KR20230112218A - Smart induction system automatically controlled by remote controller - Google Patents

Abstract

Provided is a smart induction system automatically controlled by a remote control comprising: an induction unit that heats an induction-only container; and a remote control unit that wirelessly controls the induction unit, wherein the remote control unit measures at least one or more temperature values of an only-container during a cooking process, and controls an operation of the induction unit based on the temperature value. Therefore, the present invention is capable of preventing an accident such as a fire and the like in advance.

Description

Smart induction system automatically controlled by remote control {SMART INDUCTION SYSTEM AUTOMATICALLY CONTROLLED BY REMOTE CONTROLLER}

The present invention relates to an induction system, and more particularly, to a smart induction system capable of automatically controlling the output of an induction using the temperature of a dedicated container measured through a remote control during a cooking process.

As a heating device for cooking food, a microwave oven, a gas stove, an oven, and the like have been used. However, the use of an induction range has recently been increasing due to problems such as indoor air pollution and an increase in indoor temperature. Induction is a heating cooking appliance adopting an induction heating method, and has great advantages in terms of high energy efficiency and stability. In addition, induction has the advantage that there is no consumption of oxygen and no discharge of waste gas. In induction, when a line of magnetic force generated by flowing a high-frequency current passes through the bottom of a dedicated container placed above the induction, only the dedicated container itself is heated using eddy currents generated by resistance components.

On the other hand, induction is used by placing a dedicated container directly on the top plate of the induction oven itself because the range of the magnetic field is relatively narrow. Unlike this, in some cases, the installation location is changed to the lower part of the dining table due to contamination or damage caused by existing food. In this case, a wired remote control or the like can be used to solve the inconvenience of control because the induction is located under the dining table.

On the other hand, there is a difference in baking food such as meat or fish depending on the cooking temperature, which influences the difference in taste, and there is an inconvenience that expensive foods must be cooked by a skilled person. In addition, since the induction system is a device for transferring heat, there is a problem in that it may cause an indoor fire accident due to user carelessness.

Republic of Korea Patent Registration No. 10-2045993 (registered on November 12, 2019) Republic of Korea Patent Publication No. 10-2019-0134951 (published on December 5, 2019) Republic of Korea Patent Registration No. 10-2021332 (registered on September 6, 2019)

Embodiments of the present invention have been devised to solve the above problems, and can automatically control the size of the output (power) of induction using the temperature value of the bottom surface of the induction-only container measured during cooking in real time. To provide a smart induction system.

On the other hand, temperature measurement is a non-contact method, and it is intended to be applied to a remote control, which is a wireless controller of induction. In addition, it is intended to provide multipurpose functions by adding a function of measuring body temperature and monitoring an indoor fire when cooking is not done to a remote controller. Through this, we want to prevent accidents such as fire caused by induction in advance.

In addition, by using the remote control attached to the induction, to control the induction in a variety of ways.

An embodiment of the present invention to solve the above problems, the induction unit for heating the dedicated induction container; And a remote control unit for wirelessly controlling the induction unit; wherein the remote control unit measures at least one temperature value of the exclusive container during the cooking process, and controls the operation of the induction unit based on the temperature value. It provides a smart induction system automatically controlled by a remote control, characterized in that.

Preferably, the remote control unit includes a non-contact type temperature sensor unit, and the measured temperature value is transmitted to the induction unit in real time.

The temperature value is preferably the surface temperature of the bottom surface of the exclusive container.

The induction unit further includes a control module, and the control module preferably changes the amount of power supplied to the induction unit in accordance with the temperature value received from the remote control unit.

When information on the type of food to be cooked is input to the induction unit, the control module may automatically change the power while gradually changing it according to the lapse of a preset time.

The remote control unit preferably operates in any one mode selected from among a body temperature check mode for checking the temperature of a human body by a pressing operation of a temperature sensing button, a cooking mode for measuring the surface temperature of the bottom surface of the exclusive container, and an indoor monitoring mode for monitoring the indoor temperature in a space in which the induction unit is installed.

