KR20070119259A - Electric range - Google Patents

Abstract

A portable electric range is provided to incorporate a heating plate into a flat plate, and use a plurality of slim heating plates hinged to each other. A portable electric range includes a burner unit(110), a heating unit, and a power supply unit(130). The burner unit includes a frame(111) formed into the shape of a container, and a heating plate(113) mounted on the frame such that cooking is carried out through a thermal conduction. The heating unit applies power to a thin film heater arranged on a rear surface of the heating plate of the burner unit. The power supply unit supplies power to the heating unit. The burner unit and the power supply unit are mechanically and electrically separated from each other, and the power supply unit is equipped with a battery(139).

Description

Portable electric range

1 is a perspective view showing a portable gas range according to the prior art.

Figure 2 is a perspective view showing the structure of a portable electric range according to an embodiment of the present invention.

Figure 3 is a partial cutaway view of the front state of a portable electric range according to an embodiment of the present invention.

4 is an exploded perspective view illustrating a separated state of a charging part of a portable electric range according to an embodiment of the present invention.

5 is a perspective view of a state in which the burner unit of the portable electric range according to another embodiment of the present invention is deployed;

6 is a partial cutaway view from the front showing a state in which the burner part of the portable electric range of FIG. 5 is folded;

Figure 7 is an enlarged cross-sectional view showing a cross-sectional structure for explaining an embodiment of the heat generating means according to the present invention.

Figure 8 is an enlarged cross-sectional view showing a cross-sectional structure for explaining another embodiment of the heat generating means according to the present invention.

9 to 11 are exemplary views showing various embodiments of a conductor pattern formed on a thin film heater according to the present invention.

12 to 13 are exemplary views showing embodiments of various arrangement patterns of the metal pad and the thin film heater according to the present invention.

14 is a schematic view showing the specifications of the specimen for experimenting the heating characteristics of the heating means according to the present invention.

15 is a graph measuring a temperature change value according to time displacement in a state in which a constant current (50 W) is applied to the specimen of FIG. 14.

FIG. 16 is a graph measuring a temperature change value according to a displacement of an amount of current applied for a time (10 seconds) specified in the specimen of FIG. 14.

<Description of the symbols for the main parts of the drawings>

110,110 ': burner section 111: frame

113: heating plate 117: cover

117a: fixed wing 120: heating means

122: insulating film 123: thin film heater

124: conductor pattern 125: metal pad

127: protective layer 130: power supply

131: input terminal portion 132: docking portion

133: control unit 134: power switch

135: power gauge 136: temperature gauge

137: output terminal 139: rechargeable battery

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a portable electric range, and more particularly, to a portable electric range capable of being portable and mobile, and at the same time slimming by providing a heating means capable of low power driving using a thin film heater.

In general, the portable burner is a heating device that can be easily cooked food at home or outdoors using butane gas. The portable burner is configured to form a burner part for cooking by placing a copel or a fire plate on the top of a rectangular body, and to form a fuel supply part for attaching butane gas to one side of the burner part to supply fuel. Is done.

However, such a rectangular box-type portable gas range has a problem that the flame is exposed to the outside as the top surface of the burner is installed on the body to form almost the same surface, so that the flame is easily turned off when the wind blows. As a method to compensate for this, a method of blocking winds around the gas range was used by providing a separate windshield, but it was cumbersome to carry the windshield.

In order to solve such a problem, as shown in FIG. 1, a portable gas range has been provided to improve usability by preventing the burner from being affected by wind and preventing oil from being sprayed into the body.

1 is a perspective view showing a portable gas range according to the prior art, the gas range of the prior art as shown in the figure is a body 10, the burner unit built in the center of the body 10 to ignite a flame 20 and the governor 30 which supplies gas to the burner unit 20 and regulates the amount of gas through the control lever 32, and is inserted into the upper portion of the body 10 and penetrated through the center thereof. A concave circular support plate 40 in which discharge holes 42 and 44 through which you 30 are inserted and oil is discharged on the surface thereof, and slides to an integral part of the body 10 and discharges of the circular support plate 40. It consists of a sump 50 for storing the oil coming out through the holes (42) (44).

However, in the gas stove according to the related art as described above, a structure such as the head 22 and the support leg piece 46, which is a structure for supporting a cope or the like, is troublesome because it protrudes to the outside, and in particular, the gas stove body ( 10) As the top of the opening is open, when cooking foods such as stew or yakiniku, there is a problem that it becomes difficult to clean and manage due to the flow of soup or oil, and the burner may become dirty due to the penetration of every corner. In addition, there were problems that were not hygienic.

Above all, the gas stoves of the prior art as described above all use the spark ignition method, and there is a danger of fire when used in outdoor activities (especially in the acid of the dryer), and there is an inconvenience that the carry-in is prohibited, and oxygen There is a problem that is difficult to use in the high altitude.

