KR20120116381A - Method of producing heat plate for ceramic heater - Google Patents

Abstract

PURPOSE: A manufacturing method of a ceramic heater embedded heat radiation plate is provided to maximize the heat storage properties of ceramic by integrally forming a ceramic heat radiation plate and a ceramic heater. CONSTITUTION: A metal color formation ion is added into alumina basic composition. The mixture of the metal color formation ion and the alumina basic composition are mixed in a ball mill for 48 hours. Solvent uses organic solvent and a PVB-binder. A central particle diameter of the solvent is 0.3μm. The solvent is in a slurry state. The air in the slurry is removed using a defoamer. The thickness of a green sheet is 600 to 1000μm in a tape casting method. A resistance patterning green sheet and the green sheet are compressed by pressing.

Description

Ceramic Heater Insert Heat Dissipation Plate Manufacturing Method {METHOD OF PRODUCING HEAT PLATE FOR CERAMIC HEATER}

The present invention relates to a method for manufacturing a ceramic heater insert type heat dissipation plate, and more particularly, to a ceramic heater used for a cosmetic machine such as an ancient machine for straightening and shaping human hair and a far-infrared ceramic material having high emissivity of ceramic composition on a heat dissipation plate. Therefore, the heat transfer mechanism of ceramics relates to a method of manufacturing a ceramic heater insert type heat dissipation plate which has a large specific heat by radiation and conduction, heat recovery ability when hair is formed, and heat dissipation is not easily performed once the temperature is raised, and maintains a proper temperature on the hair.

Hair curling iron is a beauty tool for applying heat to human hair to straighten hair or to produce various hair styles. Recently, hair curlers are widely used in not only beauty salons but also homes.

However, most of the curling irons use AC or DC power. In addition, since the user needs to be connected to a power source and an electric wire, there is a problem in that it is inconvenient to use the electric wire connected to the iron when the user molds the hair.

In order to solve this problem, the present inventors have developed a ceramic heater for AC and DC, which is widely used and widely used to charge and use without a wire.

In general, ceramic heating elements are currently being used in various industrial fields because light and small parts are easily implemented because the thermal efficiency of the ancient times, such as heat exothermic rate, calorific value, etc. in cosmetic machines is superior to rapid heating elements.

Ceramic heaters are applied to ancient times by heating when forming human hair, but heat sinks generate heat by bringing ceramic heaters close to the bottom of aluminum heat sinks, so that the heat transfer mechanism uses the conductivity of the metal part. Have

Conventional antique high-temperature ceramic heating element is a pair of handle portion 1 that rotates within a predetermined angle range around the hinge shaft 16, as shown in Figures 1 to 2 attached to, and extending from the handle portion A pair of heat generators (5), each of which is built in each of the two parts, generates heat by a power source, a charging terminal unit (13) for supplying and charging power to the heat generator, and power supply to the heat generator; A ceramic heater including an operation button 3 and having a very high temperature rise temperature is used as the heat generator 5.

In the conventional heating device 5 using the ceramic heater, as shown in FIGS. 2 and 3, the ceramic heater 7 generates heat by external power supply, and the ceramic heater 7 is mounted on one side. A heat sink 9 for dissipating heat generated from the ceramic heater to the outside, a support plate 8 for supporting the ceramic heater 7 inserted into the heat sink 9, and an external power source to the ceramic heater 7. It consists of the electric wire 10 which supplies.

That is, the conventional ceramic heating element structure for the ancient times is a structure in which far-infrared rays are emitted by forming a heating plate formed by compression-molding an aluminum material and a ceramic coating layer on the surface of the aluminum heat sink.

The ceramic coated aluminum heat sink is manufactured by inserting a conventional ceramic heater into a plate-shaped spring.

Such a structure has a problem that it is inconvenient in continuous operation during hair forming by easily rising and falling easily at elevated temperature, and the ceramic coating layer is peeled off by repeatedly contacting the hair containing moisture when it is already used, and has a problem of low thermal efficiency.

In addition, thermal fatigue causes crack peeling due to the double material of aluminum metal and ceramic coating layer, and ceramic heater is in close contact with the metal heat sink, resulting in electric shock due to leakage current due to insulation breakdown of ceramic heater due to the difference in thermal expansion coefficient. There is an example.

In the conventional ceramic heater manufacturing method, as shown in the attached 4 to 5 to make a green sheet (Green Sheet) 21 of a soft state using a ceramic slurry (Slurry), and titrate the green sheet 21 After cutting to size, the surface of the resistor 22 is printed using metal paste, and the green sheet 21 on which the resistor 22 is printed and the green sheet 21 on which the resistor 22 is not printed are laminated ( 23) and hot pressing 24 to produce a hot baking (25) in a wet reducing atmosphere at a temperature of 1400 ~ 1700 ℃. Of course, the green sheet 21 is sintered to a hard state in the firing 25 process, and finally, the lead wire 26 is fixed to the resistor 22 to manufacture a ceramic heater. In order to compensate for the above disadvantages, a method of manufacturing a heating plate-integrated ceramic heating element, which is disclosed in Patent Application No. 10-2004-0020497, is proposed. However, this method uses six layers of alumina substrate sintered at high temperature in an oxidizing atmosphere. As an integrated ceramic heating element, each alumina plate is cut by sintering the substrate to a predetermined size by laser cutting method, and printed resistance patterns on Mo-Mn and Mo-W-Mn pastes on one side, and then the sintered substrate is coated with glass adhesive. (Glass Fuit).

In order to compensate for the disadvantages of the conventional aluminum heat sink, the ceramic heating element and the heating plate are shown to be integrally formed as shown in FIGS. 6 to 8, which is a sintered ceramic sintered substrate 31 provided with a lower plate 32. ) And an upper plate 33, and a resistor is printed on either the lower plate 32 or the upper plate 33 to form a ceramic heater 35.

