KR101113713B1 - Manufacturing method for a mini type ceramic heater with a built in sensor - Google Patents

Abstract

The present invention relates to the manufacture of a sensor-embedded ceramic substrate heater, and more particularly, a small sensor that can be applied to various small electronic devices by reducing the thickness of the substrate by printing both a heating circuit and a sensor circuit on a single substrate. A method for producing a built-in ceramic substrate heater. In addition, the present invention is to maintain a proper distance between the terminal and the terminal even if the heating circuit and the sensor circuit is printed on one substrate to solve the problem of energization between the adjacent terminals generated in the small ceramic substrate heater small sensor-type ceramic substrate heater It is a manufacturing method.

Description

MANUFACTURING METHOD FOR A MINI TYPE CERAMIC HEATER WITH A BUILT IN SENSOR}

The present invention relates to the manufacture of a small-type ceramic substrate heater, and more particularly, a small sensor that can be applied to various small electronic devices by reducing the thickness of the substrate by printing both a heating circuit and a sensor circuit on a single substrate. A method for producing a built-in ceramic substrate heater.

In general, a ceramic heater is a heating element made by printing a heating wire (heating circuit) on a ceramic substrate and sintering at a high temperature of about 1600 ° C., and rapidly heating it when electricity is supplied, and raising the temperature to 800 ° C. or more within 30 seconds. Excellent insulation resistance, no noise when energized. In addition, it is possible to apply various types of applications as the characteristics of ceramic materials appear when electricity is applied, and it can be used for perm beauty instruments, soldering irons, hot air fans, dryers, electric boilers and oil stoves, various mold thermostats, hot water heaters, and deniers. It can be variously applied to medical devices such as therapists and massagers.

Hereinafter, a conventional ceramic heater will be described with reference to the drawings.

1 is a view showing a conventional ceramic heater described in the prior patent application No. 10-2005-0083532 ceramic heater.

A first substrate 10, a heating circuit 14 provided in a predetermined pattern on the first substrate 10, a temperature sensor circuit 12 positioned between the pattern and the pattern of the heating circuit 14, and It consists of a second substrate 16 laminated on one substrate 10.

The temperature sensor circuit 12 and the heating circuit 14 have a pattern formed on the first substrate 10. In this case, the temperature sensor circuit 12 and the heat generating circuit 14 may be directly formed on the upper portion of the first substrate 10 through a screen printing technique, or first using a semiconductor process such as a photolithography technique. One of the patterns of the temperature sensor circuit 12 or the heating circuit 14 is formed on the first substrate 10, and then a material constituting the heating circuit or the temperature sensor circuit is formed by a process such as deposition. Then, the pattern of the remaining temperature sensor circuit or the heating circuit is formed on top of the second substrate 10 using a photolithography technique in a similar manner and then formed by vapor deposition.

In addition, the first substrate 10 and the second substrate 16 has a rectangular plate shape as shown in the figure, but it can be changed to a three-dimensional structure, such as a plate or circular column of various shapes, Applicable to ceramic heaters.

In the case of the conventional ceramic heater, the temperature sensor circuit 12 is positioned between the heating circuit 14 patterns so that the temperature sensor circuit 12 can accurately sense the heating temperature so that the user can precisely measure the heating temperature of the ceramic heater. Take control.

In addition, the heating circuit 14 and the temperature sensor circuit 12 is supplied with power through a wire 20 that is separately connected to generate heat, and outputs the detected heating temperature to the controller.

The heating circuit 12 is made of Pt, W, Mo, Ni, Ta, SiC, MoSi2 Ni-Cr alloy, Fe-Cr alloy or a combination thereof, and the temperature sensor circuit is Pt, W, Mo, Ni, Ta, Exothermic materials comprising SiC, MoSi2 Ni-Cr alloys or Fe-Cr alloys or composites thereof, or NTC thermistor materials containing Mn, CO, Ni, Fe, etc., or BaTiO3, Y, Ce, La, Sn, etc. It consists of a composite material which consists of any one or combination of PTC containing the PTC material which is contained, or platinum (Pt). NTC thermistor materials are Mn, CO, Ni, Fe and the like, and the PTC thermistor material is BaTiO3, Y, Ce, La, Sn and the like.

In the case of FIG. 1, the size of the product should be 60 × 15 mm or more, so that the heating circuit and the sensor circuit can be simultaneously implemented on the lower layer. In this case, the energization of the heating circuit and the sensor circuit causes a serious problem in product reliability.

