KR101288551B1 - Induction range with high frequency induction heating technology - Google Patents

Abstract

The present invention relates to an induction stove, and more particularly, a working coil in which a high frequency induction magnetic field is generated under a plate on which a cooking container is placed, and thus a controller of power control and high frequency oscillation control for generating a high frequency induction magnetic field. High-frequency induction heating induction stove to minimize the power consumption by heating at a high efficiency by cooling with high efficiency by forming a cooling unit having a high cooling function to one side to prevent overheating of the process and the inside of the device It is about.
Such a feature of the present invention is a stove cover case having a working coil in which a high frequency magnetic field is generated and a range plate formed therein, and a stove base panel coupled to the bottom of the stove cover case and having a working coil installed therein, and a working coil. A hi-hapco controller is provided to control a power supply to generate a high-frequency magnetic field. The hi-hapco controller includes a power control unit for supplying power, an oscillation control unit for adjusting a high-frequency magnetic field generated by the working coil, and control of the oscillation control unit. In accordance with the signal is characterized in that the output is provided so that the power supplied from the power control unit is supplied to the working coil.

Description

Induction range using high frequency induction heating technology {INDUCTION RANGE WITH HIGH FREQUENCY INDUCTION HEATING TECHNOLOGY}

The present invention relates to an induction stove, and more particularly, a working coil in which a high frequency induction magnetic field is generated under a plate on which a cooking container is placed, and thus a controller for power control, high frequency oscillation control, and the like. The present invention relates to a high frequency induction heating induction stove that is configured to have a cooling unit having a high cooling function on one side in order to prevent overheating inside the apparatus, thereby to operate stably and to minimize power consumption through a high efficiency cooling operation.

In general, the food is cooked through a number of processes, such as heating, seasoning, minced and boiled. In particular, the heating device of the cooking device is a variety of heating tools such as a microwave, a gas stove, an oven, a steamer, an electric rice cooker, a pot for boiling tea.

These heating tools have been used mainly in recent years because they are not only much more convenient but also cleaner than wood burning or oil burning.

In particular, income levels are getting higher, and cooking utensils, such as electricity, that do not burn, are getting more attention than burning. Electric ovens, microwave ovens, hot plate stoves, highlight stoves, etc. have been used in recent years.

In the case of gas stoves that are widely used, most of them are installed together with a sink, but they are convenient to cook, but not only automatic temperature control and cooking can be selected, but also because of direct sparks, there is a risk of fire due to carelessness. This is inconvenient.

Therefore, the device is gradually installed as a sink and can be used conveniently like a stove, and a device that can be used conveniently and safely while cooking, such as an electric oven, a microwave oven, or an electric rice cooker, is required. Plate and highlight ranges are used.

However, hot plate and highlight ranges are more convenient because they use electricity, but because the heating coil inside the device heats the plate on the place where the container is placed, it may take a long time to heat once. The heated plate has a problem that it is difficult to adjust the temperature of the food as desired when cooking, such as not easily cooled.

In addition, since the heated plate should not be cooled easily and at least several tens of minutes have elapsed, there is a risk of fire if the dishcloth, collar, food, or food wrapper falls on the cooked hot plate. There is considerable inconvenience.

In order to overcome this problem, a microwave oven is used to heat the induction current using some magnetic fields, but it is difficult to maintain the recommended level of the magnetic field, making it difficult to meet the standard, and the efficiency is low. When it is convenient to use, the problem of improvement such as excessive power consumption is considerable.

In order to solve the above problems, the present invention has a working coil under which a high frequency induction magnetic field is generated under a plate on which a cooking container is placed. Thus, a process of a controller of power control and high frequency oscillation control for generating a high frequency induction magnetic field and In order to prevent overheating inside the device by configuring a cooling unit having a high cooling function to one side, while operating stably, there is an object to minimize the power consumption by heating with high efficiency by cooling with high efficiency.

In other words, the control structure according to the high-performance cooling efficiency increases the heating effect by the high frequency induction magnetic field and the power consumption becomes low.

In addition, a frequency suitable for the shape and size of the vessel placed on the initial induction stove is generated, and even when the position of the vessel placed on the stove is changed, the frequency is appropriately operated to form a magnetic field according to the changed position. The purpose is to allow the induced magnetic field to be generated according to the situation and to facilitate the use.

In addition, because the power consumption is lower than the hot plate range, highlight range, etc., the plate on which the container is placed is not heated, but only the container is heated, so that the temperature of the device can be adjusted optimally according to the cooking conditions. In fact, it is not hot, which reduces the risk of fire or burns.

In order to achieve the above object, the present invention provides a stove cover case 12 having a working coil 30 in which a high frequency magnetic field is generated and a range plate 121 formed thereon, and the range cover case 12. It is provided with a stove base panel 14 coupled to the bottom of the) and the working coil 30 is installed, and a hi-hapco controller 20 for controlling the power supply to generate a high frequency magnetic field in the working coil 30, The hapco controller 20 includes a power control unit 21 for supplying electric power, an oscillation control unit 22 for adjusting a high frequency magnetic field generated by the working coil 30, and a control signal of the oscillation control unit 22. In accordance with the high-frequency induction heating induction stove is provided, characterized in that the output unit 23 is provided so that the power supplied from the power control unit 21 is supplied to the working coil (30).