The lower plate 32 and the upper plate 32 made by integrating the ceramic heater 35 at a high temperature are plastically bonded to form a heating plate 36 to form the ceramic heating element 30 in which the ceramic heater 35 and the heating plate 36 are integrated. Make.

In another method of making the ceramic heating element 30, the lower plate 32 and the upper plate 33 having a predetermined thickness on the lower side and the upper side of the ceramic heater 35 made by printing a resistance on the thin ceramic sintered substrate 31 are formed. ) May be brought into close contact with each other, and then fired at a high temperature to be integrated.

As another method of making the ceramic heating element 30, a heating plate 36 made of a ceramic sintered substrate 31 having a considerable thickness (the same thickness as the entire heating plate), or a plurality of sintered substrates having a thin thickness ( 31 is laminated to form a heater hole 41 in the heating plate 36 made to have a constant thickness, and the configuration is proposed to be formed by inserting the ceramic heater 35 in the heater hole 41. .

The above configuration is a method of manufacturing the glass sintered alumina substrate by heat cutting with a glass adhesive to melt the glass by cutting the laser sintered alumina substrate. ) A large amount is formed, and due to the material property of glass, it is installed in ancient times due to the difference in density and thermal expansion coefficient between alumina material and glass adhesive layer. A burn accident is expected.

In addition, the high purity alumina composition has excellent thermal conductivity (Thermal Conductivity: 96% Al ₂ O ₃ 26W / mk), but glass frit has Thermal Conductivity (Glass Ceramic: MgO, Al ₂ 0 ₃ , SiO ₂ 3W) / mk) is so low that three glass adhesive layers are formed on the alumina substrate ceramic heating pattern layer, which has a very slow heat transfer rate. That is, since four layers of insulating glass adhesive layers are present on the ceramic heating plate, the heating rate is very slow when installed in ancient times.

The problem of the prior art presented above is that the aluminum heat sink has low thermal efficiency because the heat transfer principle uses conductivity, and an electric shock accident due to leakage current is caused by an insulation breakdown caused by the original matrix bonding the ceramic substrate to glass frit. Due to the large number of municipal processes, there are problems of cost increase and low service life.

In addition, in the previously-patent patent application No. 10-2004-20497, a resist pattern layer is formed on an alumina sintered substrate, and then bonding of each layer uses a glass frit adhesive. The integrated heat sink and ceramic heater have the advantage of having the thermal functionality of ceramic in one body, but due to thermal stress difference between the dissimilar materials (alumina sintered substrate and glass frit bonding layer), heat sink peeling phenomenon due to thermal stress As a result, it has a big problem in electrical safety, and thermal characteristics have a disadvantage in that thermal efficiency is lowered due to thermal barriers caused by dissimilar materials.

[Related Technical Literature]

1. Ceramic heater (Patent Application No. 10-2007-0047060)

2. CERAMIC HEATER AND PRODUCTION METHOD THEREFOR AND HEATING DEVICE AND HAIR IRON (Patent Application No. 10-2006-7027130)

3. ROUND-TYPE CERAMIC HEATER AND MANUFACTURE METHODTHEREOF (Patent Application No. 10-2005-0052150)

The present invention has been made to solve the above and the conventional problems, the object is to simultaneously fire the ceramic heater and the heat sink in a wet reducing atmosphere to integrate or to heat the heat dissipation plate by inserting a general ceramic heater into the oxidation atmosphere. The ceramic green sheet is manufactured by tape casting method and printed resistance pattern with the same alumina composition and heated and compressed by pressing press. To provide a ceramic heater insert type heat dissipation plate manufacturing method that can reduce power consumption when using the ceramic heater by expressing various colors by integrating the ceramic heater to maximize the heat storage function and heat recovery ability of the ceramic to the maximum.

The present invention also provides a method for manufacturing a ceramic heater insert type heat dissipation plate using a press molding method, an extrusion molding method, an injection molding method by forming a hole to insert a general ceramic heater for an ancient period under the heat sink to embed a ceramic heater.

Ceramic heater heat dissipation plate according to the present invention for achieving the above object in the manufacture of a ceramic heater insert type heat dissipation plate, alumina 70 ~ 99% composition of the ball milling and dry powder in an organic binder or an aqueous solvent or organic solvent system in a press molding method, It is manufactured by extrusion molding or injection molding, and is characterized in that the ceramic heating element is inserted into the heat dissipation plate hole and integrated.

In addition, another embodiment of the ceramic heater insert type heat dissipation plate according to the present invention is a variety of color chromophores are TiO ₂ , (Co, Ni) O (Cr, Fe) spinel structure, SnO ₂ (CSb ₂ O ₅ , V ₂ O ₅ ), ZrSio ₄ (CoO, NiO), (Sn, Ti) O ₂ (V ₂ O ₅ ), (Zr, Ti) O ₂ (V, In), ZrSiO ₄ (cds), TiO ₂ (Cr ₂ O ₃ , Sb ₂ O ₅ ), Zr SiO ₄ [Cd (SSe)], α-Al ₂ O ₃ (Mn, P), ZnO (Al, Cr) ₂ O ₃ spinel structure, CaOSnO ₂ SiO ₂ [Cr, Co] , SnO ₂ (Cr), ZrSiO ₄ (Fe), (Co, ZnOnAl ₂ O ₃ , 2 (Co, Zn) OSiO ₂ , ZrSiO ₄ (V ₂ O ₅ ), (Co, Zn) O (Al, Cr) ₂ O ₃ Spinel structure, 3CaO, Cr ₂ O ₃ , 3Si0 ₂ , (Al, Cr) ₂ O ₃ is added and calcined to 1700 ℃ or less in an oxidizing atmosphere, white black gray yellow red pink blue or green It is characterized by.

