KR101052168B1 - Fan drive circuit of electric cooker and electric cooker - Google Patents

Abstract

The present invention relates to an electric cooker and a fan driving circuit of the electric cooker.

An electric cooker according to an embodiment of the present invention includes a fan operated in a plurality of driving modes and a fan driving circuit for driving the fan according to a heating operation of a heating source, wherein the fan driving circuit is separate from a power supply unit. It includes a first and second drive control unit connected. Accordingly, the present invention provides an electric cooker in which a driving mode of a fan is variously set according to a heating operation, and a cooling effect occurs even when one of the driving control units is burned out.

Electric cooker, pan

Description

Electric cooker and fan operating circuit of the electric cooker

The present invention relates to a cooking appliance, and more particularly, to an electric cooking apparatus for cooking food using electricity and a fan driving circuit of the electric cooker.

An electric cooker is a cooker that heats food using an induction heating heater or an electric resistance heater. The electric cooker includes a heating source for heating operation, a power supply unit for supplying power to the heating source, and a heating source driving unit for controlling the heating operation of the heating source.

SUMMARY OF THE INVENTION An object of the present invention is to propose an electric cooker and a fan driving circuit in which the heating source driving unit is prevented from being damaged by overheating according to the driving operation in the process of controlling the heating operation of the heating source. Is in.

Electric cooking apparatus according to the present invention for achieving the above object, the power supply; A heating source heated by receiving power from the power supply unit; A heating source driver for controlling power supply to the heating source and driving output of the heating source; A fan motor for rotating the fan for cooling the heating source driver; And a fan driving circuit for driving the fan motor, wherein the fan driving circuit comprises: a microcomputer for outputting a driving signal of the fan motor according to an operation state of the heating source driver; A first connection connected to the power supply unit and selectively supplying power supplied from the power supply unit to the fan motor according to the driving signal to apply power to the fan motor so that the fan motor is driven in a first driving mode; A first driving controller including a switching element; It is connected to the power supply unit independently from the first driving control unit, and selectively supplies power supplied from the power supply unit to the fan motor to supply power to the fan motor so that the fan motor is driven in the second driving mode. A second driving controller including a second switching element to be applied; The fan driving circuit may include a voltage drop unit configured to supply the fan motor in a state in which the voltage of the power supplied from the first driving controller is dropped. Wherein the power applied by the first switching element is dropped by the voltage drop unit to be supplied to the fan motor or the power applied by the second switching element is supplied to the fan motor, thereby providing the fan motor. The speed of is adjusted.

According to another aspect of the present invention, a fan motor driving circuit of an electric cooker includes a fan motor for rotating a fan for cooling a heating source driver; A microcomputer outputting a driving signal for the fan motor according to an operating state of the heating source driver; First and second switching elements, one end of which is connected to a power supply and supplied with power, and turned on / off according to the input driving signal; And a voltage drop unit having one end connected to the other end of the first switching element to drop the voltage of the current supplied from the other end of the first switching element, wherein the fan motor includes the other end of the second switching element. And the first switching element is turned on or the first and second switching elements are turned on, and power of different voltages is applied to the fan motor, thereby being driven in a plurality of driving modes.

According to the fan driving circuit of the electric cooker and the electric cooker according to an embodiment of the present invention, the fan motor for driving the fan is operated in a plurality of driving modes according to the operating state of the heating source driver. Therefore, there is an advantage that the cooling efficiency is increased, and noise that may be generated by excessively cooling the heat source driving unit in a low heat generation state is reduced.

In addition, since the first driving control unit and the second driving control unit are separately connected to the power supply unit, even if any one of the first and second driving control units is damaged, the operation of the other driving control unit is not affected. There is an advantage that can be cooled stably the heating source drive unit.

Hereinafter, with reference to the accompanying drawings, an embodiment of an electric cooker and a fan driving circuit of an electric cooker according to the present invention will be described in more detail.

1 is a perspective view showing the disassembled top plate in the electric cooker according to an embodiment of the present invention.

Referring to FIG. 1, referring to FIG. 1, an electric cooker 1 according to an embodiment of the present invention includes a casing 10 that forms a lower surface and an edge, a top plate 20 that forms an upper surface, and the A heating source 30 provided in the casing 10, a heating source driver 40 for controlling a heating operation of the heating source 30, and the heating source driver in an operation process of the heating source driver 40. A fan 50 for cooling the 40.

The casing 10 is formed of a flat hexahedron having an upper surface opened, and the casing 10 has a space in which the heating source 30 and the heating source driver 40 may be provided.