2 is a view showing another example of a conventional ceramic heater described in the prior patent application No. 10-2005-0083532.

As shown in FIG. 2, the first substrate 10, the heating circuit 14 provided in a predetermined pattern on the first substrate 10, the intermediate substrate 18 stacked on the first substrate 10, and The temperature sensor circuit 12 is provided on the intermediate substrate 18 in a predetermined pattern, and the second substrate 16 is stacked on the intermediate substrate 18. The heat generating circuit 14 and the temperature sensor circuit 12 have patterns formed on the first substrate 10 and the intermediate substrate 18, respectively.

At this time, as shown in Figure 1, the temperature sensor circuit 12 and the heat generating circuit 14 is formed through a screen printing technique or a photo etching technique and deposition.

1, the first substrate 10, the intermediate substrate 18, and the second substrate 16 have a rectangular plate shape as shown in the drawing, but this is like a plate or a circular column of various shapes. It can be changed to three-dimensional structure, so it can be applied to all types of ceramic heaters.

In the above-described conventional technology, the heating circuit and the sensor circuit are printed on the first substrate of the first heating element, and the second substrate is formed. The heating circuit is printed on the second first substrate, and the sensor circuit is printed on the second substrate. It consists of more than a board.

However, the conventional ceramic heater with a sensor as shown in FIGS. 1 and 2 is a substrate for a sensor-embedded ceramic heater having an insulating layer as a substrate, and has a size of about 60 * 15 mm. There is a difficult problem.

Also, when the heating circuit and the sensor circuit are simultaneously printed on the same substrate as shown in FIGS. 1 and 2, mutual interference between the sensor circuit and the heating circuit may occur at a rated voltage, thereby generating noise in the sensor circuit. Therefore, there are design drawbacks that must be avoided design to avoid mutual interference, and these design drawbacks are a major cause of difficulty in implementing products of various resistances and sizes.

In addition, if the substrate structure is formed of three or more layers, such as a ceramic heater with a built-in sensor, there is a problem in that the response speed to the temperature sensing is lowered. This will cause problems, so countermeasures need to be taken.

In addition, the conventional technology is a substrate for a sensor-built ceramic heater made by forming an insulating layer as a substrate, there is a problem that it is difficult to implement a heating circuit and wiring in a small sensor-type ceramic board heater.

The present invention solves the above problems, the present invention is a compact sensor-embedded ceramic substrate heater to print a heating circuit on one substrate by a precision printing technique and to insulate by printing an insulating thin film thereon and again to the sensor circuit on the insulating thin film An object of the present invention is to provide a method for manufacturing a small sensor-embedded ceramic substrate heater in which the thickness of the substrate is first printed and the cover substrate is bonded thereto.

In addition, the present invention is to provide a small-sensor-type ceramic substrate heater to solve the problem of the current between the other terminals generated in the small ceramic substrate heater by maintaining the proper spacing of the terminal even if the heating circuit and the sensor circuit is printed on one substrate It is an object to provide a manufacturing method.

The present invention for achieving the above object is a step of printing the heating circuit and the terminal portion of the heating circuit by a precision printing technique on the substrate, and printing and insulating the insulating thin film layer of 20 ~ 30㎛ thickness on the heating circuit, and insulation And printing the sensor circuit and the terminal of the sensor circuit on the thin film layer and coupling the cover substrate onto the sensor circuit.

In addition, the heating circuit of the present invention has a composition ratio of W 30%, Mo 70%, and the insulating thin film layer is Al ₂ O ₃ 93%, CaCO ₃ 0.90%, Talc 3.40%, SiO ₂ 1.85%, Y ₂ O ₃ 0.85 It has a composition ratio of%, the sensor circuit is characterized by having a composition ratio of W 21%, Mo 49%, Al ₂ O ₃ 30%.

In addition, the heat generating circuit terminal unit of the present invention maintains a distance between the sensor circuit terminal unit and at least 2mm ~ 2.50mm, and the small sensor-embedded ceramic substrate heater is characterized in that the size of 60 * 7mm or 50 * 7mm. .

The present invention is implemented by applying an insulating thin film between the heating circuit and the sensor circuit on a single substrate to increase the insulation between the two circuits, the thin film is very excellent in response to the temperature detection of the heating circuit.

In addition, since it is a small (MINI TYPE) sensor built-in ceramic heater that is difficult to implement in the prior art, the product utilizing this can realize a smaller size than the conventional product.

In addition, the sensor is a ceramic heater with a sensor (MINI TYPE) of the conventional product has the effect of improving the reliability of the ceramic heater with a sensor.

