KR102252570B1 - Electric range capable of recognizing shape and size of cooking vessel using capacitance sensors - Google Patents

Abstract

The present invention relates to an electric range capable of recognizing a shape and size of a cooking container using a capacitance sensor that allows a plurality of capacitance sensors spaced at regular intervals on a lower part of a plate to be arranged in a matrix form of (Xn)×(Yn), allows the outline formed by connecting each end point to be configured to recognize the shape and size of the cooking container by using coordinates located at the outermost part of the capacitance sensor matrix that changes as the cooking container is mounted on the plate, and allows only the heating part located at a lower part of the cooking container to be operated, thereby allowing for efficient cooking by minimizing unnecessary use of electricity.

Description

Electric range capable of recognizing shape and size of cooking vessel using capacitance sensors}

The present invention relates to an electric range capable of recognizing the shape and size of a cooking vessel using a capacitive sensor, and more particularly, a plurality of capacitive sensors spaced at predetermined intervals under a plate (Xn)×(Yn). It is arranged in the form of a matrix of dogs, and the outline of each end point is recognized as the shape and size of the cooking container using the coordinates located at the outermost part of the capacitance sensor matrix, which changes as the cooking container is seated on the plate. By configuring, since it is possible to operate only the heating unit located under the cooking container, the electric range that can recognize the shape and size of the cooking container by using a capacitive sensor capable of efficient cooking by minimizing unnecessary use of electricity will be.

In general, an electric range is a device that cooks food by heating a heating element by electricity. Unlike a gas range, this electric range is not a direct heating method, so no harmful gas is generated and gas leaks. It is safe from fire because there is no risk of gas explosion due to this, and there is no risk of burns, and it provides pleasant indoor air without odor.

In addition, unlike a gas range, the electric range is very advantageous in that it is installed in a built-in method as it is configured to mount a container on a simple exterior, particularly a flat plate.

The above'electric range' is published in Utility Model Registration No. 20-0463751 (hereinafter referred to as'Patent Document 1').

Referring to Patent Document 1, in the conventional'electric range', a top plate 20 having a heater mounting hole 21 formed in the base 10 is formed, and in the heater mounting hole 21 of the top plate 20 A coil heater 30 is formed to be exposed to the top, a reflection tray 31 and an auxiliary tray 32 are sequentially formed at the bottom of the coil heater 30, and a connection plug ( 41) is formed, and the connection plug 41 is coupled to the connection socket 42 attached to the lower end of the upper plate 20,

The periphery of the heater mounting hole 21 of the upper plate 20 is formed with an inflow prevention step 21a inclined to the top, and the ends of the reflective tray 31 and the auxiliary tray 32 have a wedge-shaped cross-sectional shape. An inclined reflection fixing part 31a and an auxiliary fixing part 32a are formed, respectively, and a cut-out part 32c is formed in the auxiliary tray 32.

Patent Document 1 composed of the above configuration is easy to repair and replace the connection socket because the reflective tray and the auxiliary tray are not combined with each other, so it is easy to repair and replace the connection socket. Not only can it be made more sturdy, but it is also constructed to prevent foreign substances such as soup from seeping into the auxiliary tray by an inflow prevention step.However, in order to check the presence or absence of a container, current must be passed through the coil heater to check the magnitude of current Therefore, a large current is passed every time the container is sensed, and unnecessary electricity is wasted for the determination of the presence or absence of the container, and for this reason, there is a problem that the container is not always detected and is executed only when a specific operation is performed.

In addition, when the container is sensed, it is impossible to check the size of the container, so that all coil heaters are operated, resulting in unnecessary waste of electricity.

Patent Document 1: Republic of Korea Utility Model Publication No. 20-0463751

The present invention was conceived to solve the above-described problem, and an object of the present invention is to arrange a plurality of capacitive sensors spaced at a predetermined interval under the plate in the form of (Xn)×(Yn) matrices, and the cooking vessel is plated. The heating unit located under the cooking container is configured to recognize the shape and size of the cooking container by using the coordinates located at the outermost part of the capacitive sensor matrix, which changes as it is settled. Since it is possible to operate only, it is to provide an electric range capable of recognizing the shape and size of a cooking container using a capacitive sensor capable of efficient cooking by minimizing unnecessary use of electricity.

In order to solve the above problems, an electric range capable of recognizing the shape and size of a cooking container using a capacitive sensor according to a preferred embodiment of the present invention includes: a plate on which the cooking container is mounted; A heating unit located under the plate to heat the cooking vessel; A capacitance sensor arranged in the form of a matrix of (Xn)×(Yn) in a state spaced apart from the lower surface of the plate and measuring a capacitance value according to whether or not the cooking vessel is seated on the upper surface of the plate; A signal conversion unit converting a capacitance value transmitted from the capacitance sensor into a digital signal; And a control unit that calculates the shape and size of the cooking vessel using a plurality of capacitance sensors in which capacitance change is sensed through the digital signal converted from the signal conversion unit.

In addition, the control unit uses the coordinates located at the outermost part of the capacitive sensors in which the change in capacitance occurs as the cooking container is seated on the plate, and uses the coordinates located at the outermost part of the capacitive sensor to determine the shape and size of the cooking container. It is characterized in that it is configured to recognize.