In addition, this type of gas range has a problem that the explosion occurs due to the gas cylinder heating as the flame is flowed back to the lower side as the top of the range is blocked in the cooking vessel during cooking.

In addition, the prior art is that when the ambient temperature is too low in the open air, the heat is taken away to the surroundings, the thermal efficiency is lowered, and when the rain is rainy, there is a problem that it is difficult to use.

An object of the present invention for solving the above problems is to provide a portable electric range having a heating means capable of low power drive using a thin film heater.

Another object of the present invention is to provide a portable electric range that allows a large area of the cooking area, such as designing a heating plate of the burner unit in a flat plate shape, hinge-bonding a plurality of slimming heating plates, and folding or storing them at the same time. have.

In addition, another object of the present invention is to provide a portable electric range that is easy to configure and manufacture the heat generating means, free design and design of the whole product, and the user's operation is convenient.

In addition, another object of the present invention is to form a power supply unit to receive a variety of forms of power, including a vehicle power source and a household power supply, and to drive a variety of electrical products through a variety of output terminals, multi-purpose in outdoor activities The present invention provides a portable electric range that can be used as a charger.

Portable electric range according to the present invention for achieving the object as described above is a frame manufactured in the shape of a housing to provide mechanical strength, the heating plate is installed in a flat plate shape on the upper surface of the frame to be cooked by heat conduction Burner unit consisting of; Heating means for applying electric power to the thin film heater formed on the rear surface of the heating plate of the burner to generate electric heat; Characterized in that it comprises a power supply for supplying power to the heat generating means.

Here, the burner part and the power supply unit are mechanically and electrically separated and coupled, and the power supply unit is characterized in that the removable battery is built-in.

In addition, the burner unit may be hinged or coupled to at least one or more of the plurality, or may be folded and used.

The power supply unit may include a control unit configured to form a plurality of input terminal units for receiving at least one or more powers, and to output and control power charged through the input terminal unit.

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

Figure 2 is a perspective view showing the structure of a portable electric range according to an embodiment of the present invention, Figure 3 is a partial cutaway view of the front state of the portable electric range according to an embodiment of the present invention.

Portable electric range according to the present invention as shown in the drawing is a frame 111 is produced in the shape of a housing to provide mechanical strength, the plate 111 is installed on the upper surface of the frame 111 is cooked by heat conduction Heat generation to apply electric power to the burner unit 110 formed of the heating plate 113 and the thin film heater 123 formed on the rear surface of the heating plate 113 of the burner unit 110 to be electrically heated. The means 120 and the power supply unit 130 for supplying power to the heat generating means 120.

First, the burner part 110 is composed of a frame 111 and a heating plate 113. The frame 111 may be manufactured in various shapes such as a square or a circle, and a hollow space part therein. By maintaining the structural strength, the insulating layer made of the air layer is formed.

The heating plate 113 is manufactured using a material having excellent thermal conductivity, and a conductive material or a non-conductive material may be used.

The heating plate 113 may be placed on the upper surface of the cooking container so that indirect heating through heat conduction may be performed, or a food (meat) serving as a direct cooking object may be directly heated and cooked. To this end, the heating plate 113 is manufactured in a tray shape in which the center is recessed and the rim is raised, thereby preventing food or water from flowing down during cooking.

In addition, the heating plate 113 as described above preferably has a structure that is thermally separated from the frame 111 in order to minimize the heat conduction loss. For this purpose, a heat shielding packing may be installed between the coupling portion of the heating plate 113 and the frame 111.

In addition, the cover 117 may be coupled in a detachable state from the upper side in which the burner unit 110 and the power supply unit 130 are coupled, and the cover 117 serves as a protective cover to enable cooking even in rainy weather. As to perform, a predetermined number of fixed blades 117a around the bottom is coupled to be folded or unfolded.

The fixed blade 117a is coupled around the frame 111 of the electric range in an unfolded state when cooking, which serves to fix the cover 117 by maintaining a predetermined height on the upper surface of the heating plate 113. do.

After cooking, the fixing blade 117a is folded and coupled to the electric range. In this case, the upper surface of the cover 117 and the upper portion of the burner part 113 are coupled to each other.

The cover 117 as described above is preferably made of a transparent material (synthetic resin, glass, etc.) in order to be able to visually check the state in which the food is cooked inside.

Next, the heat generating means 120 includes a thin film heater 123 capable of driving low power (eg, 100 W). The thin film heater 123 generates heat at a very high speed when external power is supplied. At this time, the heat is conducted to the heating plate 113 so that cooking can be performed.

In addition, the heat generating means 120, when the external power supply is cut off, since the thin film heater 123 is cooled at a very high speed, the surface temperature of the heating plate 113 is lowered together, and thus does not leave a separate cooling time after use. Since it is not necessary, secure management can be achieved.