In addition, another embodiment of the ceramic heater insertion type heat dissipation plate according to the present invention is a surface of Al ₂ O ₃ 96wt% white heat dissipation plate by adjusting the surface roughness by the Sand Blast method by adding an inorganic pigment to the nano coating liquid made of silica It is characterized by the color development.

The present invention relates to a ceramic insert type heat sink for the ancient times used to straighten and shape the human hair, by expressing various colors by integrating the ceramic heat sink and the ceramic heater to maximize the heat storage function and heat recovery ability of the ceramic while high efficiency heat radiation It has characteristics and can reduce power consumption. It is manufactured by integrating ceramic heater and heat sink in wet reducing atmosphere at the same time, or by heating high temperature firing structure designed to insert heat-dissipating plate into oxidizing atmosphere. It is characterized by.

Ceramic heater insert type heat dissipation plate is first composed of ceramic powder (aluminum ~ 99.9wt%) ZrO ₂ , FeO, Fe ₂ O ₃ , Fe ₃ O ₄ , MnO, Mn, Cr ₂ O ₃ , Ni, NiO, NiO ₂ , CoO, V ₂ O ₅ , Heat dissipation produced by adding 0.5 ~ 30 wt% of Cds, Se, Ta, In, etc. to develop white, black, gray, orange, red, blue, pink, yellow, pink, amber color to have texture like natural gemstone Plate.

By integrating a heat sink with a ceramic heater integrated therein, the heat transfer rate, heat uniformity, and speed and ease of hair forming are greatly improved, and safety accidents can be prevented in advance.

1 to 3 is a view showing the structure of a conventional common ancient ceramic heating element.
4 to 5 is a view prepared by inserting a ceramic heater in a conventional ceramic coated aluminum heat sink.
6 to 8 is a view in which the ceramic heating element and the heating plate are integrally configured to compensate for the disadvantages of the conventional aluminum heat sink.
9 is a view showing a ceramic heater embedded heat dissipation plate manufacturing process according to the present invention.
10 is a flowchart illustrating a process of adding alumina to a ceramic composition as one embodiment according to the manufacture of a ceramic heater-embedded heating plate according to the present invention.
11 is a cross-sectional view of the ceramic heater built-in heat dissipation plate produced by the present invention
12 is a cross-sectional view according to the pattern resistance to be implemented in the ceramic heater embedded heat dissipation plate according to the present invention.
13 to 14 is a cross-sectional view of the ceramic heater embedded heat dissipation plate according to the present invention and an embodiment of the product
15 is a cross-sectional view of the ceramic heater insertion type heat dissipation plate according to another embodiment of the present invention.
16 is a graph showing the temperature rise characteristics of the ceramic heater embedded heat dissipation plate and the ceramic heater insertion heat dissipation plate manufactured according to the present invention
17 is a graph showing the relationship between the heater temperature characteristics and the current consumption of the ceramic heater embedded heat dissipation plate and ceramic heater insertion heat dissipation plate manufactured according to the present invention.
18 to 19 are graphs showing temperature characteristics of heater positions as shown in FIGS.
20 is a graph showing the relationship between the temperature and current consumption of the ceramic heater according to the applied time of the ceramic heater heat radiation plate according to the present invention according to the present invention

Hereinafter, a detailed description of a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

The ceramic heater heat dissipation plate of the present invention can manufacture a ceramic heater embedded heat dissipation plate or a ceramic heater insertion heat dissipation plate, which will be described in detail for each manufacturing process and features.

1) Manufacture of Heat Dissipation Plate with Ceramic Heater

The present invention is to manufacture a heat dissipation plate of a variety of colors with a ceramic heater built-in, as shown in Figure 9 attached to the ceramic heater embedded heat dissipation plate according to the present invention is a ceramic green sheet 600 ~ 900mm thickness tape casting method After manufacturing and cutting to a certain size, and pattern-printing the high-melting-point resistance paste (Mo-Mn, W, W-Mo, W-Mo-Mn), the pattern printed green sheet as the lower plate 100, do not print Uncut ceramic green sheet is set to the upper plate (120). The upper and lower ceramic green sheets 100 and 120 are pressed (laminated) by a pressing press, and then a heat dissipation plate is pressed by six sheets by the pressing press to form one compressed plate.

The green sheet (thickness 600 ~ 900㎛) of the crimped top portion using the sheet produced the green sheet with the color ceramic composition to allow the top of the heat dissipation plate to develop a variety of colors.

The ceramic heater built-in heat-dissipating plate is characterized in that it is manufactured by high temperature co-firing (Co-Firing) at a maximum of 1,700 ℃ in a wet reducing atmosphere.

In addition, the heat dissipation plate embedded in the ceramic heater of the present invention can be used for the general-purpose ceramic heaters of the conventional ancient times, it is a heat sink manufacturing method designed to exhibit the same effect as the co-fired ceramic embedded heat dissipation plate.

That is, as shown in Figure 10 attached to the alumina 0 ~ 99.9wt% in the ceramic composition by adding the coloring composition, uniformly mixed and pulverized in a slurry state with an aqueous solvent in a ball mill, the slurry having a particle size of 1㎛ or less To a granulated powder of 50 ~ 300㎛ granule powder through a drying process using a spray dryer to prepare by the press molding method, or to prepare the ceramic composition in the cake (Cake) state by extrusion molding by extrusion molding, or the ceramic The composition is prepared by mixing a mixture of organic binders (polypropene, acrylic, polyethylene, cellulose, etc.) with an extruder by heating and mixing ceramic powder with a binder, followed by injection molding with an injection molding machine, followed by degreasing and baking. can do.

Hereinafter, a detailed manufacturing method of the ceramic heater embedded heat dissipation plate will be described with reference to the accompanying drawings.

11 is a cross-sectional view of the ceramic heater-embedded heat dissipation plate manufactured by the present invention.