Accordingly, a controller cooling unit 40 is disposed on one side of the stove cover case 12 and the stove base panel 14 and is made of a metal material, and the hepco controller 20 is coupled thereto. One side of the 40 is coupled to the power control unit 21 of the hepco controller 20, the other side is coupled to the oscillation control unit 22 and the output unit 23, the lower portion of the controller cooling unit 40 Cooling heat sink blades 41 are formed, and the cooling fan 42 coupled to the cooling through-hole 141 formed in the range base panel 14 is provided below the cooling heat sink blades 41 to be coupled. Can be.

In addition, the output unit 23 is provided with a resonant frequency generator 231 for generating a resonant frequency of a high frequency magnetic field generated by the working coil 30, and is connected to the resonant frequency generator 231 to generate a resonant frequency. It is provided with a frequency control unit 50 to automatically find, the frequency control unit 50, the control resonance coil 51 is connected in series with the resonant coil 232 of the resonant frequency generator 231 In addition, the control resonant coil winding unit 52 is wound around the resonant coil 51, the frequency control moving core 53 is moved in the longitudinal direction inside the control resonance coil 51, and the frequency control moving core ( The control motor 54 to move 53 in the longitudinal direction, and the control core feed shaft 55 is formed by the outer screw to be coupled to the inner screw of the frequency control moving core 53 while being rotated by the control motor 54 Is included and provided, the frequency control moving core 53 A guide groove 531 is formed on one side of the outer surface, and a guide feed protrusion 521 is formed inside the control resonance coil winding 52 to guide the guide groove 531 in a longitudinal direction, and thus, an adjustment motor ( Frequency-controlled moving core 53 received the rotational force by 54 is provided to be moved in the longitudinal direction inside the control resonance coil 51 by the guide groove 531 and the guide feed projection 521, the control resonance coil 51 may be provided to adjust the resonant frequency in accordance with the position of the frequency control moving core (53) inside.

And a motor control unit 56 for controlling the operation of the regulating motor 54 is provided, the sensing unit for transmitting a signal sensed for the current flowing to the output unit 23 to the motor control unit 56 (57) is provided, by adjusting the rotation of the control motor 54 through the motor control unit 56 in accordance with the change in the high frequency generated in the working coil 30 through the output unit 23, the control motor 54 The high frequency resonant frequency at the frequency adjusting unit 50 and the resonant frequency generating unit 231 through the control resonance coil 51 may be adjusted to rotate.

Furthermore, a coil frame 31 supporting the bottom of the working coil 30 is installed on the stove base panel 14, and the coil frame 31 has an outer rim 311 formed at an outer circumference thereof and has a sensor groove at the center thereof. A central rim portion 313 having a 312 formed thereon is formed, and a spinning coil stand 314 is formed in which a working coil 30 is positioned at an upper portion thereof while connecting the outer rim portion 311 and the central rim portion 313. A plurality of frame pillars 32 supporting the bottom of the outer rim 311 are installed, and a sensor cup 33 is provided to move up and down in the sensor groove 312 of the central rim 313. A heat sensor 34 is installed inside the cup 33, and a sensor part spring is formed between the sensor slide pillar 35 supporting the bottom of the sensor cup 33 and the slide bottom 331 of the bottom of the sensor cup 33. 36 is provided, the heat sensor data sensed by the heat sensor 34 is the oscillation control unit 22 of the hepco controller 20 Is transmitted may be provided to prevent overheating in the vicinity of the working coil 30 and the oven plate 121.

In addition, the present invention, the working coil 30 is a high frequency magnetic field is generated; A stove cover case 12 having a working coil 30 having a high frequency magnetic field installed therein and a range plate 121 formed thereon; A hihapco controller 20 for controlling a power supply to generate a high frequency magnetic field in the working coil 30; A resonance frequency generator 231 for generating a resonance frequency of the high frequency magnetic field generated by the working coil 30; It is connected to the resonant frequency generating unit 231 includes a frequency adjusting unit 50 to automatically find the resonant frequency, the frequency adjusting unit 50, the resonance coil of the resonant frequency generating unit 231 ( Regulating resonance coil 51 connected in series with 232; It provides a high frequency induction heating induction stove characterized in that it comprises a frequency-controlled moving core (53) which is moved in the longitudinal direction inside the control resonance coil (51).

According to the present invention configured as described above, a working coil in which a high frequency induction magnetic field is generated is placed under a plate on which a cooking container is placed. By configuring a cooling unit having a high cooling function to one side to prevent overheating, while having a stable operation, there is an excellent effect to minimize the power consumption by heating at a high efficiency by cooling with high efficiency.

That is, the heating effect by the high frequency induction magnetic field is increased and the power consumption is low due to the control configuration according to the high performance cooling efficiency.

In addition, a frequency suitable for the shape and size of the vessel placed on the initial induction stove is generated, and even when the position of the vessel placed on the stove is changed, the frequency is appropriately operated to form a magnetic field according to the changed position. There is an excellent advantage that the induced magnetic field is generated according to the situation, making it easy to use.

In addition, because the power consumption is lower than the hot plate range, highlight range, etc., the plate on which the container is placed is not heated, but only the container is heated, so that the temperature of the device can be adjusted optimally according to the cooking conditions. In fact, it is not hot and has the advantage of reducing the risk of fire or burns.

