KR100735104B1 - Structure of heater for hair iron having onebody type of heating unit and plate - Google Patents

Abstract

A heater structure for a hair iron is provided to maximize durability and heat efficiency of a heating element by integrally connecting the heating element to a heating plate using a high-heat conducting layer and a sealing layer. The heater structure includes: a high-heat conducting layer(12) transferring a heat generated from a heating element(11) to a heating plate(10), and attaching the heating element to the heating plate; a sealing layer(14) preventing the heat transferred to the high-heat conducting layer from leaking, and attaching the high-heat conducting layer to the heating plate; and a temperature sensor(15) installed on one portion that a conducting wire of the heating plate passes.

Description

Structure of heater for hair iron having one body type of heating unit and plate}

1 is an exploded perspective view of a conventional PTC heater

2 is an exploded perspective view of a conventional metal sheet heater

3 is an exploded perspective view of a conventional ceramic heater

Figure 4 is an exploded perspective view showing a coupling structure of the heater and the heating plate of the conventional hair iron

5 is a perspective view showing a coupling structure of a heater and a heating plate using a conventional platinum thick film heating element

6 is a plan view showing a preferred embodiment of the present invention

7 is a cross-sectional view showing an installation of the present invention.

[Description of Symbols for Main Parts of Drawing]

10: heating plate 11: heating element

12, 16: high thermal conductive layer 13: hot plate

14, 17: sealing layer 15: temperature sensor

The present invention relates to a heater structure for a hair iron having an integrated structure of a heating element and a heating plate,

More specifically, the present invention relates to a heater structure for a hair iron having an integrated structure of a heating element and a heating plate which maximize the durability and thermal efficiency of the heating element by integrally coupling the heating element to the heating plate using the high thermal conductive layer and the sealing layer.

In the case of the conventional hair iron, the heating plate is heated by using a heating element of PTC, a coil, and a planar type with AC power by using a power line. Therefore, a power connector to which a power cord should be inserted should always be used. Beauty tools that should be in the mainstream is being limited spatial and time when using.

In order to solve these problems, portable hair irons using these heating elements and rechargeable batteries and gas-charged hair irons have emerged.

However, in the case of the hair iron having a PTC, a coil, and a heating heating element having a planar heating method, the heating plate that can be raised with a rechargeable battery is 100 to 120 ° C. or less due to the high resistance of the heating heating elements. Since the heating time is lower than ˜180 ° C. or the temperature rises to the final temperature for several ten minutes, it is practically impossible to drive the hair iron to a portable battery using the conventional heating heating element.

In addition, in the case of a gas-filled type, there is a inconvenience in that a gas cartridge needs to be purchased separately, difficult to control at a constant temperature, and there is a problem such as a risk of gas explosion.

As shown in FIG. 1, a PTC heating heating element is generally used for an electric hair iron, and a substrate 21 and an electrode 22 are formed on the heating heating element 20, and an insulating layer 23 is formed outside thereof. It is to provide a structure.

The general temperature-resistance characteristic of the PTC heating heating element 20 shows about 100 ° C. or less under 100 ° C., but the resistance value rapidly increases as the temperature increases.

Comparing the power consumption at 4.5V and 220V when the resistance value is about 100Ω, it is 0.20watt at 4.5V and about 480watt at 220V.

This can be used as a wired power source (110V or 220V), but it can be seen that it is difficult to drive the power supplied by a portable charger.

In addition, although the resistance value can be lowered to several orders of magnitude by changing the raw material of the PTC element or structural improvement to drive the low voltage of the portable battery, a temperature sufficient for hair shaping using the power source of the portable rechargeable battery (150 to 200 It is difficult to implement a heating heating element having a resistance value of 0.5 to 1.0 mA and a high current density to produce a power consumption of about 20 to 30 watts required to increase to 20 ° C).

 For example, even if there is a PTC device having a resistance of 3 kW with a 6 V power supply using six 1.5 V batteries, it is almost impossible to raise the temperature of 150 to 200 ° C with about 12 watts of power consumption.

In the case of using an electric hair iron type heating heating element that mainly uses a high voltage power source of 110V or 220V, a portable heating element or coil type heating heating element may be used. However, in this case, the resistance value is lower than that of a PTC heater. However, since there are limitations on the heating element area and volume along with durability problems due to high current density, there are difficulties in actual implementation.

2 illustrates a structure of a heating heating element using a metal (SUS. NiCr alloy, Ni-based, tungsten) thin plate structure, in which a terminal 24 is installed in the heating heating element 20 and a heating plate 21 is installed at both sides thereof. To provide.

The heating heating element having such a structure is also high in manufacturing cost, and the surface heating occurs at high temperature for a long time, so it is not good in terms of thermal efficiency. .