TiO ₂ , in alumina (~ 99wt%) composition FeO, Fe ₂ O ₃ , Fe ₃ O ₄ , Mn, MnO, Cr ₂ 0 ₃ , Ni, NiO, NiO ₂ is added Simultaneous firing of the wet reducing atmosphere expresses white, black, gray, purple, and pink as shown in the following [Table 1] and [Table 2].

TiO ₂ FeO Fe ₂ O ₃ Fe ₃ O ₄ Mn Al ₂ O ₃ 96wt% One% grey One% grey One% grey One% grey One% Mauve 3% black 3% black 3% black 3% black 3% Progressive White black black black black purple

MnO Cr ₂ 0 ₃ Ni NiO NiO ₂ Al ₂ O ₃ 96% One% Mauve One% Light pink One% grey One% grey One% yellow 3% Progressive 3% Pink 3% black 3% black 3% Red White purple pink black black Red

When the wet reducing atmosphere 1500 ~ 1700 ℃ firing versatility of color due to the variety of ceramic embedded heat dissipation plate of various colors when the ceramic surface roughness Ra = 1 ~ 3㎛ roughly by adding an inorganic pigment to the nano coating liquid made of silica in various colors Coating.

During ceramic coating, the ceramic heater built-in heat sink is formed with irregularities on the surface by the sand blast method, and the ceramic coating liquid is coated with a spray sprayer to form a coating film having a thickness of 5 to 30 μm and thermally cured at about 150 ° C. for 20 to 120 minutes.

The ceramic heater built-in heat dissipation plate is manufactured by a tape casting method with a ceramic green sheet thickness of 600 to 1000 μm, and a high melting point powder such as tungsten and molybdenum is prepared as a resistance paste on the ceramic green sheet to adjust the paste viscosity to about 6000 to 100,000 cps. The pattern was printed.

The pattern resistance was implemented to 0.5 ~ 1kΩ and as a result a pattern as shown in Figure 12 is formed.

The high temperature wet reducing atmosphere is prepared by cofiring at max.

After the sintered ceramic heater embedded heat dissipation plate is R-processed on the top and side grooved, the Ni-wire is brazed with Ag and Ag-Cu alloys at about 1000 ° C or less in a brazing furnace (under hydrogen + nitrogen mixed gas). Join the terminals.

An embodiment of the cross-sectional view and the product of the ceramic heater-embedded heat dissipation plate according to the present invention manufactured by the above method is shown as shown in FIGS. 13 to 14.

The process of manufacturing the ceramic heater-embedded heat dissipation plate formed according to the present invention by color is presented in the following examples in terms of configuration and test results.

Example 1. (white)

Alumina (Sumitomosa: ALM41: 1.3 mm average particle diameter) 96wt% composition (Al ₂ O ₃ 96 wt%, MgO 0.8 wt%, CaO 0.2 wt%, SiO ₂ 3.0 wt%) were ground and mixed in a ball mill for 48 hours.

At this time, the solvent was in a slurry state using an organic solvent (IPA + n-Buthanol + Methanol) and PVB-Binder, wherein the particle size was 0.3 ㎛ in the particle size. After the slurry was deaerated using an air defoaming machine, the tape was cast to prepare a green sheet thickness of 600-1000 μm.

In addition, a green sheet of 96 wt% alumina was also prepared in the same manner as described above, cut into a certain size, and printed with a high melting point (W-paste) paste having a resistance pattern of 0.5 kV to 1.0 kK to form a resistance. Resistance patterning green sheet and green sheet (96wt% Al ₂ O ₃ ) by crimp press 80 ~ 100 ℃ 50㎏ / ㎡ Compressed by pressure. The total laminated number was 6-8 sheets. At this time, the thickness of 5 ~ 10mm laminated product was produced by heating at 1700 ℃ high temperature in a wet reducing atmosphere electric furnace.

The fired product was R-processed on the top and grooved on the side to produce a ceramic heater-integrated heat dissipation plate.

At this time, the characteristics of the ceramic heating element are as follows.

Sintered Density: 3.83g / cm3

Color: White

MOR Strength (3-point): 249Mpa

Thermal Conductivity (Laser Measurement): 25.7w / mk

Surface Roughness: Ra = 0.684㎛ Rmax = 9.740㎛

Exothermic Temperature Characteristics (See Figures 16-20)

Set temperature: 213 ℃

Reach time: Within 20 seconds

Power Consumption: Initial) 440W (4.0A)

Ballast) 110W (1.0A)

Example 2 (grey)

Alumina (Sumitomos ALM41: Average particle size 1.3㎛)

TiO _{2 at} 96wt% After adding 3%, the mixture was ground and mixed for 48 hours in a ball mill.

At this time, the solvent was in a slurry state using an organic solvent (IPA + n-Buthanol + Methanol) and PVB-Binder. At this time, the particle size was 0.3㎛.

The slurry was degassed in a deaerator to remove air, and then, the tape was cast to prepare a green sheet thickness of 600-1000 μm. In addition, the green sheet of 96 wt% alumina was prepared in the same manner as above, and cut to a certain size to form a resistance by printing with a high melting point (W-paste) paste with a resistance pattern of 0.5 kPa to 1 kPa. The resist patterning green sheet and the green sheet (96 wt% Al ₂ O ₃₎ were pressed at a pressure of 80-100 ° C. and 50 kg / cm 2 by a pressing press. The total number of laminated sheets was 6 to 8 sheets, and the top green sheet was laminated by pressing the TiO ₂ -added green sheet and pressed. At this time, the thickness of 5 ~ 10mm laminated product was produced by co-firing 1,700 ℃ high temperature in a wet reduction atmosphere electric furnace. The fired product was R-processed on the top and grooved on the side to manufacture a ceramic heater-integrated heat dissipation plate.

The characteristics of the ceramic heating element at this time is as follows.