The top plate 20 forms an upper surface of the electric hob 10 by shielding the opened upper surface of the casing 10. In addition, a cook zone 21 in which a cooking vessel is seated and heated is formed at a position of the top plate 20 corresponding to the heating source 30, and receives an operation signal from the outside, thereby to the inside of the electric cooking appliance 1. A control panel (not shown) for transmitting the operation signal to the control unit provided in the is formed.

The heating source 30, through the cook zone 21, heats the cooking vessel to cook food contained in the cooking vessel. The heating source 30 may be, for example, a radiant heater.

The heating source driver 40 controls the power supply to the heating source 30 and the driving output of the heating source 30. The heating source driver 40 may be, for example, a triode AC switch (TRIAC or less triac), and the heating source driver 40 may perform control on the heating source 30. In the process, the internal resistance is raised by the internal resistance. When the temperature of the heating source driving unit 40 increases, the efficiency of the heating source driving unit 40 may decrease, and when the temperature rises excessively, the heating source driving unit 40 may be damaged by heat. Can be.

The fan 50 cools the heating source driver 40 according to the operating state of the heating source driver 40. In more detail, the fan 50 rotates in a number of stages according to the operating state of the heating source driver 40. When the heating source driver 40 controls the heating source 30 to be driven at a high output, a large amount of power is supplied to the heating source driver 40, so that the heating source driver 40 has its own resistance. The amount of heat generated is increased. On the contrary, when the heating source 30 is controlled to be driven at a low output, a small amount of power is supplied to the heating source driving unit 40, thereby reducing the amount of heat generated.

That is, the amount of heat generated by the heating source driver 40 is changed according to the operating state of the heating source driver 40. The fan 50 is driven according to a plurality of driving modes corresponding to the operating state of the heating source driver 40.

Hereinafter, the fan driving circuit 100 (see Fig. 2) for driving the fan 50 will be described in detail.

2 is a block diagram of a fan driving circuit of the electric cooker according to the embodiment of the present invention.

Referring to FIG. 2, the fan driving circuit 100 of the electric cooker according to the embodiment of the present invention may include a fan motor 510 for rotating the fan 500 and an operation state of the heating source driver 40. Therefore, the microcomputer 300 outputs a driving signal for the fan motor 510 and the fan motor receives the driving signal from the microcomputer 300 to supply power from the first and second power supply units 210 and 220. First and second driving controllers 410 and 420 supplied to the 510, and a voltage drop unit 430 for dropping the voltage output from the first driving control unit 410.

The first and second power supply units 210 and 220 may convert, for example, 220V-60Hz AC power supplied from the outside into 12V DC power and supply the same to the fan driving circuit 100.

The driving signal is input to the first and second driving controllers 410 and 420, and the first and second driving controllers 410 and 420 supply power to the fan motor 510 according to the driving signal. The fan motor 510 is driven in a plurality of driving modes corresponding to the driving signal.

The first driving controller 410 includes a first switching element TR1, a resistor R1, and a first buffer element TR3.

The first switching element TR1 may be, for example, a bipolar junction transistor (BJT) or a metal-oxide semiconductor field effect transistor (MOSFET). In this embodiment, the case where the first switching element TR1 is BJT has been described. The emitter terminal E corresponding to one end of the first switching element TR1 is connected to the first power supply 210 to receive a voltage 12V of a predetermined size. The collector terminal C corresponding to the other end of the first switching element TR1 is connected to one end of the voltage drop unit 430. On the other hand, the base end B of the first switching element TR1 is connected to one end of the first buffer element TR3.

The first buffer element TR3 buffers a difference between the voltage applied through one end of the first switching element TR1 and the voltage of the first driving signal applied from the microcomputer 300. That is, the emitter stage E, which corresponds to one end of the first buffer element TR3, is connected to the base terminal B of the first switching element TR1, and corresponds to the other end of the base stage B. ) Is connected to the output terminal of the microcomputer 300, the collector terminal (C) is grounded. Therefore, the first buffer device TR3 indirectly connects the first switching device TR1 and the microcomputer with different applied voltages, thereby preventing damage to the device due to the voltage difference. Like the first switching element TR1, the first buffer element TR3 may be a BJT or a MOSFET. In the present embodiment, the first buffer element TR3 is described as a case where the first buffer element TR3 is a BJT.

The voltage drop part 430, one end of which is connected to the collector terminal C of the first switching element TR1, includes first and second diodes D1 and D2. The other end of the voltage drop unit 430 is connected to a node N1 connected to the fan motor 510.

The first and second diodes D1 and D2 are connected in series, and anode ends of the first and second diodes D1 and D2 are connected to the other end of the first switching element TR1. Aligned to one end side of the voltage drop unit 430, and cathode ends of the first and second diodes D1 and D2 are aligned to the other end side of the voltage drop unit 430.

The second driving controller 420 includes a second switching element TR2, a resistor R2, and a second buffer element TR4.