When the cooking mode is selected, the remote control unit is wirelessly connected to the induction unit, and it is preferable to switch the induction unit from an off mode or a standby mode to a heating mode.

According to the problem solving means of the present invention as described above, various effects including the following can be expected. However, the present invention is not established when all of the following effects are exhibited.

The smart induction system according to an embodiment of the present invention can automatically control the output (power) of induction by using the temperature value of the bottom surface of the induction-only vessel measured during cooking in real time.

In addition, the temperature of the bottom surface of the exclusive container can be measured in a non-contact manner using a remote controller, which is a wireless controller of induction. In the case of not cooking, a function of measuring the body temperature and monitoring indoor fires may be provided together. Through this, accidents such as fire due to induction can be prevented in advance.

In addition, the induction can be controlled in a variety of ways using a remote control attached to the induction.

1 is a diagram showing a schematic configuration of a smart induction system according to an embodiment of the present invention.
Figure 2 is a block diagram of Figure 1;
3 is a view showing that the remote control unit of FIG. 1 operates in any one of a body temperature checking mode, a cooking mode, and an indoor monitoring mode.
4 is a view showing a process in which the induction unit of FIG. 1 is switched between an off mode, a standby mode, and a heating mode;

In order to fully understand the configuration and effects of the present disclosure, preferred embodiments of the present disclosure will be described with reference to the accompanying drawings. However, the present disclosure is not limited to the embodiments disclosed below, and may be implemented in various forms and various changes may be made. Hereinafter, in the description of the present invention, detailed descriptions thereof will be omitted if it is determined that the related known functions may unnecessarily obscure the subject matter of the present invention as obvious matters to those skilled in the art.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms may only be used for the purpose of distinguishing one component from another. For example, a first element may be termed a second element, and similarly, a second element may be termed a first element, without departing from the scope of the present disclosure.

In this application, the terms "comprise" or "have" are intended to designate that the features, numbers, steps, operations, components, parts, or combinations thereof described in the specification exist, but it should be understood that the presence or addition of one or more other features or numbers, steps, operations, components, parts, or combinations thereof is not excluded in advance.

Terms used in this application are only used to describe specific embodiments and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. Terms used in the embodiments of the present disclosure may be interpreted as meanings commonly known to those skilled in the art unless otherwise defined.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. 1 is a diagram showing a schematic configuration of a smart induction system according to an embodiment of the present invention, FIG. 2 is a block diagram of FIG. 1, and FIG. 3 is a temperature check mode, a cooking mode, and an indoor monitoring mode of the remote control unit of FIG.

1 to 4, the smart induction system according to an embodiment of the present invention may include an induction unit 200, a remote control unit 300, a control module 210, a temperature sensor unit 320, and the like. In addition, the present system may further include an induction vessel 400 having excellent energy efficiency.

The smart induction system may be installed on the table 100 or the like. The table 100 may include a frame portion and a top plate coupled to the upper portion of the frame portion. Here, at least one table 100 may be arranged in one space. The top plate is positioned at a certain height from the ground. The top plate is an object on which the induction unit 200 is installed, and may mean, for example, a top plate such as a dining table. In one embodiment, the induction unit 200 may be installed on the upper side of the top plate.

Alternatively, the induction unit 200 may be installed below the top plate 110 . At this time, a top plate 110 for transmitting a magnetic field may be coupled to the table 100 . Such a top plate 110 may be formed of any one material selected from the group of non-magnetic materials such as marble, wood, and glass, for example. In addition, the upper plate 110 is formed in a flat plane with upper and lower surfaces, and preferably has a thickness within a preset range. In addition, the thickness range of the top plate 110 may be changed according to its material.

In one embodiment, the induction unit 200 heats the container 400 dedicated to induction. The induction unit 200 heats food in the exclusive container 400 in an indirect manner by inducing heat to the exclusive container 400 itself using a magnetic field. The induction unit 200 according to an embodiment is fixedly installed below the top plate 110 of the table 100 and heats the exclusive container 400 located above the top plate 110. In one embodiment, the induction unit 200 induces the magnetic field formed by the internal circular coil to the exclusive container 400 located on the upper side of the top plate 110.