1 is a top perspective view of an induction stove according to the present invention.
2 is a plan view of an induction stove according to the present invention.
Figure 3 is a perspective view of the microwave oven cover case is open in the induction stove according to the present invention.
Figure 4 is a perspective view of the separation of the inner member in the induction stove open state in the induction stove according to the present invention.
5 is a plan view of the inner members of the induction stove according to the present invention.
Figure 6 is a side cross-sectional view of the induction stove according to the present invention.
Figure 7 is a perspective view of the separated state for the heapco controller and the controller cooling unit in the induction stove according to the present invention.
8 is a plan view of the power control unit of the induction stove according to the present invention.
9 is a front view of the power control unit of the induction stove according to the present invention.
10 is a plan view of the oscillation control unit and the output unit of the hi-hapco controller of the induction stove according to the present invention.
11 is a front view of the oscillation control unit and the output unit of the hi-hapco controller of the induction stove according to the present invention.
12 is an exemplary cross-sectional view of the controller cooling unit in the induction stove according to the present invention.
13 is an exploded perspective view of the controller cooling unit and the cooling fan of the induction stove according to the present invention.
14 is an exemplary cross-sectional view of the controller cooling unit and the cooling fan of the induction stove according to the present invention.
15 is a control block diagram of an induction stove according to the present invention.
16 is a block diagram of an output unit and a frequency control unit in the induction stove according to the present invention.
17 is a perspective view of the frequency control unit of the induction stove according to the present invention.
18 is an exploded perspective view of the frequency control unit of the induction stove according to the present invention.
Figure 19 is a side cross-sectional view of the frequency control unit of the induction stove according to the present invention.
20 is an exemplary view of the motor control unit of the frequency control unit in the induction stove according to the present invention.
21 is an exploded perspective view of the working coil and the coil frame in the induction stove according to the present invention.
22 is a plan view of the working coil and the coil frame in the induction stove according to the present invention.
Figure 23 is a side cross-sectional view of the working coil and coil frame in the induction stove according to the present invention.
24 is a plan view of a three-spherical shape provided with three working coils in the induction stove according to the present invention.
25 is a plan view of an internal configuration of a three-spherical shape provided with three working coils in an induction stove according to the present invention.
26 is a schematic side view illustrating a three-spherical shape provided with three working coils in an induction stove according to the present invention.

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

That is, the induction stove 10 using the high-frequency induction heating technology according to the present invention, as shown in Figures 1 to 26, the induction heating vessel (not shown) to the upper portion of the stove cover case 12 in the shape of the enclosure The induction magnetic field is generated at the working coil 30 inside the induction range, and the high frequency induction magnetic field is generated to heat the induction heating vessel (not shown) in the induction magnetic field region. As a result, the food ingredients contained in the induction heating vessel are cooked and cooked.

1 to 6 illustrate an exemplary diagram of a single-shaped induction stove capable of heating one container by using a single working coil, and a plurality of working coils are illustrated in FIGS. As shown in the illustration of the three-spherical induction stove provided to heat the container, it may be used as a single single-shaped induction stove by the induction stove 10 according to the present invention, such as two or three The induction stove may be provided as a multi-ball type.

In the present invention, by effectively generating a high frequency in particular, the harmful electromagnetic waves are generated so that the user is safe. And in order to effectively reduce the heat generated during high frequency generation, the controller cooling unit for cooling is formed relatively large near the Hipco controller, and prevents overheating of the Hipco controller, which is a control structure by other heat sink blades and cooling fans. .

In addition, due to the positional relationship with the working coil in which the induction magnetic field is generated according to the state in which the container is located, the generated frequency should be changed, and an automatic adjusting device is added to automatically adjust the frequency and the intensity of the output. The optimum heating situation can be made to increase the efficiency.

Looking at an embodiment of a specific configuration of the present invention for this feature is as follows.

First of all, in the case of the enclosure shape, a working coil 30 having a high frequency magnetic field is installed therein and a range of a range between the range of the range and the bottom of the range of the range, It is coupled to the stove base panel 14 is provided with a walking coil 30 is provided.

Therefore, the overall stable form can be achieved.

However, as shown in the example of the accompanying drawings, a single enclosure shape, and also the configuration consisting of a single working coil therein only shows an embodiment for the description of the present invention. And when the configuration of the present invention, such as the configuration of the case-shaped case of a monotonous basic form, the configuration of a single hihapco controller, the single working coil, etc. are provided in plural, it is like a two-hole gas stove, a three-hole It may be composed of a plurality of induction stoves that can use several vessels at the same time, such as a gas stove.

As shown in the example of the plurality of configurations and drawings, the selection for a single configuration, etc. may be appropriately selected and provided according to the harmony of the kitchen or sink installed, or the shape desired by the user. Of course, the power control unit to supply power in the present invention, but may be an example that the external general power is supplied, but is not limited thereto, the power is supplied from a moving means, such as automotive power, fuel cells, high capacity storage battery If the embodiment can be supplied with power from the back, it may also be carried out for outdoor use or outdoor use. Of course, if there is a general electricity supply in the vicinity, it will be obvious that the general power can be used and can be easily carried.

As described above, the upper cover cover case 12 and the lower range base panel 14 are formed in a housing shape, and the electronic control members including the walking coil are provided together.

In addition, the range control panel 15 may be provided on one side of the range cover case 12 of the upper portion so that each control configuration for generating a high frequency induction magnetic field can be operated by the user's operation. In the accompanying drawings, since the induction range of the small size includes a single working coil and the stove plate 121 in which the container is positioned, the range control panel 15 is disposed at the edge of one side of the stove plate 121. Although the position is taken as an example, a plurality of spheres medium or large, if the installation is high enough to allow other users to stand, it may be installed to suit the side or front of the range cover case 12, and the like.