The thickness of the heating plate 113 is preferably processed to 0.3 mm ~ 2mm, a metal such as aluminum or stainless steel may be used as the material.

Next, the power supply unit 130 is configured to receive an external power source to charge it or to charge and mount the rechargeable battery 139 from the outside.

The power supply unit 130 forms a plurality of input terminal units 131 for receiving at least one or more powers, and controls the control unit 133 to output and control the power charged through the input terminal unit 131. And a plurality of output terminal units 132 for supplying the charged power to various electrical products.

In this case, the input terminal unit 131 includes a vehicle power input terminal and a home power input terminal.

In addition, the control unit 133 is a power switch 134 to turn on / off the power of the electric range, a power gauge 135 for displaying the remaining power of the rechargeable battery, a temperature gauge 136 for displaying the heating temperature, and the like. It will include.

The power supplied through the output terminal unit 137 may be used as a power source for driving a portable radio, a TV, a lamp, or the like.

Figure 4 is an exploded perspective view showing a state of separation of the charging portion of the portable electric range according to an embodiment of the present invention, the present invention as shown in the drawing is burner unit 110 and the power supply unit 130 mechanically separated It can be manufactured in a removable structure to be combined.

Such the present invention separates and manages only the power supply unit 130 separately, which is convenient to carry and move, as well as the convenience of charging operation using a vehicle power source.

The burner unit 110 and the power supply unit 130 form a separate docking unit 132 to allow mechanical and electrical coupling to each other.

5 is a perspective view of the burner unit of the portable electric range open state according to another embodiment of the present invention, Figure 6 is a partial cutaway view from the front showing a state in which the burner portion of the portable electric range of Figure 5 folded.

The present invention as shown in the figure is a structure that can be slimmed burner unit 110, can be folded or stored by folding at least one burner unit 110 (110 ') or folded to use.

At this time, each of the burner parts 110 and 110 ′ is composed of a frame 111 and a heating plate 113 having a hollow part, and each of the burner parts 110 and 110 ′ is a heating plate 113. Should be folded and stored facing each other.

5 to 6 illustrate a state in which two burner parts 110 and 110 ′ are hinged, but two or more burners may be hinged as necessary.

The present invention having the above configuration has the advantage of being able to use it on a table by simply charging at a branch such as a restaurant as well as using it outdoors.

Figure 7 is an enlarged cross-sectional view showing a cross-sectional structure for explaining an embodiment of the heating means according to the present invention, the heating means 120 of the present invention is installed on the back of the heating plate 113 made of a non-conductive material An example is explained.

Heat generating means 120 of the present invention as shown in the drawing is a heating plate 113 made of a non-conductive material, and is mounted in the form of a thin film on the outer surface of the heating plate 113 is supplied with power from the outside to itself electric Electrical bonding is made to the thin film heater 123 which is instantaneously heated at high temperature by instantaneous heating according to a resistance, and the power supplied from the outside may be uniformly applied to the entire surface of the thin film heater 123. The metal pad 125 and the metal pad 125 and the thin film heater 123 are formed of a protective layer 127 coated to a predetermined thickness so as to be protected from an external environment.

In this case, as a material of the heating plate 113 of the non-conductive material, a heat-reinforced plastic, a heat resistant resin, a ceramic, glass, ceramics, and the like that can withstand at least 250 ° C. or more may be used.

8 is an enlarged cross-sectional view showing a cross-sectional structure for explaining another embodiment of the heat generating means according to the present invention, an example in which the heat generating means 120 of the present invention is installed on the back of the heating plate 113 made of a conductive material It explains.

The heat generating means 120 of the present invention as shown in the drawing is coated with a predetermined thickness on the heating plate 113 made of a conductive material, the inner surface of the heating plate 113 is provided with electrical insulation properties and at the same time excellent thermal conductivity The insulating film 122 and the thin film heater 123 mounted in the form of a thin film in the lower portion of the insulating film 122 is supplied with power from the outside and instantaneously generates high temperature by instantaneous heating according to its own electrical resistance. The metal pad 125 may be electrically bonded to the thin film heater 123, and may have a specific pattern such that power supplied from the outside may be uniformly applied to the entire surface of the thin film heater 123 and the metal pad 125. ) And the thin film heater 123 is composed of a protective layer 127 coated to a predetermined thickness so as to be protected from the external environment.

Here, the thickness of the heating plate 113 made of the conductive material is preferably made of 0.3 mm ~ 2mm, the material may be a metal such as aluminum or stainless steel.

In this case, as shown in FIGS. 7 and 8, a separate conductor pattern 124 is formed on the thin film heater 123 so that the current is evenly distributed and supplied to the entire surface of the thin film heater 123. Excessive heat generation may be prevented from concentrating on a specific portion of the 123 so that the heat generation property may be stabilized.