Specifically, the induction unit 200 may include a case, a coil base unit (not shown), a circular coil (not shown), a control module 210, a power supply unit 220, a first communication module 230, and a recipe mapping unit 240 and the like. The coil base unit according to one embodiment is preferably disposed close to or in contact with the upper inner surface of the case. This is due to the fact that this system is an under induction system in which the induction unit 200 is disposed below the top plate 110 of the table 100. As a result, induction heating performance of the induction unit 200 can be further improved.

The circular coil is disposed in the limited inner space of the case, particularly the coil base portion. As a result, the circular coil according to an embodiment needs to maximize the heating efficiency of the container 400 by increasing the number of turns per unit area. To this end, the circular coil is wound concentrically on the coil base a plurality of times, and may be formed to have at least one stage.

The control module 210 generates a plurality of control signals for controlling the operation of the induction unit 200 . The control module 210 may be formed using an electric wire formed on a printed circuit board and circuit elements such as semiconductors, capacitors, and resistors mounted on the upper surface thereof. The control module 210 may change the amount of power supplied to the induction unit 200 depending on the temperature value received from the remote control unit 300 . Meanwhile, in one embodiment, the control module 210 may adjust the output of the induction unit 200 to any one of a plurality of non-continuous output stages.

The power unit 220 includes a power On/Off button. When the power of the induction unit 200 is turned on, the induction unit 200 may be switched from an off mode to a standby mode. In this system, when the induction unit 200 is converted from a standby mode to a heating mode, a heating operation for the exclusive container 400 may be started. Meanwhile, in order to switch the induction unit 200 from the standby mode to the heating mode, the induction unit 200 may further include a mode conversion button. The mode of the induction unit 200 may be changed between a standby mode and a heating mode by pressing a mode change button.

Unlike this, in order for the induction unit 200 to switch from the standby mode to the heating mode, the induction unit 200 may be set to receive a preset control signal through the remote control unit 300. For example, when a cooking mode (A2), which will be described later, is selected in the remote control unit 300, the remote control unit 300 is wirelessly connected to the induction unit 200, and the induction unit 200 is off mode or standby mode. Can be switched to heating mode. That is, the induction unit 200 can be switched from an off mode to a heating mode even without a pressing operation of the power On/Off button.

Meanwhile, when the power of the induction unit 200 is turned off by pressing the power on/off button, the heating mode or the standby mode is switched to the off mode. In contrast, when the cooking mode (A2) already selected by the remote control unit 300 is changed to the body temperature check mode (A1) or the indoor monitoring mode (A3), the remote control unit 300 transmits a radio signal about the mode change to the induction unit 200, so that the induction unit 200 can be switched from the heating mode to the standby mode. At this time, the control module 210 may cut off power supplied to the circular coil for heating.

The first communication module 230 is electrically connected to the control module 210 and functions to transmit and receive radio signals to and from the second communication module 350 of the remote control unit 300 . The first communication module 230 may wirelessly transmit and receive data using short-distance wireless communication technology. For example, the first communication module 230 may use technologies such as Bluetooth, Wi-Fi, and ZigBee. The first communication module 230 can receive only radio signals transmitted from the induction unit 200 and any one remote control unit 300 constituting one set.

The remote control unit 300 wirelessly controls the induction unit 200. The remote control unit 300 may control some of the operations of the induction unit 200 at a location spaced apart from the induction unit 200 by a predetermined distance. The remote control unit 300 according to an embodiment is characterized in that it measures at least one temperature value of the exclusive container 400 during the cooking process, and controls the operation of the induction unit 200 based on the temperature value.

In one embodiment, the remote control unit 300 is matched one-to-one (1:1) with the induction unit 200 and may be provided to form a pair. In this system, the remote control unit 300 has a function of switching the one-to-one matching induction unit 200 from an off mode or a standby mode to a heating mode, a function of measuring the surface temperature of the bottom surface of the exclusive container 400 in a non-contact manner, a function of transmitting the temperature value measured in the exclusive container 400 to the induction unit 200 in real time to automatically change the output of the induction unit 200, and an induction unit 200 A function of converting the heating mode or the standby mode to the off mode may be provided.