Sintered Density: 3.83 g / cm 3

Color: gray

MOR Strength (3-point) 250 Mpa

Thermal Conductivity (Laser Measurement) 26.0 W / mk

Surface Roughness: Ra = 0.788㎛ Rmax = 10.976㎛

* Exothermic temperature characteristics were implemented the same characteristics as in Example 1.

Example 3 (pink)

After adding 3% Cr ₂ O _{3 to the} composition of 96 wt% alumina, the mixture was ground and mixed for 48 hours in a ball mill.

Same as full length (the same division as in Example 2 below)

Sintered Density: 3.83 g / cm 3

Color: pink

MoR Strength (3-point): 247Mpa

Thermal conductivity (laser measurement): 26.2 W / mk

Surface Roughness: Ra = 0.730㎛ Rmax = 10.240㎛

* The exothermic temperature characteristic shows the same characteristics as in Example 1.

Example 4 (black)

-FeO, Fe ₂ O ₃ , Fe ₃ O _{4 in} alumina 96wt% composition 1 to 3 wt% of one component, 1 to 3 wt% of one of Ni and NiO, or 50:50 each of the Fe and Ni components, or 0.5 wt of TiO ₂ to the composition. % The added composition also develops in the same black color.

The composition was ground and mixed for 48 hours in a Ball Mill.

Same full length (the same division as in Example 2 below)

Sintered Density: 3.84 g / cm3

Color: Black

MOR Strength: 25.9 w / mk

Surface Roughness: Ra = 0.720㎛ Rmax = 9.757㎛

* The exothermic temperature characteristic shows the same characteristics as in Example 1.

Example 5 (red)

-Alumina 96wt% composition of Ta ₂ O ₅ , TaCl ₅ weighted 1 ~ 3wt% was added and pulverized and mixed in a ball mill for 48 hours. The solvent used was an organic solvent and a PVB binder, and the particle size was 0.3 μm in a slurry state.

The slurry was degassed with an air defoaming machine to remove air, and then, the tape was cast to prepare a green sheet thickness of 100-600 μm, laminated on the surface layer of the ceramic heater-embedded heat dissipation plate, and then fired at a temperature of 1,700 ° C. in a wet reduction atmosphere electric furnace.

At this time, the color of the upper surface of the heat sink was red, and XRD mineral phase analysis showed that the Ta ₃ N ₅ tetragonal perovskite structure was present.

Example 6 (coating color development)

In Example 1, a ceramic coating solution was used to express a color by adding an inorganic pigment to the nano-silica coating solution.

The unevenness is formed on the upper surface (R processing surface) of the completed heat sink embedded ceramic heater by sand blast method using molten alumina abrasives # 50 to # 400, and a small amount of inorganic pigment is added to the SiO ₂ coating liquid to coat the coating film at about 150 ° C. It is manufactured by forming a coating layer by thermal curing for 30 to 60 minutes.

At this time, the characteristics of the ceramic heating element is the same as in Example 1, and exhibits the same characteristics as the product before and after coating.

The ceramic heater-integrated heat dissipation plate manufactured for each color has the characteristics as shown in Table 3 below.

Heat Dissipation Plate with Ceramic Heater L a b Remarks White 60.96 -0.83 0.96 black 26.16 0.40 -0.42 Red 40.69 14.53 7.42 green 44.30 -14.74 9.98 blue 37.35 -11.40 -17.01

2) Ceramic Heater Insert Type Heat Dissipation Plate

As another embodiment of the present invention can be manufactured in the heating element (heater) insertion type of the heat dissipation plate, that is, the process of manufacturing a ceramic heater insertion type heat dissipation plate by color in the following examples, the configuration and test results were presented.

A cross-sectional view of the ceramic heater insert type heat dissipation plate is shown as shown in FIG. 15.

First, the following metal chromophores are added to alumina ˜99 wt% to express various colors. The minor component atmosphere is characterized by color development by high temperature firing at 1,000 ° C. to 1,700 ° C. as an oxidizing atmosphere.

In the manufacturing method, a leach composition containing a metal coloring ion is added to alumina base composition in a ball mill, and a batch composition is added to the water-based binder for 48 hours.

At this time, the central particle size is x = 0.3 탆, and the powder dried in the slurry state is molded by press molding, extrusion molding, or injection molding. At this time, Binder uses PVA, acrylic, EVA, PVB, PE, PP, MC, Epoxy Resin, Polymeta Acrylacid Compound, Polystylene, Celurose, Celurose Nitrate, Celurose Diacetate, Ethyle Celurose, Bengyl Celurose.

Ceramic coloring composition Al ₂ O ₃ Metal chromophores Remarks White 85 to 99% TiO ₂ Black (Co, Ni) O (Cr, Fe) ₂ O ₃ Spinel structure Gray SnO ₂ (CSb ₂ O ₅ , V ₂ O ₅ ) structure
Zr SiO ₄ (CoO, NiO) Yellow (Sn, Ti) O ₂ (V ₂ O ₅ )
(Zr, Ti) O ₂ (V, In)
Zr SiO ₄ (cds)
TiO ₂ (Cr ₂ O ₃ , Sb ₂ O ₅ ) Red Zr SiO ₄ [Cd (sse)] ZrO _{2 ,} SiO _{2 ,} CdCO ₃
S, Se Pink α-Al ₂ O ₃ (Mn, P)
ZnO (Al, Cr) ₂ O ₃ Spinel Structure
CaO SnO ₂ SiO ₂ [Cr, Co]
SnO ₂ (Cr)
ZrSiO ₄ (Fe) Cobalt Carbonate,
K ₂ Cr ₂ O _{2 ,} FeSO ₄ ,
7H ₂ O, FeCl ₃ Blue (Co, Zn) O nAl ₂ O ₃
2 (co, Zn) O SiO ₂
Zr SiO ₄ (V ₂ O ₅ ), CoO, ZnO, Al (OH) 3, ZnO, SiO ₂ , ZrO ₂ , V ₂ O ₅ , NH ₄ VO ₃ Green (Co, Zn) O (Al, Cr) ₂ o ₃ spinel structure, 3CaO Cr ₂ O ₃ 3SiO ₂ ,
(Al, Cr) ₂ O ₃ CoO, ZnO, Cr ₂ O ₃ , Al (OH) 3,
CaO: Cr ₂ O ₃ : SiO ₂ = 3: 1: 3
Al ₂ O ₃ : Cr ₂ O ₃ = 1: 1 ~ 1: 5

The composition is manufactured by heating the molded product in an oxidizing atmosphere electric furnace at ~ 1,700 ° C. to produce a ceramic heater-insertable heat dissipation plate.