In addition, the heating unit is formed of a plurality of individually controllable by the control unit, and is configured to match the plurality of capacitive sensors one-to-one or many-to-one.

In addition, the control unit controls the operation of the heating unit according to the change of the capacitive sensor, and operates only the heating unit matching the capacitive sensor in which the change in capacitance is detected through the digital signal converted from the signal conversion unit. It characterized in that it is configured.

In addition, it characterized in that it further comprises a; display unit for displaying the shape and size of the cooking vessel recognized by the control unit.

As described above, according to the present invention, a plurality of capacitive sensors spaced at predetermined intervals under the plate are arranged in the form of (Xn)×(Yn) matrices, and the change occurs as the cooking vessel is seated on the plate. By using the coordinates located at the outermost part of the capacity sensor matrix to recognize the completed outline by the shape and size of the cooking container, it is possible to operate only the heating part located under the cooking container, so unnecessary electricity There is an advantage in that the use can be minimized and efficient cooking can be proceeded.

1 is a configuration diagram of an electric range capable of recognizing the shape and size of a cooking vessel using a capacitive sensor according to a preferred embodiment of the present invention.
2 is a schematic diagram showing a connection state of a capacitance sensor of an electric range capable of recognizing the shape and size of a cooking vessel using a capacitance sensor according to a preferred embodiment of the present invention, a signal conversion unit, and a control unit.
3 is a block diagram showing the configuration of an electric range capable of recognizing the shape and size of a cooking vessel using a capacitive sensor according to a preferred embodiment of the present invention.
FIG. 4 is an explanatory view showing an arrangement of capacitive sensors of an electric range capable of recognizing the shape and size of a cooking vessel using the capacitive sensor according to a preferred embodiment of the present invention.
5 to 7 are explanatory diagrams showing a process of recognizing a shape of a cooking vessel of an electric range capable of recognizing a shape and size of a cooking vessel using a capacitive sensor according to a preferred embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings. The same reference numerals shown in each drawing indicate the same members.

1 is a configuration diagram of an electric range capable of recognizing the shape and size of a cooking vessel using a capacitive sensor according to a preferred embodiment of the present invention, and FIG. 2 is a capacitive sensor according to a preferred embodiment of the present invention. Thus, it is a schematic diagram showing a connection state of a capacitive sensor of an electric range capable of recognizing the shape and size of a cooking container, a signal converter, and a control unit, and Fig. 3 is a cooking container using a capacitive sensor according to a preferred embodiment of the present invention. It is a block diagram showing the configuration of an electric range that can recognize the shape and size.

4 is an explanatory view showing the arrangement of the capacitive sensor of an electric range capable of recognizing the shape and size of a cooking vessel using the capacitive sensor according to a preferred embodiment of the present invention, and FIGS. 5 to 7 are the present invention. Is an explanatory diagram showing a process of recognizing the shape of a cooking vessel of an electric range capable of recognizing the shape and size of the cooking vessel using a capacitive sensor according to a preferred embodiment of FIG.

1 to 7, the electric range 100 capable of recognizing the shape and size of a cooking vessel using a capacitive sensor according to a preferred embodiment of the present invention includes a plate 110, a heating unit 120, and It includes a capacitive sensor 130, a signal conversion unit 140, and a control unit 150.

The plate 110 is one on which the cooking container 10 is mounted, and is preferably configured to display a plurality of craters 111 so that a user can easily check the mounting position of the cooking container 10.

The heating unit 120 heats the cooking vessel 10 in a state fixed by the heating unit support 190 under the plate 110, and in the present invention, the heating unit 120 includes a plurality of It is characterized in that the dogs are formed separately and are configured to be individually controlled by the control unit 150.

The heating unit 120 is configured to be matched one-to-one with a plurality of capacitive sensors 130, respectively, or a plurality of capacitive sensors and one heating unit are matched many-to-one. When the cooking vessel 10 is seated on the plate 110, it is possible to operate only the heating unit 120 matched with the capacitance sensor 130 in which a change in capacitance is detected by the control of the controller 150, It is possible to conduct efficient cooking by minimizing unnecessary use of electricity.

The capacitance sensor 130 is positioned on the lower surface of the plate 110 and measures a capacitance value according to whether the cooking vessel 10 is seated on the upper surface of the plate 110. As shown in FIG. 4, the capacitive sensor 130 is characterized in that a plurality of the capacitive sensors 130 are arranged in a matrix form of (Xn)×(Yn) in a state spaced at a predetermined interval.

As the capacitive sensors 130 are arranged in a (Xn) × (Yn) matrix form, the control unit 150 allows the cooking vessel 10 to be seated at a certain position through the respective installation coordinates of the capacitive sensor 130. It is possible to check whether or not it has been achieved, and the capacitance value measured through the capacitance sensor 130 is compared to the case where the cooking vessel 10 of a metal body is not present on the upper surface of the plate 110, the cooking vessel 10 is When seated, a value increased by about 10 to 20 pF is shown, and when a change in the capacitance value occurs, it is transmitted to the signal conversion unit 140.