In addition, the range control panel 15 may be provided with an on / off switch (ON / OFF SWITCH) to operate or stop the induction stove 10, or may be provided with an operation lamp to determine whether the operation. Could be

In addition, the temperature display unit (not shown) that can be displayed in the vicinity of the cooking coil or the range of the cooking plate 121 for the induction stove (10) to operate, a temperature switch (not shown) that can increase or decrease the temperature Operation, such as a temperature setting display unit (not shown) that displays the set temperature, and the like is provided and implemented to facilitate the use, and such an operation switch or display unit may be a function or specification. , Or may be appropriately determined according to the degree of preference.

In the induction stove 10 according to the present invention, the food contained in the induction heating vessel of the upper side may be cooked only when the high frequency induction magnetic field is generated in the working coil 30. Thus, the induction stove 10 according to the present invention may be used. As a control configuration for the operation of the induction range, a hi-hapco controller 20 for controlling a power supply to generate a high frequency magnetic field in the working coil 30 is provided.

The hihapco controller 20 is a configuration for controlling power supply and high frequency generation, and in particular, high heat due to the power supply and high frequency generation operation. This can be generated, the main feature is that the configuration for effective cooling is formed integrally.

Looking at the configuration of the hi-hapco controller 20 for this purpose, the power control unit 21 for supplying power and the oscillation control unit 22 for adjusting the high frequency magnetic field generated by the working coil 30 is provided.

In addition, an output unit 23 for supplying power supplied from the power control unit 21 to the working coil 30 according to the control signal of the oscillation control unit 22 is provided.

As described above, the induction stove 10 has a working coil 30 in which a high frequency induction magnetic field is generated at the center thereof, and a hepco controller 20 is positioned at one side thereof. 21), the oscillation control unit 22 and the output unit 23 to which the high frequency power signal is supplied to the working coil 30 is configured.

The oscillation control unit 22 and the range control panel 15 installed in the range cover case 12 is connected, the signal manipulated by the user through the range control panel 15 is transmitted to the oscillation control unit 22 It will be processed according to the signal being transmitted.

For example, the operation of the induction stove 10 (ON / OFF), the display of the set temperature, including the rise and fall of the temperature, the actual temperature display in the vicinity of the working coil 30, and, if necessary, the magnetic field or abnormal conditions The operation on the display and the like will be handled by the range control panel 15 and the oscillation control unit 22 and the like.

In addition, such an oscillation control unit 22, a power control unit, an output unit, etc. may be implemented with a basic component or a circuit configuration for the operation of the stove using a generally known magnetic field. In addition to the basic configuration, in the present invention, as described later, the characteristic configuration that can be achieved by the hihapco controller 20 is further added.

In particular, in the power control unit 21, a high-performance bridge circuit and related components may be further used for efficiency of power control. In addition, the oscillation control unit 22 may include a member for high frequency oscillation, a member for automatic temperature control, a member for operating at a stable temperature, a member for stopping operation or notification of an abnormal temperature at an abnormal temperature, and the like. The term members described above or hereinafter means that electronic components, electronic circuits, a plurality of components, operation programs applied to control components, and the like, which are applied to a circuit, may be made in a single or a combination, and may be made for any operation. Modules, engines, blocks, etc. for physical (circuit or electronic components) or programs (control programs, operation programs of specific components, etc.) may be followed.

In addition, the output unit 23 is connected to the working coil 30 to generate a high frequency induction magnetic field, and thus various components such as a member for resonance, a member for high frequency oscillation, a member for adjusting high frequency or frequency, etc. In particular, a pulse width modulator (PWM) may be applied to the resonant module, and a more stable and efficient resonant frequency may be generated by the configuration of the resonant module by the pulse width modulator. There will be.

In addition, the voltage amplification and high frequency characteristics are improved by the configuration of a FET (developing effect transistor) connected to the pulse width adjusting unit PWM.

In particular, the high-frequency induction magnetic field generated by the working coil connected thereto by the resonant frequency generator connected to the pulse width adjusting unit (PWM) and the FET is generally 250 kHz (125 kHz x 2 per unit), thereby reducing the conventional low efficiency frequency ( It can be performed with the high frequency efficiency superior to the conventional approximately 20kHz). It is generated at 25mG (milli Gauss) generated from the stove base panel by the high frequency efficiency, and it is a measured value when it is about 10cm away from the safety base of the stove base panel. Since mG degree comes out, it can be seen that the efficiency is superior to that of the prior art.

In addition, the controller cooling unit 40 may be provided to cool the heat generated during the operation of the hihapco controller 20.

That is, the controller is provided with a controller cooling part 40 which is positioned to one side of the inside of the stove cover case 12 and the stove base panel 14 and is made of a metal and is coupled to the hepco controller 20.

One side of the controller cooling unit 40 is coupled to the power control unit 21 of the Hipco controller 20, the other side is coupled to the oscillation control unit 22 and the output unit 23, the controller cooling unit ( 40) is generally made of a material having a rectangular planar shape and excellent in thermal conductivity and cooling efficiency. As shown in the accompanying drawings, the oscillation control unit 22, the output unit 23, the power control unit 21, and the like, respectively, are divided into both sides of the controller cooling unit 40 forming a rectangle. By being coupled, the cooling efficiency in each member is provided to be excellent. Thus, the control performance of the hepco controller 20 is excellent.