3 is a structure using a heating heating element 30 of a ceramic such as alumina, and a heating circuit 31 such as silver, gold platinum, palladium, tungsten, etc. is printed in a paste form on alumina with alumina therebetween, and then fired at high temperature. I made it.

This structure has advantages in terms of simplification of printing process. However, high purity alumina plate should be used to increase thermal efficiency, which leads to an increase in manufacturing cost, which is more economical than PTC or coiled hair iron. It forms a high price.

In addition, since the resistance value at the driving temperature of the hair iron is large, the thermal efficiency is lower than that of the PTC heating heating element. In addition, due to the characteristics of the ceramic, the impact is also weak, which shows low durability.

In addition, since the conventional hair iron has a heat generating structure on both plates, the internal structure is complicated by connecting the upper and lower heating heating elements and the circuit part with long conductors, and there are difficulties in the manufacturing process.

In addition, due to the heat generated by the resistance of these long conductors, there is a problem that the heat efficiency is lowered and other parts of the iron other than the handle portion and the heater become hot.

4 shows a coupling structure of a heater and a heating plate of a conventional hair iron, and provides a structure in which the heater 13 is inserted into the heating plate 10.

This coupling structure has the advantage that the heat generated from the heater is directly transmitted to the hot plate to quickly and efficiently raise the temperature of the heat generating plate, it is easy to control the temperature of the heat generating plate.

However, since it depends on the electric insulation characteristics of the heater itself, it can be used to test the withstand voltage test (a test for determining safety by applying 1,000 to 4,000 AVC voltage to the product) and the leakage current test (withstand voltage test or measuring the amount of current leaked during use of the product). The electrical safety standards such as test)

Since the fixing spring fixes the heater directly by pressing it, the surface of the heater in contact with the spring is locally stressed and easily broken at high temperatures, and has a weakness in mechanical shock at room temperature and high temperature,

When the heater is broken, a metal heating element inside the heater is exposed to the outside, such that there is a risk of electric shock.

FIG. 5 is a patent application filed by the present applicant, which is a patent registration No. 614195 (registered on Aug. 11, 2006), which shows a coupling structure of a heater and a heater and a heating plate using a platinum thick film heating element, and has a high thermal conductivity ceramic or electrical insulating property. In the interior of the heating plate 30 made of a metal material having a coating film in the both sides in the longitudinal direction of the electrical insulating layer 32 which is provided in the interior of the electrode pad 31 is installed in the electrical insulating layer 32 It consists of an electrode pad 31 installed in the longitudinal direction on the heating plate 30 on both sides of the platinum thick film heating element 33 having a high thermal conductive layer 34 therein, and a thermistor 35 for measuring and controlling the temperature of the heater. .

However, the coupling structure of the heater and the heating plate was a suitable structure when using the battery wirelessly without directly connecting the power source, and it was not preferable when the power source was directly connected because it was expensive.

The present invention has been made to solve the above-mentioned drawbacks, and an object of the present invention is to provide a heater that maximizes the durability and thermal efficiency of the heating element integrally coupled to the heating plate by using the high heat conductive layer and the sealing layer.

According to the accompanying drawings, preferred embodiments of the present invention made for this purpose will be described in detail.

The heating element 11 is installed inside the heating plate 10 made of a metal material to have a U-shape.

The heating element 11 can use a hot wire or a thin plate, and uses a metal and alloy hot wire or thin plate, such as nichrome, iron chromium, aluminum, copper, gold, silver, platinum, and tungsten.

The resistance value of the heating element 11 is set in principle by adjusting the type, length, width, thickness or density of the heating element (11).

The heating element 11 installed on the heat generating plate 10 provides a function of transferring the heat generated by coating the high thermal conductive layer 12 to the heat generating plate 10, and prevents cracking or destruction in thermal shock.

The high thermally conductive layer 12 may be a porous ceramic such as alumina (Al ₂ O ₃ ) having high thermal conductivity, or a composite material using a metal powder having an electrically insulating coating film.

The composite material using porous ceramics or metal powder is prepared in the form of coating liquid or paste so that the heating element 11 and the heating plate 10 are integrally coupled to the high thermal conductive layer 12 using a printing, discharging, or brushing process.

The high thermally conductive layer 12 is wrapped with a sealing layer 14 that suppresses a phenomenon in which heat transferred from the heating element 11 to the high thermally conductive layer 12 escapes to outside air and increases heat transfer efficiency toward the heating plate 10. .

The sealing layer 14 uses a ceramic or glassy material that forms a dense coating film, or a polymer material having high heat resistance.

The material is manufactured in the form of a coating liquid or paste to bond the heating element 11 and the heating plate 10 to the high thermal conductive layer 12 using a printing, discharging, or brushing process.