Hereinafter, required for each component such as the insulating film 122, the thin film heater 123, the conductor pattern 124, the metal pad 125 and the protective layer 127 constituting the heat generating means 120 of the present invention The physical properties and structural conditions will be described in more detail as follows.

First, the insulating film 122 is thinned as much as possible so that the heat generated from the thin film heater 123 can be conducted to the heating plate 113 at a high speed, and the insulating plate 122 is formed between the heating plate 113 and the thin film heater 123. An insulating film using a ceramic material or a polymer material such as alumina (aluminum oxide, Al 2 O 3) or magnesia (magnesium oxide, MgO) or the like, or a mixed material of the two insulating films may be used for electrical insulation.

In addition, the insulating layer 122 may have a thin thickness such that heat generated from the thin film heater 123 may be conducted to the heating plate 113 at a high speed, and the heating plate 113 and the thin film heater 123 may be used. ) 0.5 μm to 500 μm, in particular 0.5 μm to 200 μm, is sufficient to electrically insulate the liver, and thickness may vary depending on the material.

The conditions of the insulating film 122 is as follows.

First, the insulating film 122 must electrically insulate the heating plate 113 from the thin film heater 123, and the thin film heater 123 to electrically isolate the thin film heater 123 supplied with external power. When the voltage of about 100V is applied, the breakdown of the insulating film 122 should not occur and the electrical leakage current of the insulating film 122 should be 20 μA or less.

In addition, when the high temperature heat is generated in the thin film heater 123, the insulating film 122 contacts the heating plate 113 and the heating plate 113 so that physical desorption does not occur from the heating plate 113 and the thin film heater 123, respectively. The contact between the insulating film 122 and the thin film heater 123 should be excellent.

In addition, when high temperature heat is generated in the thin film heater 123, the insulating film 122 does not chemically react with the heating plate 113 and the thin film heater 123, and the surface roughness of the insulating film 122 should be excellent.

That is, when the surface roughness of the insulating film 122 is not excellent, since the insulating film 122 affects the electrical resistivity of the thin film heater 123, the insulating film 122 affects the electrical resistivity of the thin film heater 123. It is desirable to have a surface roughness of a degree that does not affect.

In order to satisfy the conditions as described above, the insulating film 122 is an oxide insulating film obtained by oxidizing the surface of the heating plate 113 of a metal material such as aluminum or stainless steel with an arc, or a ceramic, One or two of an insulating film coated with glass, porcelain, or the like, or a polymer insulating film coated with a polymer-based material (Polyimide, Polyamide, Teflon, PET, etc.) on the surface of a metal heating plate 113 such as aluminum or stainless steel. An insulating film or the like having at least two branches formed on the surface of the heating plate 113 is used.

An embodiment of a method of forming an oxide insulating film is as follows.

First, electric energy such as an arc is applied from the outside to the surface of the heating plate 113 made of a metal material such as aluminum (Al) or beryllium (Be) or titanium (Ti) or stainless steel (immersed in an alkaline electrolyte solution). In this case, the metal atoms on the surface of the heating plate 113 and the external oxygen cause an electrochemical reaction to be formed by converting the characteristics of the surface of the heating plate 113 into an oxide film.

As the oxide insulating layer, Al 2 O 3, ZrO 3, Y 2 O 3, or the like may be used, and the oxide insulating layer may be formed on the heating plate 113 by plasma spray coating.

Hereinafter, an embodiment of a process of forming an oxide insulating film on a heating plate will be described.

First, the concentration of the alkaline electrolyte solution filled in the bath is evaluated, and the aluminum is connected to the heating plate 113 made of aluminum so that external power can be supplied to the heating plate 113 made of aluminum. The heating plate 113 of the material is immersed in the alkali electrolyte in the container, and then external power is supplied to the heating plate 113 of the aluminum material to oxidize the surface of the heating plate 113 of the aluminum material.

Next, an arc is generated on the heating plate 113 surface of the aluminum material as a strong power source having a high frequency alternating current (AC) shape is applied to the heating plate 113 of aluminum material by the oxide insulating film forming process. Therefore, an oxide insulating film is formed on the surface of the heating plate 113 made of aluminum, which is dense in oxidation and has a very small concentration of pinholes.

Aluminum oxide may be formed on the surface of the heating plate 113 made of aluminum or titanium oxide may be formed on the surface of the heating plate 113 made of titanium, or the heating plate 113 made of beryllium may be formed using the oxide oxide insulating layer forming process. Beryllium oxide can be formed on the surface.

On the other hand, the polymer insulating film is formed by coating a polymer-based material having a uniform thickness on the surface of the heating plate 113 of the metal material to ensure electrical insulation.

In particular, the polymer insulating film should be less thermally deformed when heat is generated in the thin film heater 123. In addition, the polymer insulating film should be excellent in contactability so that physical desorption does not occur from the heating plate 113 and the thin film heater 123 when the high temperature heat is generated in the thin film heater 123, and the heating plate 113 And do not cause a chemical reaction with the thin film heater 123, respectively, and the surface roughness should be excellent.