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

It should be noted that in the following description, only parts necessary for understanding the operation according to the present invention will be described, and descriptions of other parts will be omitted.

The present invention is a method of manufacturing a ceramic substrate heater for initializing the thickness of the ceramic substrate heater by implementing a heating circuit and a sensor circuit in a single substrate using an insulating thin film technology when manufacturing a mini-type ceramic substrate heater.

The main process of the present invention is similar to the manufacturing process of a conventional ceramic heater. However, in the case of the conventional ceramic heater is manufactured by bonding the heating layer to the upper layer after printing the heating circuit on the green sheet (Green Sheet) of the bottom, the present invention prints the insulating thin film after printing the heating circuit on the lower substrate, and the sensor circuit again Print and bond with the upper substrate.

3 is a side view of a ceramic substrate heater according to an embodiment of the present invention.

The ceramic substrate heater of the present invention includes a substrate 200, a heating circuit 220, an insulating thin film 240, a sensor circuit 260, and a terminal unit (not shown).

The ceramic substrate heater of the present invention is a mini type having a small size of about 50 * 7mm, and the heating circuit 220 is printed on the substrate 200 by using a precision printing technique, and the insulating thin film method is formed on the heating circuit 220. After printing the insulating thin film 240 having a thickness of 20㎛ ~ 30㎛ by using the method to be manufactured by printing the sensor circuit 260 and covers the cover of the substrate 200 on the sensor circuit 260.

The present invention improves the insulation between the heating circuit 220 and the sensor circuit 260 by using an insulating thin film method, and since the insulating thin film, the response speed of the temperature sensing of the heating circuit 220 is very excellent.

In addition, since the present invention implements a compact ceramic substrate heater using an insulated thin film method, the product size can also be implemented in a compact size that meets the current trend.

In the prior art, it could not be applied to the first substrate heater.

In addition, when the conventional technology is applied to a small ceramic substrate heater such as the present invention, a problem of energization between adjacent terminals occurs, thereby causing a serious problem of product defects.

The composition of the heating circuit 220 constituting the ceramic substrate heater of the present invention will be described. A heating circuit electrode paste is prepared by combining W and Mo powders at an appropriate ratio, thereby producing a line of the heating circuit 220. The resistance of the circuit is designed by length, width, thickness, etc. to form a heat resistance of about 70 Ω.

Electrode paste is manufactured by mixing conductive metal W and Mo in a certain ratio for the electrical resistance required for the circuit pattern of ceramic heater products, and is in a fluid state by mixing the conductive metal, organic solvent and binder (similar to ink) ) Is called a paste.

division W Mo CaCO ₃ Talc SiO2 system Combination Ratio (%) 30 70 100

Table 1 shows the composition ratio of the heating circuit 220 is made up of W 30%, Mo 70% to form a total of 100%.

Next, the composition of the insulating thin film 240 having a thickness of 20 μm to 30 μm, which is overlaid on the heating circuit 220 constituting the ceramic substrate heater of the present invention, will be described.

The composition of the insulating thin film 240 is a mixture of Al ₂ O ₃ , CaCO ₃ , Talc, SiO ₂ , Y ₂ O ₃ oxide powder (powder) in an appropriate ratio to prepare a paste of the insulating layer, heating circuit An insulating layer is printed on the 220 to a thickness of 20 to 30 μm to form an insulating layer of the heating circuit 220 and the sensor circuit 260.

division Al ₂ O ₃ CaCO ₃ Talc SiO ₂ Y ₂ O ₃ system Combination Ratio (%) 93 0.90 3.40 1.85 0.85 100

Table 2 shows the composition ratio of the insulating thin film 240, 93% of Al ₂ O ₃ , 0.90% of CaCO ₃ , 3.40% of Talc, 1.85% of SiO ₂ , and 0.85% of Y ₂ O ₃ .

Next, the composition of the sensor circuit 260 covered on the heat generating thin film 240 constituting the ceramic substrate heater of the present invention will be described.

The composition of the sensor circuit 260 according to the present invention is to prepare a sensor circuit electrode paste by combining a powder mixed with W, Mo, Al ₂ O ₃ in an appropriate ratio as shown in Table 3 below, The resistance of the circuit is designed by the line length, width, thickness, etc. of the sensor circuit 260 to form a high resistance of about 2 kW. The reason for constructing the high resistance is to improve the resistance variation with respect to the temperature of the sensor circuit.

division W Mo Al ₂ O ₃ system Combination Ratio (%) 21 49 30 100

Table 3 shows the composition ratio of the sensor circuit 260, consisting of W 21%, Mo 49%, Al ₂ O ₃ 30% to form a total of 100%.