In addition, a large number of cooling heat sink blades 41 are formed at the bottom of the controller cooling unit 40 to form a large area in the wing-shaped heat sink by the wind passing, and thus the cooling contact surface is wide, so that heat exchange characteristics through a large area are achieved. To be superior.

In addition, a cooling fan 42 coupled to a cooling through hole 141 formed in the range base panel 14 is provided below the cooling heat sink wing 41.

The cooling fan 42 includes a cooling heat sink blade 41, a controller cooling unit 40, a power control unit 21, an oscillation control unit 22, and an output unit (Hipco controller 20) coupled thereto. 23), in addition to the heat inside the induction stove 10, including the working coil 30 to be discharged to the outside, the operation of the induction stove 10 is to be smooth.

As described above, in the apparatus of the induction stove 10 according to the present invention, the heat inside the apparatus is discharged to the outside by the cooling fan 42 so that the apparatus is stably operated without overheating and cooling for cooling as a whole. During operation of the fan 42, the cooling air near the cooling fan 42 having a large degree of flow of cooling air moves at a high speed in the vicinity of the controller cooling unit 40 and other members of the hepco controller 20. Therefore, the cooling efficiency is provided to be improved. In particular, the control cooling unit 40 with the plurality of wing-shaped cooling heat sink vanes 41 facing in the direction of the cooling fan 42 is provided to improve the thermal conductivity in the shape of a metal plate to be forced by the cooling fan 42. Due to the flowing cooling air, the control cooling unit 40, particularly, the cooling air flows between the plurality of wings of the cooling heat sink wing 41, the control cooling unit 40 is good cooling characteristics. At both ends of the control cooling unit 40, the power control unit 21, the oscillation control unit 22, the output unit 23, and the like of the hepco controller 20 are respectively coupled, and the efficiency thereof may be reduced due to high heat. It is to be provided to improve the efficiency by cooling the respective members of the hepco controller 20.

Thus, the configuration of the control cooling unit 40 is provided so that the members of the hepco controller 20 and other devices with improved cooling efficiency can operate stably without overheating. In order to increase the cooling characteristic efficiency of the control cooling unit 40, the heat transfer efficiency and the heat dissipation efficiency are made of a cooling metal material, and the control cooling unit 40 has a plurality of blade-shaped cooling in the downward direction. The heat sink blade 41 is formed in the shape of a plurality of wings in the downward direction, and is provided so that the heat dissipation effect with the cooling air flowing by the cooling fan 42 below is substantial. In addition, the multiple wings of such cooling heatsink blades 41 are generally shortened downwardly in the center where the cooling fan 42 is located, as shown in the accompanying drawings, while the wings at the edges are formed relatively long, so that the device Air located at many places in the interior also flows smoothly into the space formed by the shortening of the plurality of wings near the cooling fan 42, thereby improving the cooling effect. On the other hand, the edges of the cooling heatsink blades are relatively long, thereby widening the cooling contact area with the flowing air, thereby improving the cooling efficiency by the heatsink. Therefore, the cooling effect is further improved by the arcuate shape of the wings of the cooling heat sink wing 41 having a plurality of wings to form an arc of the arc downward and the operation of the cooling fan 42.

Next, in order to generate a high frequency in the high frequency induction heating induction stove 10 according to the present invention, a member for generating a resonant frequency operation is provided. May be generated.

Looking at the members for this purpose, the output unit 23 is provided with a resonant frequency generator 231 to generate a resonant frequency of a high frequency magnetic field generated by the working coil 30, the resonant frequency generator 231 and Is connected is provided with a frequency control unit 50 to automatically find the resonant frequency.

In general, in the generation of the resonance frequency, when the reference to the working coil 30, the resonance frequency is generated by the combination of the inductor and the capacitor. In order to achieve the action of the induction magnetic field, the generation of induction current with the food cooking container in the upper through the working coil 30, a resonance frequency appropriate to the situation should be generated. That is, in order to operate the working coil 30 and the induction magnetic field, the induction current, etc., the high frequency of the magnetic field must be properly adjusted between the working coil and the container. And to this end, in the present invention, the frequency control unit 50 is provided together, such that the frequency control unit 50 is to be connected to the inductor, the capacitor for the resonant frequency generation.

For example, in the embodiment of the present invention and the accompanying drawings, the resonant frequency is automatically adjusted by connecting to an inductor so that a separate frequency adjusting coil is connected, and other applications of other members of the present invention are applied. In the invention made by the present invention, even if the resonance frequency adjustment members presented in the present invention is applied by analogy, it is natural that these technical ideas are related to the present invention and thus belong to the scope and spirit of the present invention.

Looking at one embodiment by the configuration of the output unit, the resonant frequency generator, the frequency control unit and the like is provided as follows may be operated as follows. Of course, other members of the other output unit, resonant frequency generator or other members of the frequency control unit may be implemented with some modification. In addition, when the resonant frequency generating unit is an inductor and a capacitor, the embodiment of the present invention is connected to the inductor to provide a frequency adjusting unit as an example. However, the frequency adjusting of the present invention is performed in another example other than the inductor. Additional applications may be implemented and operated in combination.

In the present invention, since the high-frequency induction magnetic field should be generated, the inductor and the capacitor are relatively large in the resonance frequency generator 231 of the output unit 23. However, the present invention is not limited thereto. In this case, the size and shape may be somewhat smaller, and thus may be implemented in a molding form, a PCB (printed circuit board) embedded type, or a component welded to the PCB.