An embodiment of the process of forming the polymer insulating film will be described below.

First, the polymer insulating film is formed using a liquid organic polymer material, and is coated with a uniform thickness on the surface of the heating plate 113 made of a metal material.

Here, as the coating method, a spin coating method, a spray coating method, a dipping coating method, a screen printing method, or the like is used.

In addition, the polymer material may be a polyimide-based material, a polyamide-based material, a teflon-based material, a paint-based material, silver-ston, Tefgel-S ( tefzel-s), epoxy, rubber, or the like, or a material that is sensitive to ultraviolet light (UV) may be used.

For example, one embodiment of a process of forming a polyimide-based material on the heating plate 113 by spray coating is as follows.

First, the heating plate 113 is organically washed with acetone, isopropyl alcohol (IPA), or the like, and then the heating plate 113 is rotated at a high speed (for example, 2,000 rpm or more) while being polyimide-based. After spraying the material on the heating plate 113, the polyimide-based material coated on the surface of the heating plate 113 is heat-treated.

The polymer insulating film having a high thermal stability and a glassy temperature (GT) of 300 ° C. or more is formed on the surface of the heating plate 113 by the spray coating method of forming a polymer insulating film.

In addition, by slowly cooling the polyimide-based material during the heat treatment of the polyimide-based material, the adhesion between the polymer insulating film and the heating plate 113 is excellent, and by coating the surface of the polymer-based material on the heating plate 113 during the spray coating process. The thickness uniformity is excellent, and the pinhole concentration of the polymer insulating film is very small, so that no electric leakage current is generated.

On the other hand, the double insulating film of the oxide insulating film and the polymer insulating film forms an oxide insulating film on the surface of the heating plate 113 of the metal material and then coats the polymer-based material with a uniform thickness on the oxide insulating film or, conversely, the surface of the heating plate of the metal material. The polymer-based material may be coated on and an oxide insulating film is formed thereon.

The total thickness of the double insulating film of the oxide insulating film and the polymer insulating film is the thickness of the result of forming the oxide insulating film on the surface of the heating plate 113 alone and the thickness of the result of forming the polymer insulating film on the surface of the heating plate 113 alone. It can be small compared to the sum, and can minimize the breakdown of the insulation compared to each single insulating film.

Here, the main reason for the oxide insulating film insulation breakdown may be caused by the external power supplied to the thin film heater 123 being transferred into the pinhole due to the pinhole formed in the oxide insulating film.

The main reason for the breakdown of the polymer insulating film may be due to bubble generation due to the application of liquid Pr at the time of forming the polymer insulating film, and then the dielectric breakdown may occur at the portion where the bubble was present after the polymer insulating film was solidified.

Therefore, it is preferable to compensate for the occurrence of dielectric breakdown inherent in each of the oxide insulating film or the polymer insulating film with a double insulating film of the oxide insulating film and the polymer insulating film.

The thickness of the insulating film 122 is preferably in the range of 0.5 μm to 500 μm, especially 0.5 μm to 100 μm, for thermal efficiency (the thickness varies depending on the material), and the dielectric breakdown voltage of the insulating film 122 ( The breakdown voltage is 1,000 V or more, the leakage current of the insulating film 122 is 20 μA or less when the voltage reaches 100 V, and when the heat is generated in the thin film heater 123 (thermal cycle) 122 prevents detachment (peeling) from each of the heating plate 113 and the thin film heater 123.

Next, the thin film heater 123 will be described. The thin film heater 123 is mounted on the insulating film 122 in the form of a thin film having a thickness of 0.05 μm to several μm (eg, 0.05 μm to 2 μm), and the metal When external power (DC power or AC power) is supplied through the pad 125, joule heating is generated by its own electrical resistance.

Here, due to the thin film characteristics of the thin film heater 123, that is, the small volume, the heat generation rate and the cooling rate may be made very fast, and the temperature generated by the self electrical resistance may exceed 500 ° C. Alternatively very fast temperature rises are possible.

The conditions of the thin film heater 123 are as follows.

First, the thin film heater 123 is capable of increasing the temperature at a faster rate than the conventional heater due to the thin film property, but due to this thin film property, the current flow rate (current flux), etc. can be very large, its own electrical / thermal Chemical resistance is required.

That is, the thin film heater 123 should have a high electrical strength (heater strength), and the self-resistance to the energy applied continuously through the metal pad 125 should be high, but the long life of the thin film heater 123 can be maintained. Do.

In addition, the thin film heater 123 is mounted on the insulating film 122, so that the insulating film 122 is not detached due to heat generation and the peeling between the heating plate 113 and the insulating film 122 should not occur.

In addition, the thin film heater 123 is a device that is continuously subjected to a thermal shock, it should be such that a significant increase in the change in its resistance is not caused by the thermal shock.