The ceramic heater insert type heat dissipation plate is manufactured in various colors by inserting a heater of 0.5 ~ 1 kΩ of the general ceramic heater into the heat dissipation plate hole manufactured by the above method.

Example 7 (press molding)

Al ₂ O ₃ 96wt% SiO ₂ 3.0wt% MgO 0.8wt% CaO 0.2 wt% Batch added 3 wt% of TiO ₂ to the basic composition was ground and mixed in an aqueous ball mill for 48 hours. At this time, the central particle diameter of slurry is 0.3㎛. Spray dried granule powder is prepared in a granule particle size of 80 ~ 300㎛ with a spray dryer. At this time, Binder was powder press-molded powder using PVA and calcined at 1,650 ℃ for 2 hours to prepare a sintered product.

In the manufacturing process conditions, the water recirculation rate was adjusted to 1.1wt% by adjusting the moisture of the granular powder, and the manufacturing process conditions are as follows.

Molding pressure: 2,000kg / ㎠

Al ₂ O ₃ (particle diameter): 2.5 μm 96 wt%

Flux: SiO ₂ 3.0wt%, MgO 0.8wt%, CaO 0.2 wt%

Poly Vinyl Alchcol (PVA): 3.0wt%

Di-Bbuthyl Phthalate (DBP): 0.4wt%

Parapin Wax: 1.5 wt%

Solvent (water): appropriate amount

The firing conditions were degreased at 5 ° C./h up to 400 ° C., and then heated to 100 ° C./h and held at 1,650 ° C. for 30 minutes to be fired.

At this time, the heat dissipation plate color is white.

The characteristics of the ceramic heater insert type heat dissipation plate manufactured by the press molding method are as follows.

Sintered Density: 3.84g / cm3

Color: white

MOR Strength (3-point): 250Mpa

Thermal conductivity (laser measurement): 26.0 w / mk

Surface Roughness: Ra = 0.694㎛ Rmax = 9.840㎛

Exothermic temperature characteristics are the same as in Example 7 of the electric ceramic heater insertion type heat dissipation plate.

Example 8 (Extrusion Molding)

96 wt% alumina, 2.0 wt% kaolin 1.3 wt%, 0.7 wt% limestone were dried in a ball mill for 24 hours after wet grinding. Binder methylcellulose (MC) 6wt%, mold release agent 3.5wt%, glycerin 3wt%, distilled water 13.5wt% was kneaded for 1 hour in the kneading machine and the bait cake read in a vacuum state in the reading machine is aged for at least 4 days. A molded article in which the aged clay is set as an extruder is prepared and naturally dried.

The natural drying time is 48 hours or more, and the characteristics of the ceramic heater insert type heat-dissipating plate manufactured by firing at 400 ° C. 5 ° C./h in a oxidizing atmosphere and then heating at 100 ° C./h for 30 minutes are maintained at 1650 ° C. for 30 minutes. same.

Example 9 (Injection Molding)

After preparing a master batch with a binder mixture resin as in Example 1, the ceramic heater-inserted heat-dissipating plate according to another embodiment of the present invention was molded by an injection molding machine. The molded product was burned out at 500 ° C. for 5 hours in a degreasing furnace and calcined at 1,650 ° C. for 1 hour in an oxidizing atmosphere electric furnace. The color at this time was white. Manufacturing process conditions are as follows.

1) The mixture was ground and mixed for 20 hours in a ball mill, and distilled water was used as a solvent.

2) The derived raw materials were dried at 120 ° C. for 24 hours in a drying furnace.

3) Binder was mixed at 150 ~ 180 ℃ for 1 hour in dispersion mixer.

4) The mixed raw material was pulverized and dried in a dispersion mixer for 30 minutes in order to make it easy to feed into the injection machine.

5) The ceramic injection machine was injection-fired as a 25ton injection molding machine.

Composition: Alumina 90wt% + Flux (SiO ₂ 3.0wt%, MgO 0.8wt%, CaO 0.2wt%) 4wt%

Poly Stylene (PS) 0.10wt%

Poly Prophylence (PP) 0.4wt%

Di-Octhyl Phthalate (DOP) 0.5wt%

Steariz Acid 0.5wt%

Mineral Oil 5wt%

The composition was de-bittered at 400 ° C. 50 ° C./h, and then heated to 100 ° C. and maintained at 1,650 ° C. for 1 hour.

Example 10 (black)

Al ₂ O ₃ 96wt% Flux (SiO ₂ 3.0wt%, Mgo 0.8wt%, Cao 0.2wt%) 4wt% composition by the manufacturing process shown in Example 3 as the chromophore composition as CoO 1mol% NiO 1mol% Cr ₂ O ₃ 1mol% Fe ₂ O ₃ Α-Al ₂ O ₃ solid solution was prepared using (Co, Ni) (Cr, Fe) ₂ O ₃ -based spinel structure by mixing 1 mol% of oxide to form Al ₂ O ₃ 96wt% + Fluxwt4% (total solid 100%) is added to 1.0wt% composition.