The signal conversion unit 140 converts the capacitance value transmitted from the capacitance sensor 130 into a digital signal, and the controller 150 calculates the shape and size of the cooking container through the change in capacitance. The converted digital signal is transmitted to the control unit 150 to be possible.

The control unit 150 calculates the shape and size of the cooking container 10 using a plurality of capacitance sensors 130 in which capacitance change is detected through the digital signal converted from the signal conversion unit 140. In the present invention, the control unit 150 is a capacitance sensor 130 ′ in which a change in capacitance occurs as the cooking container 10 is seated on the plate 110 as shown in FIGS. 5 to 7. It is characterized in that it is configured to recognize the shape and size of the cooking container 10 to a finished outline connecting each end point using coordinates located at the outermost part of the center. Accordingly, the control unit 150 may recognize the shape and size of various cooking containers 10 such as a circle, a square, and a deformed shape.

In addition, the control unit 150 is characterized in that it is configured to control the operation of the heating unit 120 according to a change in the capacitance value measured through the capacitance sensor 130, from the signal conversion unit 140 It is configured to operate only the heating unit 120 matched with the capacitance sensor 130 ′ in which the capacitance change is sensed through the converted digital signal. Accordingly, as shown in FIG. 1, the cooking container 10 As it is possible to heat the cooking container 10 through the heating unit 120 located directly below the cooking vessel 10, it is possible to efficiently cook by minimizing unnecessary use of electricity.

On the other hand, the electric range 100 of the present invention may be provided with an operation button 160 for cooking food, the operation button 160 is a button that can memorize the user's direct input and recipe, food cooking start. It may be configured in various ways, such as a button for commanding or a button indicating that it is completed when a change of food is required.

In addition, the electric range 100 of the present invention is preferably provided with a display unit 170 that displays the shape and size of the cooking container 10 recognized by the control unit 150, including the cooking state of the food.

In addition, the electric range 100 of the present invention may be provided with a storage unit 180 for storing a recipe, etc., and the storage unit 180 includes a capacitance sensor 130 in which a change in capacitance is detected by the controller 150. It is preferable that matching information between the heating unit 120 and the capacitance sensor 130 is stored so that only the heating unit 120 matched with') can be operated.

In addition, the electric range 100 of the present invention is provided with an alarm function that notifies the user to recognize when the cooking container 10 is separated. The alarm function includes the display unit 170 of the electric range 100. It may be displayed through or be configured to output a warning sound, and may be configured in various forms, such as notifying the occurrence of departure of the cooking vessel 10 to a user terminal registered in the electric range 100.

In the present invention, as described above, a plurality of capacitive sensors 130 spaced at predetermined intervals under the plate 110 are arranged in a matrix form of (Xn)×(Yn), and the cooking container 10 is provided with a plate ( 110) by using the coordinates located at the outermost part of the matrix of the capacitive sensor 130 ′, which changes as it is seated, and is configured to recognize the finished outline as the shape and size of the cooking container 10 by connecting each end point. , Since it is possible to operate only the heating unit 120 located under the cooking container 10, efficient cooking is possible by minimizing unnecessary use of electricity.

Optimal embodiments have been disclosed in the drawings and specification. Although specific terms have been used herein, these are only used for the purpose of describing the present invention, and are not used to limit the meaning or the scope of the present invention described in the claims. Therefore, those of ordinary skill in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

10: cooking container 100: electric range
110: plate 111: crater
120: heating unit 130: capacitive sensor
140: signal conversion unit 150: control unit
160: operation button 170: display
180: storage unit 190: heating unit support

Claims (5)

A plate on which the cooking container is mounted;
A heating unit located under the plate to heat the cooking vessel;
A capacitance sensor arranged in the form of a (Xn)×(Yn) matrix in a state spaced apart from the lower surface of the plate in the form of (Xn)×(Yn), and measuring a capacitance value according to whether or not the cooking vessel is seated on the upper surface of the plate;
A signal conversion unit converting a capacitance value transmitted from the capacitance sensor into a digital signal; And
Including; a control unit that calculates the shape and size of the cooking vessel using a plurality of capacitance sensors in which capacitance change is detected through the digital signal converted from the signal conversion unit,
The control unit is configured to recognize, as the shape and size of the cooking container, an outline that is completed by connecting each end point using a coordinate located at the outermost part of the capacitive sensor in which the change in capacitance occurs as the cooking container is seated on the plate. Is composed,
The heating unit consists of a plurality of individually controllable by the control unit, and is configured to match the plurality of capacitive sensors one-to-one,
The control unit is configured to control the operation of the heating unit according to the change of the capacitive sensor, and operate only the heating unit matched with the capacitive sensor in which the change in capacitance is sensed through the digital signal converted from the signal conversion unit. Electric range capable of recognizing the shape and size of a cooking vessel using a capacitive sensor, characterized in that.
delete delete delete The method according to claim 1,
An electric range capable of recognizing the shape and size of the cooking container by using a capacitive sensor, further comprising: a display unit for displaying the shape and size of the cooking container recognized by the control unit.

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