In addition, the thin film heater 123 may generate heat at a high temperature while being exposed to air (oxygen), but it is necessary to prevent a significant increase in its resistance due to such oxidation.

In order to satisfy the above conditions, a thin metal having a high melting point (eg, Ta, W, Pt, Ru, Hf, Mo, Zr, Ti, etc.) may be used as the material of the thin film heater 123, Combined two-component metal alloys (e.g. TaW, etc.) are used, or two-component metal-nitride series (e.g., WN, MoN, ZrN, etc.) combined with metal-nitride is used, or metal-silicides ( Two-component metal-silicide series (for example, TaSi, WSi, etc.) combining metal-silicide is used.

In addition, the thin film heater 123 may have a thickness of several μm or less (eg, a difference in thickness occurs depending on a material, such as a range of 0.05 μm to 2 μm).

In particular, in order to increase the temperature of the thin film heater 123 instantaneously, that is, to minimize the time taken to heat itself by itself, the heat capacity of the thin film heater 123 itself may be very small.

That is, the heat capacity of the thin film heater 123 is expressed as a function using the thickness as a parameter, and as the thickness of the thin film heater 123 becomes thin, the value thereof decreases. On the other hand, the life of the thin film heater 123 may be shorter as the thickness becomes thinner.

Therefore, in the present invention, the optimum thickness range of the thin film heater 123 may be derived through various simulations and experiments to satisfy two conditions for instantaneously raising the temperature of the thin film heater 123 and extending the life. On the other hand, there is a slight difference depending on the material of the thin film heater 123, it turns out that it is a minute difference.

That is, the optimum thickness of the thin film heater 123 is derived based on the following equation.

(resistivity)는 박막 히터(123) 소재의 고유한 비저항값이고, Rs(sheet resistance)는 박막 히터(123)의 면 저항값이고, t(thickness of film)는 박막 히터(123)의 두께이다. 한편, 두께와 고유 비저항값은 비례 관계에 있음을 알 수 있다.here,

(resistivity) is a specific resistivity value of the thin film heater 123 material, Rs (sheet resistance) is the sheet resistance value of the thin film heater 123, t (thickness of film) is the thickness of the thin film heater 123. On the other hand, it can be seen that the thickness and the specific resistivity are in proportion.

Therefore, in consideration of the specific resistance range of the material of the thin film heater 123, the simulation using the above-described parameters as input data, the optimum thickness range of the thin film heater 123 according to the characteristics of each product according to the material (eg 0.05 μm to 2 μm).

The thin film heater 123 is formed on the insulating film 122 by the vacuum deposition method, the vacuum deposition method PVD (Sputtering, Reactive Sputtering, Co-Sputtering, Evaporation, E-beam, etc.) and CVD (LPCVD, PECVD, etc.) ) Is used.

9 to 11 are exemplary views showing various embodiments of a conductor pattern formed on a thin film heater according to the present invention. As shown in the figure, the electrical resistance is lower than the thin film heater on the thin film heater 123 and the thermal conductivity is low. The high conductor pattern 124 may be formed in various shapes and shapes at various intervals.

If the thin film heater 123 in which the conductor pattern 124 is not formed is used, a temperature difference occurs between the electrode introduction portion and the center portion of the thin film heater 123 at the initial stage of power supply, so that the entire surface of the thin film heater 123 is uniform. The temperature distribution may not be achieved or overheating may occur in a portion of the thin film heater 123, which may cause fatal damage (deterioration) to the thin film heater 123 or the insulating layer 122. The lifespan of) may be extremely short.

That is, in order to prevent such a phenomenon and to generate uniform heat generation on the entire surface of the thin film heater 123 within a faster time at the initial power supply, various shapes as shown in FIGS. 9 to 11 on the thin film heater 123. And to form a conductive pattern 124.

As such, when the conductor pattern 124 is formed on the thin film heater 123, the production yield may be improved as compared to a single thin film heater in which the conductor pattern is not formed in the thin film heater 123. This is because a single thin film heater in which a sieve pattern is not formed can solve a conventional problem leading to deterioration of the quality of the entire resistor even when a small thickness difference of a part of the entire thin film heater or damage of some thin films such as scratches.

Next, with reference to the metal pad 125, the metal pad 125 is mounted on the thin film heater 123, and serves to uniformly supply power supplied from the outside to the thin film heater 123. . In this case, the metal pad 125 may be uniformly grounded on the entire surface of the thin film heater 123 so as to have a uniform (constant) current density on all surfaces of the thin film heater 123.

In particular, the width (thickness) of the metal pad 125 may be greater than or equal to the width (thickness) of the thin film heater 123 in order to have a uniform current density in all surfaces of the thin film heater 123. .

