of the heat generating unit 40, and a plurality of the reinforcing bars 44 are spaced apart at appropriate intervals therebetween and arranged in parallel with each other. The reinforcing rod 44 is coupled to the surface of the heat generating portion 40 to suppress the deformation of the heat generating portion 40 by heat to prevent the bending.

Since the plurality of reinforcing rods 44 are coupled to the heat generating unit 40 spaced apart from each other as described above, in the embodiment of the present invention, a heating wire is disposed between the reinforcing rods 44 and the lead wires 30 are connected to the ends thereof, respectively. Doing. At this time, in order to connect the lead wire 30 and the heating wire 22, a male screw is formed at the end of the lead wire 30, as shown in FIG. The end of the heating wire 22 is wound around the male thread of the lead wire 30 so that the lead wire 30 and the heating wire 22 are not separated.

However, instead of screwing, as shown in FIG. 6, the sleeve 50 is formed of the same material as that of the lead wire 30 so that the end of the lead wire 30 and the heating wire 22 is wrapped around the sleeve 50. The sleeve 50 may be crushed by applying pressure to the sleeve 50 to press the heating wire 22 toward the lead wire 30 to be coupled.

The other end of the lead wire 30 is protruded to the outside of the heating plate to be connected to the power supply unit 10. In the exemplary embodiment of the present invention, the other end of the lead wire 30 is configured to be exposed to the outside. However, the terminal of the power supply unit 10 may be inserted into the heat generating plate and connected to the inside of the heat generating plate.

The plate-type heat transfer device configured as described above surrounds the ceramic insulating material 34 and the ceramic insulating material 34 resistant to heat to prevent leakage of the insulating material 34, and surrounds the lead wire 30 with a protective member 32 resistant to impact. Since the lead wire is not exposed to external high temperature, even if heat generated from the heating wire 22 is transferred to the lead wire 30, no damage or deformation occurs, and the edge of the heat generating plate made of a thin metal plate is bent and the reinforcing rod 44 is disposed inside. The combination of a number of) prevents the bending to improve the durability.

1 is an exploded perspective view of a conventional flat plate heat transfer device

2 is a perspective view of a protective member according to an embodiment of the present invention

3 is a sectional view of a lead wire with insulation according to an embodiment of the present invention

4 is an exploded perspective view of a flat plate heat transfer apparatus according to an embodiment of the present invention

5 is a diagram showing a method of joining a lead wire and a heating wire.

6 shows a method of joining another lead wire and a heating wire

<Description of Symbols Used in Main Parts of Drawing>

10: power supply unit 20: electric heating unit

22: heating wire 24: mica board

30: lead wire 32: protective member

33: through hole 40: heat generating portion

44: reinforcing rod 50: sleeve

Claims (9)

A power supply unit 10 for supplying power, a heat transfer unit 20 for generating heat by receiving power from the power supply unit 10, and a lead wire for connecting the power supply unit 10 and the heat transfer unit 20 to each other. 30 and a flat plate heating device including a heat generating part 40 formed of a metal plate to cover the heat transfer part 20 and the lead wire 30 and to transfer heat generated from the heat transfer part 20 to the outside. To A protection member 32 through which a through hole 33 penetrates in a longitudinal direction and into which the lead wire 30 is inserted; And a ceramic insulating material 34 filled in the protection member 32 to prevent the lead wire 30 from contacting the protection member 32. The protective member 32 is filled with a silicon binder 36 at both ends of the protective member 32 to prevent the internal ceramic insulating material 34 from leaking to the outside, and the heat generating part 40 has a terminal end. B-shaped or "c" shape is bent to form a flat heat transfer device, characterized in that the reinforcing rods 44 are placed one by one on both side edges of the heat generating portion (40). The method of claim 1, The ceramic insulating material 34 is a flat plate heat transfer device, characterized in that the magnesium oxide (MgO) powder. delete delete delete delete The method of claim 1, The heating unit 40 is a plate-type heat transfer device, characterized in that the one or more reinforcing rods 44 are placed side by side spaced apart from each other between the reinforcing rods 44 of both edges. The method of claim 1, The lead wire 30 is a flat plate type heat transfer device, characterized in that to form a screw thread (38) at the end to be screwed with the power supply unit (10) or the heat transfer unit (20). The method of claim 1, Ends of the lead wire 30 and the heat transfer part 20 are inserted into a thin sleeve 50 made of the same material as the lead wire 30 and apply pressure to the sleeve 50 to connect the lead wire 30 and the heat transfer part 20. Flat plate heating device characterized in that coupled.

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