As described above, the main process of the present invention is similar to the manufacturing process of the conventional ceramic heater, but the present invention prints the insulating thin film after printing the heating circuit on the lower layer, and then prints the sensor circuit on the lower layer to bond the upper layer.

HTCC (High Temperature Co-firing Ceramic) ceramic substrate heater manufacturing process according to the present invention will be briefly described, it consists of a molding process (Casting Process), processing process (Green Process) and the end process (End Process).

The casting process consists of powder mixing, ball milling, de-air, aging, thick-film forming and thickening to control and control the viscosity of the slurry. Sheet rolling or the like.

The following green process consists of wafer punch, pattern print, lamination, slitting, and cutting.

The final process is sintering, cell break, nickel plating, lead brazing, appearance inspection, electrical inspection, etc. It is composed.

4 is a diagram illustrating an example of a terminal unit installed in a ceramic substrate heater according to an embodiment of the present invention.

The present invention prints the heating circuit 220 and the sensor circuit 260 on a single substrate and insulates between the heating circuit 220 and the sensor circuit 260 by applying an insulating thin film method and also the heating circuit terminal 225 and The distance between the sensor circuit terminals 265 is maintained at least 2 mm to solve the problem of energization between terminals conventionally generated.

A 220 V voltage is applied to the terminal portion of the heating circuit 220 to the ceramic substrate heater, and a maximum voltage of 5 V is applied to the terminal portion of the sensor circuit 260. In this case, when the spacing between the two terminal portions is not proper, the reliability problem of the product is caused by the conduction problem between the above-described heating circuit and the sensor circuit terminals. In the present invention, the heating circuit terminal 225 and the sensor circuit terminal have an optimal structure. The problem was solved by keeping the interval of (265) at least 2 mm.

Referring to FIG. 4, the terminal structure of the ceramic heater with a mini-type sensor having three examples shows a distance between a terminal 225 of the heating circuit 220 and a terminal 265 of the sensor circuit 260 at least 2 mm to 2.50 mm. You can see the gap between them.

The present invention is a mini-type sensor-embedded ceramic substrate heater to firstly print the heating circuit on the first substrate by using a precision printing technique, and to form an insulating thin film layer by printing the insulating thin film to a thickness of 20㎛ ~ 30㎛, It is manufactured by second printing the sensor circuit thereon.

In this way, if the insulating thin film layer is formed between the heating circuit and the sensor circuit, the insulation between both circuits is increased, and since the thin film is a thin film, the sensor circuit quickly senses the temperature of the heating circuit, and shows an excellent response speed. Is possible.

So far, the configuration and operation of the embodiment of the present invention have been described. The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the claims but also by the equivalents of the claims.

1 is a view showing a conventional ceramic heater.

2 is a view showing another example of a conventional ceramic heater.

3 is a side view of a ceramic substrate heater according to an embodiment of the present invention;

4 is a view showing an example of a terminal unit installed in a ceramic substrate heater according to an embodiment of the present invention;

<Description of Major Symbols in Drawing>

10: first substrate 12: temperature sensor circuit

14 heating circuit 16 second substrate

18: intermediate substrate 200: substrate

220: heating circuit 240: insulating thin film

260 sensor circuit 225 heating circuit terminal

265: sensor circuit terminal

Claims (6)

delete Printing a heating circuit having a composition ratio of W 30% and Mo 70% on a substrate and a terminal portion of the heating circuit by a precision printing technique; Printing and insulating an insulating thin film layer having a composition ratio of Al ₂ O ₃ 93%, CaCO ₃ 0.90%, Talc 3.40%, SiO ₂ 1.85%, and Y ₂ O ₃ 0.85% with a thickness of 20 to 30 μm. Wow; Printing a sensor circuit having a composition ratio of W 21%, Mo 49%, and Al ₂ O ₃ on the insulating thin film layer and a terminal portion of the sensor circuit, and bonding a cover substrate on the sensor circuit. A method of manufacturing a small sensor-embedded ceramic substrate heater. delete delete 3. The method of claim 2, The heating circuit terminal unit is a method of manufacturing a small-sensor-type ceramic substrate heater, characterized in that for maintaining the interval between the sensor circuit terminal portion and at least 2mm ~ 2.50mm. 3. The method of claim 2, The small sensor embedded ceramic substrate heater has a size of about 60 * 7mm or 50 * 7mm.

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