12 to 13 are exemplary views showing various arrangement patterns of the metal pad and the thin film heater according to the present invention. As shown in the drawing, a plurality of heat generating thin film cells form the shape of the metal pad 125. It may be formed in a pattern having various positions, shapes, sizes, and numbers.

The reason for forming the thin film cell is to divide the heat generating area into several parts while preventing the ground parts of the metal pad 125 and the thin film heater 123 from being powered from being destroyed due to overheating when a large amount of power is supplied at a time. In order to control the resistance value of each region.

The material forming the metal pad 125 as described above ensures stability to the temperature of the metal pad 125 when heat is generated from the thin film heater 123, prevents an increase in resistance due to oxidation, and the thin film heater. Metals such as Al, Au, W, Pt, Ag, Ta, Mo, Ti, H, Cu, etc. to prevent desorption from 123 may be used.

Finally, the protective layer 127 is mounted on the outer surfaces of the thin film heater 123 and the metal pad 125 to electrically / chemically protect the thin film heater 123 and the metal pad 125 from the external environment. As the material of the protective layer 127, SiNx, SiOx, AlOx, Polymer, Polyimide, Teflon, etc. may be used, and the thickness of the protective layer 127 is an optimal thickness to exert a heat insulating function and a protective function. And preferably in the range of about 0.1 μm to 100 μm.

The protective layer 127 may be formed in both the thin film heater 123 on which the conductor pattern 124 is formed and the thin film heater 123 in a state where the conductor pattern is not formed.

14 is a schematic view showing the specifications of the specimen for testing the heating characteristics of the heating means according to the present invention, Figure 15 is a temperature change value according to the time displacement in a state in which a constant current (50W) is applied to the specimen of Figure 14 The measured graph is shown, and FIG. 16 shows a graph of measuring a temperature change value according to the displacement of the amount of current applied during the time (10 seconds) specified in the specimen of FIG. 14.

In this case, the temperature values measured through FIGS. 14 to 16 are measured for each component such as the thin film heater 123, the conductor pattern 124, the insulating film 122, the metal pad 125, and the heating plate 113. It should be noted that different results may be obtained depending on resistance value, thickness, material, and the like.

As shown in FIG. 15, it can be seen that a saturation characteristic appears at 287 ° C. after a predetermined time when 50 watt power is applied.

As shown in FIG. 16, it can be seen that the surface temperature change that increases for 10 seconds according to the power change has a linear increase characteristic.

The heating means 120 according to the present invention as described above, the resistance value, thickness, material of each component such as a thin film heater, a conductor pattern, an insulating film, a metal pad, a thin film cell, a heating plate and the like reflecting the design conditions of the product Different applications are applied to reduce surface temperature arrival time and power consumption according to product characteristics, so that the optimum product can be produced.

Referring to the operation of the portable electric range according to the present invention having the configuration as described above are as follows.

First, the power switch of the power supply unit 130 is turned on so that the heat generating means 120 operates. At this time, the power supply unit 130 is configured to be used in the outdoors after receiving 220V household power and charging it in a rechargeable battery.

Of course, the charging method is also possible with a vehicle power source, and can be driven even when the home power source is connected.

The power charged in the power supply unit 130 is input to the metal pad 125 of the heat generating means 120, and is uniformly supplied to the entire area of the thin film heater 123 to allow self heating.

At this time, the thin film heater 123 is rapidly generated from the low power external power source, which is rapidly heated to 120 degrees Celsius or more in 20 seconds when the 400W power is applied.

The heat generated by the thin film heater 123 is transferred to the heating plate 113 through the insulating film 122, and the heating plate 113 indirectly heats the cooking container so that cooking is performed.

At this time, the user can check the cooking temperature and the remaining power through the control unit 133 of the power supply unit 130, and by operating the power switch 134, it is possible to adjust the temperature.

In addition, the present invention as described above has the advantage that the burner unit 110 and the power supply unit 130 can be stored separately or used, in particular by forming a separate output terminal 137 in the power supply unit 130, the burner unit ( In addition to heating 110, it can be used as a power source for driving electronic products such as portable radios, TVs, or lamps.

As mentioned above, although the present invention has been described by way of examples, the embodiments of the present invention are merely examples and should not be construed as limiting the scope of the present invention. Those skilled in the art to which the present invention pertains may modify or alter the present invention in various forms within the principles and scope described in the claims herein.

The present invention as described above is provided with a heating means capable of low power driving using a thin film heater can be configured as a power source using a rechargeable battery has the effect that it is possible to manufacture a portable electric range portable and mobile.

In addition, the present invention has an effect that the burner unit forms a flat heating plate, which is convenient to use, clean, store and manage.

In addition, the present invention has no risk of fire due to the indirect heating is possible to control the temperature through the heat conduction of the heating plate, the thickness of the heating plate and the heating means is made thinner, thereby making it possible to slim the product. The hinged combination of the two heating plates can be folded and stored at the same time, or expanded to be used.