When explaining the embodiment of the inductor having a relatively large size, the output unit 23, the resonant frequency generating unit or the frequency adjusting unit 50 may be provided as shown in the accompanying drawings, in particular the frequency adjusting unit 50 May be provided as an accompanying drawing and as described below.

That is, the frequency control unit 50, the control resonance coil 51 and the control resonance coil which is connected in series with the resonance coil 232 of the resonance frequency generator 231, as shown in FIGS. The regulating resonant coil winding portion 52 in which the 51 is wound may be provided.

In addition, the control resonance coil 51 is provided with a frequency control moving core 53 which moves in the longitudinal direction, so that the frequency control moving core 53 resonates while moving in the control resonance core 51 in the longitudinal direction. The frequency is found and thus the induction magnetic field is formed according to the resonant frequency in the working coil.

In order to move the frequency regulating moving core 53, the regulating motor 54 operated by the control signal of the motor control unit 56 is provided, and the frequency regulating moving core 53 is provided by the regulating motor 54. ) Is moved in the longitudinal direction.

In addition, it is provided with an adjustment core feed shaft 55 is formed by the outer screw to be coupled to the inner screw of the frequency control moving core 53 while being rotated by the control motor 54.

In particular, the guide groove 531 is formed on one side outer surface of the frequency control moving core 53, the guide groove 531 is guided in the longitudinal direction inside the control resonance coil winding 52 521 is formed, the frequency control moving core 53 received the rotational force by the adjustment motor 54 is closed in the control resonance coil 51 by the guide groove 531 and the guide feed projection 521. It is provided to move in the direction, the resonance frequency is provided to adjust the resonant frequency in accordance with the position of the frequency control moving core (53) inside the control resonance coil (51).

Looking at the operation by the frequency control unit 50 and the corresponding accessory members are provided as follows.

Basically, the container is positioned above the stove plate 121, but the container may be an example of forming a circular bottom while keeping the center of the working coil 30 and the center of the container in an optimal state.

In this case, when the operation of the induction stove 10 of the present invention, the motor control unit 56 received the start signal from the oscillation control unit 22 operates the control motor 54 to operate the frequency control moving core 53. ) Is made to move.

Prior to this, the adjustable frequency moving core 53 may be implemented as a default position that is off to one side edge of the control resonance coil 51 forming a circular tunnel as an initial basic position.

And a motor control unit 56 for controlling the operation of the regulating motor 54 is provided, the sensing unit for transmitting a signal sensed for the current flowing to the output unit 23 to the motor control unit 56 57 is provided.

Thus, by adjusting the rotation of the control motor 54 through the motor control unit 56 in accordance with the change of the high frequency generated in the working coil 30 through the output unit 23, the control resonance by the rotation of the control motor 54 It may be implemented so that the intensity of the high frequency induction magnetic field according to the frequency adjusting unit 50 and the resonant frequency generating unit 231 through the coil 51 is adjusted.

That is, in the exploded perspective view of FIG. 18, the frequency control moving core 53 is positioned close to the middle plate 522 in the center. Since most of the winding control resonance coil 51 is wound on the opposite side of the intermediate plate 522 in the control resonance coil winding portion 52 of the cylindrical shape, the control resonance coil 51 and the frequency control moving core 53 will be in a non-overlapping state.

Accordingly, when the adjustment motor 54 is rotated according to the start signal of operation, the rotational force will rotate the adjustment core feed shaft 55 formed at one side of the shaft coupler 551 coupled to the motor coupler 541.

Along with this, the core fixing plate 532 is coupled to both sides of the frequency adjusting moving core 53, and a thread is formed inside the two or one core fixing plate 532, and the screw thread and the screw coupling of the adjusting core feed shaft 55 are coupled thereto. Will be. In addition, the guide groove 531 is formed to protrude to the outside of the side or one side of the core fixing plate 532, the guide groove 531 is positioned outside the frequency control moving core 53, the control resonance coil winding winding The portion 52 is to move along the guide feed projection 521 which is a groove formed in the longitudinal direction on the inner surface.

Therefore, with the rotation of the control core feed shaft 55 received the rotational force of the control motor 54, the control core feed shaft 55 and the core fixing plate 532 is screwed, the core fixing plate 532 is not rotated in the longitudinal direction However, by the guide groove 531 moving along the guide transporting projection 521 is to be conveyed in the longitudinal direction from the inside of the resonant resonance coil winding 52.

Of course, since the frequency adjustment moving core 53 is coupled between the core fixing plate 532 on both sides, since the core fixing plate 532 is transferred in the longitudinal direction inside the control resonance coil winding 52, the frequency control moving core 53 will also be conveyed in the longitudinal direction from within the control resonant coil winding 52.

In addition, since one side of the adjusting resonance coil winding unit 52 is wound around the adjusting resonance coil 51, the frequency of the adjusting resonance coil 51 when viewed from the center of the adjusting resonance coil 51 is eventually increased. The adjusting movable core 53 moves in the longitudinal direction. In this way, the resonant frequency is changed according to the overlapping frequency of the adjustable frequency moving core 53 with the regulating resonance coil 51, and thus, the frequency to which the induction magnetic field is stably generated is found. Of course, other frequency sensing techniques, and techniques for controlling the regulating motor 54 may be determined by techniques appropriate to the situation, and an example thereof may be referred to by FIGS. 15 and 16. In addition, the frequency detection and control technique may be operated by applying a technique that uses null in the field of electric and electronic communication as well as the present invention. Accordingly, structural and functional features of the present invention are added to find and operate a better resonance frequency. Is one of the main feature configurations.