For example, in order to convert the induction unit 200 from the standby mode to the heating mode, the user presses the temperature sensing button 340 so that the remote control unit 300 enters the cooking mode A2. That is, when the remote control unit 300 is in the cooking mode (A2), the remote control unit 300 transmits a radio signal according to the selection of the cooking mode (A2) to the induction unit 200, so that the induction unit 200 can be turned off or in the standby mode to the heating mode.

Specifically, the remote control unit 300 may include a body part 310, a temperature sensor part 320, a display part 330, a temperature sensing button 340, a second communication module 350, and the like. A display unit 330 that visually informs various operating states of the remote control unit 300 is disposed on the front of the body unit 310. A printed circuit board electrically connected to the temperature sensor unit 320, the temperature sensing button 340, the second communication module 350, and the display unit 330 is disposed inside the body unit 310.

The temperature sensor unit 320 may measure the temperature of a subject to be measured in a non-contact manner. Through this, the remote control unit 300 may measure the actual temperature of the bottom surface of the induction container 400 while food is being cooked by heating, for example. In addition, the remote control unit 300 may measure the body temperature of visitors planning to dine in the same space or perform a monitoring function such as fire monitoring for an indoor space where a smart induction system is installed.

The temperature sensing button 340 may be disposed on any one side of the main body 310 . The user may activate the operation of the temperature sensor unit 320 through a pressing operation on the temperature sensing button 340 . For example, the remote control unit 300 can operate in any one mode selected from among a body temperature check mode (A1) for checking the temperature of a human body, a cooking mode (A2) for measuring the surface temperature of the bottom surface of the dedicated container 400, and an indoor monitoring mode (A3) for monitoring the indoor temperature in the space where the induction unit 200 is installed by pressing the temperature sensing button 340. Here, each mode of the remote control unit 300 can be sequentially changed by pressing the temperature sensing button 340 .

Meanwhile, when the cooking mode (A2) is selected, the remote control unit 300 is wirelessly connected to the induction unit 200, and can switch the induction unit 200 from an off mode or a standby mode to a heating mode. At this time, when the temperature of the exclusive container 400 is measured through the remote control unit 300, the temperature value is displayed through the display unit 330, and the first communication module through the second communication module 350. It is transmitted to the 230 in real time.

In the cooking mode (A2), in order to measure the temperature of the bottom surface of the exclusive container 400 in a non-contact manner, the user directs the temperature sensor unit 320 exposed through one side of the remote control unit 300 to the bottom surface of the exclusive container 400 being cooked. At this time, the surface temperature of the bottom surface of the cooking vessel may be detected through the temperature value measured by the temperature sensor unit 320 . Meanwhile, the measured temperature value may be transmitted to the induction unit 200 in real time. This temperature value is wirelessly transmitted to the first communication module 230 of the induction unit 200 through the second communication module 350 . The second communication module 350 uses the same short-range wireless communication technology as the first communication module 230 .

During the cooking process, most users cannot check the actual temperature of the bottom surface of the exclusive container 400 in which food is cooked. Therefore, when the user grills meat through the exclusive container 400, the user grills the meat while adjusting the output of the induction unit 200 depending on experience, etc., without knowing the temperature of the bottom surface of the exclusive container 400. However, when heated at an optimum temperature according to the food, the food may provide a natural taste.

Accordingly, in one embodiment, the remote control unit 300 measures the actual temperature value of the bottom surface of the exclusive container 400 to automatically control the output of the induction unit 200 through this. That is, when the temperature value is low or high, the induction unit 200 may automatically raise or lower the output of the induction unit 200 .