In the manufacturing process, a ceramic heater insert type heat-dissipating plate was manufactured in the same manner as in Example 9 by injection molding. The color of the heat dissipation plate sintered body at this time is expressed in black color and the results and characteristic values measured by the colorimeter (CM-3500D) are as follows.

Sintered Density: 3.83g / cm3

Color: Black L: 20.16 a: 0.4 b: -0.41

MOR strength: 247Mpa

Thermal Conductivity (Laser Measurement): 25.4 w / mk

Surface Roughness: Ra = 0.734㎛ Rmax = 10.042㎛

Heat dissipation characteristics are the same as in Example 1.

Example 11 (grey)

Prepared by the same method as in Example 10, the composition is Al ₂ O ₃ 96wt% Flux 4wt% composition of the metal chromophore SnO ₂ 1mol%, Sb ₂ O ₅ 0.5mol%, V ₂ O ₅ 1mol% 1 wt% was added to the total solid (Al ₂ O ₃ 96+ Flux 4wt%).

In the manufacturing process, a ceramic heater insert type heat-dissipating plate was manufactured in the same manner as in Example 9 by injection molding. At this time, the heat dissipation plate color is expressed in grey, and the result and characteristic values measured with the colorimeter (Minola M-3500D) are as follows.

Sintered Density: 3.84g / cm3

Color: gray L: 40.0 a: -0.41 b: 1.43

MOR Strength: 250Mpa

Thermal Conductivity (Laser Measurement): 25.7 w / mk

Surface Roughness: Ra = 0.780㎛ Rmax = 10.172㎛

Exothermic characteristics are the same as in Example 1.

Example 12 (yellow)

Prepared by the same method as in Example 10, the composition is Al ₂ O ₃ 96wt% Flux 4wt% composition to the metal chromophore SnO ₂ 1 mol% V ₂ O ₅ , TiO ₂ 0.5mol% of the total solid (Al ₂ O ₃ 96wt% + Flux4wt%) was added to 1wt%.

In the manufacturing process, a ceramic heater insert type heat-dissipating plate was manufactured in the same manner as in Example 9 by injection molding. At this time, the color of the heat dissipation plate is expressed in yellow, and the result or characteristic value measured by the colorimeter (Minola M-3500D) is as follows.

Sintered Density: 3.80 g / cm3

Color: yellow L: 33.0 a: -4.10 b: 16.70

MOR Stregth: 250Mpa

Thermal conductivity (laser measurement method): 25.3 w / mk

Surface Roughness: Ra = 0.740㎛ Rmax = 10.104㎛

Exothermic characteristics are the same as in Example 7.

Example 13 (red)

Basic composition as in Example 10 (Al ₂ O ₃ 96 wt% + Flux 4wt%) added 1 mol% of metal chromophores ZrO _3, 1 mol% of SiO _2, 1 mol5 of CdCO ₃ , 0.5 mol% of S, and 0.5 mol% of Se to the total Solid (Al ₂ O ₃ 96wt% + Flux 4%) It was carried out with the composition added 1 wt%.

Manufacturing fixation was the same as that of Example 9 by injection molding, and a sintered ceramic heater-inserted heat dissipation plate was prepared.

The characteristic values and colors are as follows.

Sintered Density: 3.83g / cm3

Color: red L: 40.74 a: 14.58 b: 7.49

MOR Strength: 252Mpa

Thermal Conductivity (Laser Measurement Method): 25.4w / mk

Surface Roughness: Ra = 0.774㎛, Rmax = 10.200㎛

Exothermic characteristics are the same as in Example 7.

Example 14 (pink)

Example 10 with a basic composition _{(Al 2 O 3 96wt% +} flux 4wt%) metal chromophore _{Zn0 1mol% Cr 2 O 3 1mol} %, Al 2 o 3 1mol% the composition total solid (Al ₂ O ₃ was added in the same 96wt% + flux 4wt%) was carried out with the composition added 1wt%.

The manufacturing process is the same as that of Example 9 by injection molding, and at this time, a sintered ceramic heater insert type heat dissipation plate was prepared.

The characteristic values and colors are as follows.

Sintered Density: 3.83g / cm3

Color: pink L: 60.96 a: -0.83 b: 0.96

MOR Strength: 257Mpa

Thermal conductivity (laser measurement): 25.7w / mk

Surface Roughness: Ra = 0.734µm Rmax = 10.124µm

Exothermic characteristics are the same as in Example 7.

Example 15 (Blue)

Example 10 and the same base composition _{(Al 2 O 3 96wt% +} flux 4wt%) metal chromophore _{Co0 1mol% Zn0 1mol% Al 2} o 3 1mol% blending the composition total _{solid (Al 2 O 3 96wt%} + flux 4wt% to ) To 1wt%.

The manufacturing process is the same as that of Example 9 by injection molding, and at this time, a sintered ceramic heater insert type heat dissipation plate was prepared.

The characteristic values and colors are as follows.

Sintered Density: 3.83g / cm3

Color: blue L: 37.35 a: -11.39 b: -17.01

MOR Strength: 254Mpa

Thermal Conductivity (Laser Measurement Method): 25.4w / mk

Surface Roughness: Ra = 0.734mm Rmax = 10.124mm

Exothermic characteristics are the same as in Example 7.

Example 16 (green)

Example 10 a basic composition, such as _{(Al 2 O 3 96wt% +} flux 4wt%) in metal chromophore Co0 1mol% Zn0 1mol%, Cr 2 O 3 1mol% Al 2 o 3 1mol% blended composition total solid (Al ₂ O ₃ 96wt% + flux 4wt%) to 1wt% added composition.

The manufacturing process is the same as that of Example 9 by injection molding, and at this time, a sintered ceramic heater insert type heat dissipation plate was prepared.

The characteristic values and colors are as follows.