The conducting wire 18 is provided in one direction of the heating plate 10 provided with the sealing layer 14, and the temperature sensor 15 is provided at one portion of the conducting wire 18, and the temperature sensor 15 The high thermally conductive layer 12 and the sealing layer 14 are formed in turn so that the temperature sensor 15 is integrally installed on the heating plate 10.

According to the present invention having the above configuration, the heat generator 11 is installed in the heat generating plate 10 in the shape of a fin, and then the high heat conductive layer 12 and the sealing layer 14 are formed at the outside thereof to be fixed integrally.

The heat generator 11 has a constant resistance as a heat source for generating heat, and generates heat when a constant current is applied thereto.

The heating element 11 is preferably formed of a hot wire or a thin plate, and the resistance value can be freely set by adjusting the type, length, width, thickness or density of the heating element.

The high thermally conductive layer 12 surrounding the heating element 11 provides high thermal conductivity functionality for efficiently transferring heat generated from the heating element 11 to the heating plate 10, and the heating element 11 generates high heat instantly. It provides a thermal shock absorbing function that efficiently transfers heat without causing cracking or breaking even in the thermal shock generated by the thermal shock.

The high thermal conductive layer 12 is manufactured in the form of a coating solution or a paste using a porous ceramic material such as alumina having high thermal conductivity or a metal powder having an electrically insulating coating film, and using a printing, discharging, or brushing process. Thus, the heating element 11 and the heating plate 10 are integrally bonded.

The sealing layer 14 surrounding the high thermal conductive layer 12 is to increase the heat transfer efficiency toward the heating plate 10 while suppressing the phenomenon that the heat transferred from the heating element 11 to the high thermal conductive layer 12 escapes to the outside air. .

In addition, the heat generating element 11 together with the high thermal conductive layer 12 is prevented from being exposed to external air or moisture to prevent damage due to oxidation or corrosion of the heat generating element 11.

The sealing layer 14 uses a ceramic or oil-based material forming a dense coating film, or a polymer material having high heat resistance.

The ceramic, glass, or polymer material is manufactured in the form of a coating liquid or a paste, and the high heat conductive layer 12 is coated using a printing, discharging, or brushing process to bond the heating element 11 and the heating plate 10 integrally.

The power is supplied through the heating element 11 from the outside to generate heat, and the heat transfer is effectively performed by integrally combining the high heat conductive layer 12 and the sealing layer 14 so as to be directly transmitted to the heating plate 10. ) Is to improve the durability.

In addition, the temperature sensor 15 installed in one portion of the conductive wire 18 also allows the high thermal conductive layer 16 and the sealing layer 17 to be integrally formed to faithfully perform the role of the temperature sensor 15. To make it possible.

The present invention effectively installs a heating element inside the heating plate and transfers the heat generated by the heating element to the heating plate through a high heat conductive layer that effectively transmits the high heat of the heating element, and cracks or fractures are caused by thermal shock generated by instantaneous high heat generation. It doesn't happen.

According to the present invention, the sealing layer surrounding the high thermally conductive layer prevents heat transferred from the heating element to the high thermally conductive layer from escaping to the outside air, and the heating element and the high thermally conductive layer are not directly exposed to external air or moisture to oxidize the hot wire. It is to prevent damage caused by corrosion.

The present invention is to maximize the durability and efficiency of the heating element by integrating the heating element integrally with the heating plate using a high thermal conductive layer and a sealing layer.

Claims (4)

In the heater for a hair iron made of a heating plate 10 is provided with a heating element (11) that generates heat from the power supplied from the outside, A high thermal conductive layer 12 transferring heat generated from the heat generating element 11 to the heat generating plate 10 and bonding the heat generating element 11 to the heat generating plate 10; A sealing layer 14 for preventing the heat transferred to the high thermally conductive layer 12 from escaping to the outside air and bonding the high thermally conductive layer 12 to the heating plate 10; Heater structure for a hair iron having an integrated structure of the heating element and the heating plate, characterized in that the temperature sensor 15 is installed in one portion of the heating plate (10) passing through the heating plate (10). The method of claim 1, wherein the high thermal conductive layer 12 is a composite material using a porous ceramic such as alumina having a high thermal conductivity or a metal powder having an electrically insulating coating film in the form of a coating liquid or paste to use a printing, discharging or brushing process. Heater structure for a hair iron having an integrated structure of the heating element and the heating plate, characterized in that the bonding. The method of claim 1, wherein the sealing layer 14 is made of a ceramic, glass or polymer material having a high heat resistance to form a dense coating film in the form of a coating liquid or paste to bond using a printing, discharging or brushing process, etc. Heater structure for a hair iron having an integral structure of a heating element and a heating plate. The hair iron of claim 1, wherein the temperature sensor 15 is integrally bonded to the heat generating plate 10 by the high thermal conductive layer 16 and the sealing layer 17. Heater structure.

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