Meanwhile, in one embodiment, when information on the type of food to be cooked is input to the induction unit 200, the control module 210 may automatically change power step by step over a preset time. To this end, the induction unit 200 may further include, for example, a recipe mapping unit 240 . The recipe mapping unit 240 may include information about an optimal heating temperature according to the type of food. Specifically, the type of food and the optimal power level according to the input of the temperature value of the bottom surface of the exclusive container 400 are mapped in advance, and the power level of the induction unit 200 is automatically increased or decreased based on these data. If it is determined that the optimum heating temperature is not converged even by measuring the temperature value, the temperature value measurement through the remote control unit 300 in the cooking mode (A2) may be performed a plurality of times or more.

On the other hand, in one embodiment, the remote control unit 300 can automatically transmit a warning message to a specific terminal or the like when the temperature value measured in the indoor monitoring mode (A3) is greater than or equal to a preset warning value according to the occurrence of a fire. This can effectively prevent safety accidents such as indoor fires.

In addition, the remote control unit 300 may include a mode changing unit that automatically changes the indoor monitoring mode (A3) to the cooking mode (A2). The remote control unit 300 may change the indoor monitoring mode A3 to the cooking mode A2 when the temperature value measured in real time in the indoor monitoring mode A3 exceeds a preset unacceptable value. Here, the unacceptable value may mean, for example, a high temperature of 100 degrees Celsius or more. An unacceptable value is a value that cannot be measured at room temperature. Here, the unacceptable value may mean a temperature value higher than the warning value.

In one embodiment, if the control module 210 disposed in the induction unit 200 is a first control unit, the remote control unit 300 is like a second control unit that double-controls the power supplied to the circular coil in order to automatically provide an actual optimal heating temperature in the cooking process through the induction unit 200 to provide convenience in cooking. Even when the size of the power of the induction unit 200 is already controlled by the control module 210, when a temperature value is received through the remote control unit 300, the induction unit 200 prioritizes the received temperature value. In order to immediately change the size of the power, the power supplied to the circular coil is adjusted. Through this, this smart induction system can secure the convenience of cooking.

In the above, preferred embodiments of the present invention have been described by way of example, but the scope of the present invention is not limited only to these specific embodiments, and can be appropriately changed within the scope described in the claims.

100: table 200: induction unit
300: remote control unit 400: exclusive container
110: top plate
210: control module 220: power unit
310: body part 320: temperature sensor part
330: display unit 340: temperature detection button

A1: Body temperature check mode A2: Cooking mode
A3: Indoor monitoring mode M1: Off mode
M2: standby mode M3: heating mode

Claims (7)

An induction unit that heats an induction-only container; and
A remote control unit for wirelessly controlling the induction unit; includes,
The remote control unit measures at least one temperature value of the exclusive container during the cooking process, and controls the operation of the induction unit based on the temperature value.
According to claim 1,
The remote control unit includes a non-contact temperature sensor unit, and the measured temperature value is transmitted to the induction unit in real time, characterized in that the smart induction system automatically controlled by the remote control.
According to claim 1,
The temperature value is a smart induction system automatically controlled by a remote control, characterized in that the surface temperature of the bottom surface of the dedicated container.
According to claim 1,
The induction unit further includes a control module;
The control module is dependent on the temperature value received from the remote control unit, smart induction system automatically controlled by the remote control, characterized in that to change the size of the power supplied to the induction unit.
According to claim 4,
When information on the type of food to be cooked is input to the induction unit, the control module is automatically controlled by a remote control, characterized in that the power is automatically changed while gradually changing over a preset time. Smart induction system.
According to claim 1,
The remote control unit, by the pressing operation of the temperature sensing button,
A smart induction system that is automatically controlled by a remote control, characterized in that it operates in any one mode selected from a body temperature check mode for checking the temperature of the human body, a cooking mode for measuring the surface temperature of the bottom surface of the exclusive container, and an indoor monitoring mode for monitoring the indoor temperature in the space where the induction unit is installed.
According to claim 6,
When the cooking mode is selected, the remote control unit is wirelessly connected to the induction unit, and automatically controlled by the remote control, characterized in that for switching the induction unit from an off mode or a standby mode to a heating mode. Smart induction system.

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