Sintered Density: 3.83g / cm3

Color: green L: 26.48 a: -4.32 b: 3.18

MOR Strength: 256Mpa

Thermal Conductivity (Laser Measurement Method): 25.9w / mk

Surface Roughness: Ra = 0.697㎛ Rmax = 9.274㎛

Exothermic characteristics are the same as in Example 7.

Example 17 (Coating Development)

The ceramic coating solution is used to express the color by adding an inorganic pigment to the nano-silica coating solution of the ceramic heater insert type heat-dissipating plate prepared in Example 7.

The unevenness was formed on the upper surface (R processing surface) of the heat sink completed in Example 7 by using the molten alumina abrasive # 50-400 by Sand Blast method, and a small amount of inorganic pigment was added to the SiO ₂ coating solution to coat the coating film thickness by spray coating. The coating is developed at -30 mu m.

The coating film is prepared by thermal curing at 150 ° C. for about 30-60 minutes to form a coating layer.

Chromatograph (Minolta M-3500D) chromaticity measurement results of the ceramic heat sinks of various colors are as follows.

The ceramic heater insert type heat dissipation plate manufactured for each of the colors has characteristics as shown in Table 5 below.

Ceramic Heater Insert Type Heat Dissipation Plate by Color L a b Remarks White 60.96 -0.83 0.96 black 26.16 0.40 -0.42 Red 40.69 14.53 7.42 green 44.30 -14.74 9.98 blue 37.35 -11.40 -17.01

16 to 20 attached to the characteristics of the temperature and the current consumption of the ceramic heater built-in heat dissipation plate and the ceramic heater insertion type heat dissipation plate manufactured according to the present invention according to the current, the current consumption and the applied time Referring to the characteristics of the present invention, FIG. 16 is a graph illustrating a temperature rising rate of a temperature rising characteristic when voltage is applied, and a graph measuring temperature characteristics and current consumption of a ceramic heater heat dissipation plate according to FIG. Indicates.

FIG. 18 is a photograph of a product measuring temperature characteristics of a ceramic embedded heat dissipation plate product, and FIG. 19 is a graph illustrating temperature characteristics and current consumption of a ceramic embedded heat dissipation plate product, which are shown in FIGS. 18 to 19. As you look at the temperature characteristics of the heater location,

The maximum temperature is 230 ℃ at the center of the plate and the temperature at the back of the plate, that is, the sensor is located at 210 ℃, and the temperature continues to rise in the power-off section, and the power-off section or over heating section occurs for about 15 seconds. It can be seen.

At this time, the temperature deviation is about 20 ℃ difference at the highest temperature in the part where the sensor in the center of the plate and the plate behind the plate is located (temperature fuse position), but the temperature does not affect the temperature fuse. In addition, the heater heat characteristic is because the heater itself has a large amount of heat, and even if the power is cut off, it can be seen that the additional rise occurs by about 20 ° C., because the temperature on the sensor side is lower than the center and the temperature control is delayed.

The relationship between the temperature of the ceramic heater and the current consumption according to the time applied according to the present invention, as shown in Table 6 below and attached 20, the temperature rises for a predetermined time and is kept constant. A) was shown to remain constant while the temperature was rising and then gradually decreased as time passed, so that the current consumption gradually decreased and remained constant.

Relationship of Temperature and Current Consumption of Ceramic Heater with Time Authorization time (sec) 12 23 34 45 56 67 78 89 100 111 122 133 144 155 166 177 Temperature (℃) 100 175 230 220 213 213 213 213 213 213 213 213 213 213 213 213 Current consumption (A) 4.2 4.1 4.1 3.7 2.2 1.5 1.4 1.3 1.2 1.1 1.1 1.1 1.1 1.1 1.1 1.1

As described above, the specification and the drawings have been described with respect to the preferred embodiments of the present invention, although specific terms are used, it is only used in a general sense to easily explain the technical contents of the present invention and to help the understanding of the invention. It is not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention can be carried out in addition to the embodiments disclosed herein.

Claims (3)

In manufacturing ceramic heating element insert type heat dissipation plate, alumina 70 ~ 99% composition is used for ball milling and dry powder of organic binder in water system or organic solvent system by press molding method, extrusion molding method, injection molding method and insert ceramic heating element into heat dissipation plate hole. Ceramic heater insertion type heat dissipation plate manufacturing method characterized in that the integrated.
The various chromophores in claim ₁ are TiO ₂ , (Co, Ni) O (Cr, Fe) spinel structure, SnO ₂ (CSb ₂ O ₅ , V ₂ O ₅ ), ZrSio ₄ (CoO, NiO), (Sn , Ti) O ₂ (V ₂ O ₅ ), (Zr, Ti) O ₂ (V, In), ZrSiO ₄ (cds), TiO ₂ (Cr ₂ O ₃ , Sb ₂ O ₅ ), Zr SiO ₄ [Cd (SSe)], α-Al ₂ O ₃ (Mn, P), ZnO (Al, Cr) ₂ O ₃ spinel structure, CaOSnO ₂ SiO ₂ [Cr, Co], SnO ₂ (Cr), ZrSiO ₄ (Fe) , (Co, ZnOnAl ₂ O ₃ , 2 (Co, Zn) OSiO ₂ , ZrSiO ₄ (V ₂ O ₅ ), (Co, Zn) O (Al, Cr) ₂ O ₃ Spinel structure, 3CaO, Cr ₂ O ₃ Method for producing a ceramic heater insert type heat dissipation plate, characterized in that the addition of ~ 10wt% of, 3Si0 ₂ , (Al, Cr) ₂ O ₃ and sintered below 1700 ℃ in an oxidizing atmosphere to color white black gray yellow red pink blue or green .
The heat dissipation type ceramic heater of claim 1, wherein the surface of the white heat dissipation plate of Al ₂ O ₃ 96wt% by adjusting the surface roughness by adding the inorganic pigment to the nano-coating solution made of silica to develop a variety of colors Plate manufacturing method.

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