Next, as shown in FIGS. 3 to 6, 21 to 23, and the like, the coil frame 31 supporting the bottom of the working coil 30 is installed in the range base panel 14. The coil frame 31 has an outer rim 311 and a ring rim formed on an outer circumference thereof, and a central rim 313 having a sensor groove 312 formed at the center thereof is formed, and the outer rim 311. And radial coil supporter 314 on which the working coil 30 is located may be formed while continuing the central rim portion 313. And a plurality of frame pillars (32, pillars) supporting the bottom of the outer rim 311 is provided, while fixing the entire working coil 30 and the coil frame 31, etc. to the range base panel 14, The installed members can be positioned stably.

As described above, the coil frame 31 in which the working coil 30 is positioned may be formed in a plate shape, such as a disc shape, a square plate shape, another polygonal plate shape, an oval plate shape, and the like according to the accompanying drawings. Also, if necessary, it may be made of a circular coil, a rectangular coil, a polygonal coil, an elliptic coil, and the like, which are shaped like a coil frame.

In addition, as shown in the present invention, the coil frame 31 may be implemented in the form of a circular frame, or may be made of various types of frame types such as other rectangular frame types, polygonal frame types, oval frame types, and walking accordingly. Coils may also be formed in various forms such as round, square, polygonal, oval.

Furthermore, even in the case of an induction heating vessel (not shown) in which an induction current is generated and heated by the induction magnetic field of the working coil, the bottom surface or the planar shape may have various shapes such as a circle, an oval, a rectangle, and a polygon. The working coil, coil frame, or container may be determined and implemented according to the installation situation.

In particular, as shown in the accompanying drawings and the description in the present invention, the shape of the coil frame 31 on which the working coil 30 is seated, the outer rim 311, the sensor groove 312, the central rim 313, And by the spinning coil band 314, etc., the installation structure is simple, less material is consumed and may be manufactured lightly. Furthermore, not only the inside or the bottom of the working coil 30 can be easily visually checked, but also the frame pillar 32 and the working coil 30, which are members that allow the working coil 30 to be fixed to the stove base panel 14. By forming the frame type of the outer rim portion 311, the central rim portion 313, the spinning coil band 314, etc. of the coil frame 31 for supporting, it can be configured to form a lot of space between the respective structural members. will be. Therefore, the heat that can be generated by the operation of the working coil 30 or other members through the many empty spaces between each structural member is discharged to the natural radiation, and does not have latent heat as much as the empty space of the frame type, Overall, many overheating factors can be ruled out.

In addition, since the air can flow freely through the empty space due to the frame type, the heated part is easily cooled while the internal air is flowing by the operation of the cooling fan to prevent overheating as a whole.

As described above, the members such as the working coil 30 and the coil frame 31 and the frame pillar 32 of the induction stove 10 according to the present invention have an excellent shape for preventing overheating, thereby allowing to operate stably. There is an excellent advantage.

In addition, a sensor cup 33 is provided to move up and down in the sensor groove 312 of the central rim 313, and a heat sensor 34 is installed inside the sensor cup 33.

In particular, in the structure of the sensor cup 33 and the heat sensor 34, as shown in the example cross-sectional view of Figure 23, the sensor cup 33 has a cup shape with a border to the upper edge, and below the inner center Since the heat sensor 34 is positioned, it is installed so as to sense the temperature of the ambient air of the heat sensor 34 in a state where the upper range plate 121 and the heat sensor 34 do not directly contact, The temperature near the actual working coil 30, and whether the stove cover case, the stove plate, or the like may be overheated.

In addition, a sensor part spring 36 is provided between the sensor slide pillar 35 supporting the bottom of the sensor cup 33 and the slide bottom 331 of the bottom of the sensor cup 33, and is detected by the heat sensor 34. The heat sensor data is transmitted to the oscillation control unit 22 of the hepco controller 20 to prevent overheating in the vicinity of the working coil 30 and the range plate 121.

In particular, the sensor unit spring (36) is provided between the upper sensor cup (33) on which the heat sensor is installed, and the sensor slide column (35) fixed to the lower range base panel (14). 36, the upper edge of the edge of the sensor cup 33 is in contact with the range base panel 14. Thus, the temperature of the induction heating vessel (not shown) in which the heat sensor 34 configured in the sensor cup 33 is actually heated is to sense the nearest position.

This is prevented if the container is heated to a high temperature, not only the container but also the stove base panel 14 and the working coil 30 and other members therein may cause overheating, which may result in malfunction, failure or damage. It is to. That is, when the container is too overheated by sensing the temperature close to the container, an operation to prevent overheating may be achieved.

In addition, if the actual temperature is measured in close proximity to the container may be adjusted according to the cooking method accordingly.

In other words, when cooking food at a high temperature, it must be heated to high temperature, such as when moxibustion to achieve a medium temperature when the middle temperature, and if the other simple warming is not so high temperature It should be able to heat to maintain. Therefore, by directly measuring whether it is a high temperature state, a medium temperature state or not a high state, and transmits the temperature sensor value to the hyhapco controller side, it is possible to meet the optimum cooking conditions according to the temperature according to the cooking situation.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The technical idea of the present invention should not be construed as being limited.