In addition, the present invention by forming a cover detachable to the burner, it is possible to use even in rainy weather, has the effect of minimizing the heat loss even in cold outside environment.

In addition, the present invention is easy and simple to configure and manufacture the heat generating means free design of the whole product, as well as can be used by a simple power switch operation has the effect of convenient operation of the user.

In addition, as the power supply unit of the present invention receives a variety of power supply including a vehicle power supply and a home supply power supply excellent portable and mobile and charged power through a variety of output terminals of various electrical products (lantern, radio, TV, etc.) By allowing to drive, it has the effect that can be used as a multi-purpose charger in outdoor activities.

Claims (15)

Burner unit 110 made of a frame 111 manufactured in a box shape to provide mechanical strength, and a heating plate 113 installed on the upper surface of the frame 111 to be cooked by heat conduction. ; Heating means 120 for applying electric power to the thin film heater 123 formed on the rear surface of the heating plate 113 of the burner unit 110 to generate electric heat; A power supply unit 130 for supplying power to the heat generating means 120; Portable electric range comprising a. The method of claim 1, Portable burner, characterized in that the burner unit 110 and the power supply unit 130 is mechanically and electrically coupled, the power supply unit 130 is a built-in rechargeable battery (139). The method of claim 1, Portable burner, characterized in that the cover (117) from the upper side of the burner unit 110 and the power supply unit 130 is coupled in a detachable state to cook. The method of claim 2, The burner unit 110 is a portable electric range characterized in that at least one or more of the plurality of hinges are folded and stored, or used unfolded. The method of claim 2, The power supply unit 130 includes a control unit 133 configured to form a plurality of input terminal units 131 for receiving at least one or more powers, and to output and control the power charged through the input terminal unit 131. Portable electric range, characterized in that made. The method according to any one of claims 1 to 5, The heating means 120, A heating plate 113 made of a non-conductive material; A thin film heater 123 mounted on the rear surface of the heating plate 113 and receiving power from the outside to instantaneously generate high temperature by instantaneous heating according to its own electrical resistance; And A metal pad 125 having electrical connection to the thin film heater 123 and having a specific pattern such that power supplied from the outside may be uniformly applied to the entire surface of the thin film heater 123; Portable electric range comprising a. The method of claim 6, The heating means 120, A heating plate 113 made of a conductive material; An insulating film 122 coated on the rear surface of the heating plate 113 to have a predetermined thickness to provide electrical insulating properties and excellent thermal conductivity properties; A thin film heater 123 mounted in the form of a thin film on the lower portion of the insulating film 122 and receiving power from the outside to instantaneously generate high temperature by instantaneous heating according to its own electrical resistance; And A metal pad 125 having electrical connection to the thin film heater 123 and having a specific pattern such that power supplied from the outside may be uniformly applied to the entire surface of the thin film heater 123; Portable electric range comprising a. The method of claim 7, wherein Portable electric range characterized in that the metal pad 125 and the thin film heater 123 is coated with a protective layer 127 of a predetermined thickness to protect from the external environment. The method of claim 7, wherein By forming a conductor pattern 124 through which the current flows on the thin film heater 123, the current applied through the metal pad 125 is uniformly supplied to the entire surface of the thin film heater 123, and heat generation characteristics are improved. Portable electric range, characterized in that to be stable. The method of claim 7, wherein The metal pad 125 is a portable electric range, characterized in that to form a pattern to form a plurality of heat generating thin film cells. The method of claim 7, wherein The thin film heater 123 is a combination of a single metal or a two-component metal alloy or a metal-nitride in combination with the metal or a two-component metal-nitride or metal-silicide in combination with the metal-nitride. A portable electric range comprising any one of a two-component metal silicide or a thick film conductive paste. The method of claim 7, wherein The metal pad 125 is set so that its width is greater than or equal to the width of the thin film heater so that current density can be uniformly supplied to the thin film heater 123, and is stable to temperature during heat generation, and according to oxidation A portable electric range comprising any one of Al or Au or W or Pt or Ag or Ta or Mo or Ti, which increases resistance and prevents physical peeling. The method of claim 7, wherein The insulating film 122 may include an oxide insulating film formed by oxidizing the surface of the heating plate 113 with an arc or a polymer insulating film formed by coating a polymer on the surface of the heating plate 113, or the oxide insulating film and a polymer insulating film on the surface of the heating plate. Portable electric range, characterized in that any one of the formed double insulating film. The method of claim 13, The insulating film 122 has a dielectric breakdown voltage of 1000V or more, and has a leakage current of 20 mA or less when 100V voltage is applied. The method of claim 13, The oxide insulating film is any one of metal oxides including aluminum oxide or beryllium oxide or titanium oxide, and the polymer of the polymer insulating film is polyimide or polyamide or teflon or paint. Or silver-ston or tefzel-s or epoxy or rubber.

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