10: Induction Range 12 Range Cover Case
14 Range Range Panel 15 Range Control Panel
20: hihapco controller 21: power control unit
22: oscillation controller 23: output unit
30: working coil 31: coil frame
32: frame pillar 33: sensor cup
34: thermal sensor 35: sensor slide pillar
36: sensor part spring 40: controller cooling part
41: cooling heat sink wing 42: cooling fan
50: frequency control unit 51: control resonance coil
52: control resonance coil winding 53: frequency control moving core
54: control motor 55: control core feed shaft
56: motor control unit 57: sensing unit
121: range plate
231: resonant frequency generator 232: resonant coil
311: outer rim 312: sensor groove
313: central forest part 314: spinning coil
331: lower slide
521: guide transfer projection 522: the middle plate
531: guide groove 541: motor coupler
551: Shaft Coupler

Claims (5)

A working coil 30 in which a high frequency magnetic field is generated;
A stove cover case 12 having a working coil 30 having a high frequency magnetic field installed therein and a range plate 121 formed thereon;
A hihapco controller 20 for controlling a power supply to generate a high frequency magnetic field in the working coil 30;
A resonance frequency generator 231 for generating a resonance frequency of the high frequency magnetic field generated by the working coil 30;
A frequency adjuster 50 connected to the resonance frequency generator 231 to automatically find the resonance frequency;
Lt; / RTI >
The frequency control unit 50 is:
A control resonance coil 51 connected in series with the resonance coil 232 of the resonance frequency generator 231;
A frequency regulating moving core 53 which is moved longitudinally in the regulating resonance coil 51;
High frequency induction heating induction stove comprising a.
The method of claim 1,
The hepco controller 20,
A power control unit 21 for supplying power;
An oscillation control part 22 for adjusting a high frequency magnetic field generated by the working coil 30;
An output unit 23 for supplying the power supplied from the power control unit 21 to the working coil 30 according to the control signal of the oscillation control unit 22;
Lt; / RTI >
A controller cooling unit 40 is disposed on one side of the stove cover panel 12 and the bottom of the stove base panel 14 and is made of a metal material, and the hepco controller 20 is coupled thereto.
One side of the controller cooling unit 40 is coupled to the power control unit 21 of the hepco controller 20, the other side is coupled to the oscillation control unit 22 and the output unit 23,
A plurality of cooling heat sink vanes 41 are formed at the bottom of the controller cooling unit 40,
High-frequency induction heating induction stove, characterized in that provided below the cooling heat sink wing 41 is coupled to the cooling fan 42 coupled to the cooling through-hole 141 formed in the stove base panel (14).
The method of claim 1,
The hepco controller 20,
A power control unit 21 for supplying power;
An oscillation control part 22 for adjusting a high frequency magnetic field generated by the working coil 30; And
An output unit 23 for supplying the power supplied from the power control unit 21 to the working coil 30 according to the control signal of the oscillation control unit 22;
Lt; / RTI >
The frequency control unit 50 is:
An adjusting resonance coil winding unit 52 in which the adjusting resonance coil 51 is wound;
An adjusting motor 54 for moving the frequency adjusting moving core 53 in a longitudinal direction; And
An adjustment core feed shaft 55 which is rotated by the adjustment motor 54 and has an outer thread formed so as to be coupled to an inner thread of the frequency adjusting moving core 53;
/ RTI >
Guide grooves 531 are formed at one outer surface of the frequency control moving core 53, and guide guide protrusions guiding the guide grooves 531 in the longitudinal direction in the control resonance coil winding unit 52. 521 is formed, the frequency control moving core 53 received the rotational force by the adjustment motor 54 is longitudinally inside the control resonance coil 51 by the guide groove 531 and the guide feed projection 521. Is equipped to move to,
The resonance frequency is provided to adjust the resonant frequency according to the position of the frequency control moving core (53) inside the resonator coil (51),
The motor control unit 56 for controlling the operation of the regulating motor 54 is provided,
The sensing unit 57 is provided to transmit a signal sensed for the current flowing to the output unit 23 to the motor control unit 56,
In accordance with the change of the high frequency generated in the working coil 30 through the output unit 23, by adjusting the rotation of the control motor 54 through the motor control unit 56, the control resonance coil by the rotation of the control motor 54 High-frequency induction heating induction stove, characterized in that the high-frequency resonant frequency in the frequency control unit 50 and the resonant frequency generator 231 through (51) is provided to be adjusted.
delete The method of claim 1,
The coil frame 31 supporting the bottom of the working coil 30 is installed in the range base panel 14,
The coil frame 31 has an outer rim 311 formed at an outer circumference thereof, and a central rim 313 having a sensor groove 312 formed at the center thereof, and forming the outer rim 311 and the central rim 313. While continuing to form a spinning coil band 314 in which the working coil 30 is located,
A plurality of frame pillars 32 supporting the bottom of the outer rim 311 is provided,
The sensor cup 33 is provided to be movable up and down in the sensor groove 312 of the central rim 313,
The thermal sensor 34 is installed inside the sensor cup 33,
A sensor part spring 36 is provided between the sensor slide pillar 35 supporting the bottom of the sensor cup 33 and the slide bottom 331 of the bottom of the sensor cup 33.
The heat sensor data sensed by the heat sensor 34 is transmitted to the oscillation control unit 22 of the hepco controller 20 to prevent overheating in the vicinity of the working coil 30 and the range plate 121. High frequency induction heating induction stove characterized in that.

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