The emitter terminal E corresponding to one end of the second switching element TR2 is connected to the second power supply 220 and has the same voltage 12V applied to one end of the first switching element TR1. Is applied. One end of the first and second switching elements TR1 and TR2 may be connected in parallel to each other in connection of the power supply unit. In addition, the collector terminal C corresponding to the other end of the second switching element TR2 is connected to the node N1, and the base terminal B receiving the second driving signal output from the microcomputer 300 is It is connected to the second buffer element TR4.

Since the configuration of the second buffer element TR4 is the same as that of the first buffer element TR1, a detailed description thereof will be omitted.

When the voltage of the driving signal of the microcomputer 300 is equal to the voltage of the current supplied from the power supply unit, or when the withstand voltage configuration is added to the microcomputer 300, the first and second buffering elements TR4 may be The fan driving circuit 100 may be omitted in the configuration.

Hereinafter, the driving of the fan driving circuit 100 according to the operating state of the heating source driver 40 will be described in detail.

The heating source driver 40 corresponds to the driving output of the heating source 30 and operates at a plurality of driving levels in which the output is sequentially increased. In this embodiment, some of the plurality of drive levels are defined as a low drive level, which is lower than any particular drive level, and a remaining drive level that is equal to or greater than the specific drive level as a high drive level.

When the heat source driver 40 is operated at the low drive level, the heat source driver 40 is driven in a relatively low heat generation state. In addition, when the heating source driver 40 is operated at the high driving level, the heating source driver 40 is driven in a relatively high heat generation state.

First, while the heating source driver 40 is not operated, the first and second driving signals output from the microcomputer 300 are low, and the first and second buffering elements TR3 and TR4, respectively. And the resistors R1 and R2 are input to the first and second switching elements TR1 and TR2, respectively. At this time, the first and second switching elements TR1 and TR2 remain off, and power supply to the fan motor 510 is not performed.

Next, when the heating source driver 40 is operated at the low drive level, the microcomputer 300 outputs the first drive signal to high and the second drive signal to low. Low).

The first switching device TR1 receiving the high first driving signal is turned on and from the power supply connected to one end of the first switching device TR1, the voltage dropping unit 430. The current is supplied to the fan motor 510 via. At this time, the voltage of the current in the state passing through the voltage drop unit 430 is referred to as V1.

On the other hand, the second switching element TR2 receiving the low second driving signal is continuously maintained in an off state and does not supply power to the fan motor 510.

The fan motor 510 supplied with the current having the V1 voltage rotates the fan 500 at a predetermined rotational speed in a first driving mode, thereby driving the heating source driver 40 driven at the low driving level. Cool down.

Next, when the heating source driver 40 is operated at the high driving level, the microcomputer 300 outputs both the first and second driving signals high.

Both the first and second switching elements TR1 and TR2 that have received the first and second driving signals having a high level are turned on. In this case, the voltage passing through the second switching element TR2 is referred to as V2.

The voltage of the current passing through the first switching element TR1 and the voltage dropping unit 430 is formed at V1, as in the case where the heating source driver 40 operates at the low driving level. . In this case, a voltage having the same magnitude is applied to one end of the first and second switching elements, and the current passing through the first switching element passes through the voltage dropping unit 430, so that the voltage V1 having the reduced voltage drop is a voltage. A relationship smaller than V2 holds.

Accordingly, the voltage of the node N1 connected to the other end of the voltage drop unit 430 and the other end of the second switching element TR2 is formed at V2 having a relatively high potential, and the fan motor 510 has V2. The power of the voltage is supplied.

The number of revolutions per hour of the fan 500 driven by the fan motor 510 increases in proportion to the voltage of the power supplied to the fan motor 510. Therefore, when the heating source driver 40 is operated at the high driving level, the power of the V2 voltage is supplied, so that the rotation per hour is relatively larger than the first driving mode to which the power of the V1 voltage is supplied. The fan 500 is driven by water. At this time, the driving mode of the fan motor 510 is called a second driving mode.

That is, when the heating source driver 40 is operated at the low drive level in the low heat generation state, the fan motor 510 is driven in the relatively low first drive mode. In addition, when the heating source driver 40 is operated at a high driving level in a high heat generation state, the fan motor 510 is driven in a relatively high speed second driving mode.

According to the fan driving circuit of the electric cooker and the electric cooker according to an embodiment of the present invention as proposed, the fan motor 510 for driving the fan 500 is the operating state of the heating source drive unit 40 As a result of operating in a plurality of driving modes according to the present invention, the cooling efficiency is increased, and noise that may be generated by excessively cooling the heating source driver 40 in a low heat generation state is reduced.

In addition, since the first driving control unit 410 and the second driving control unit 420 are separately connected to the power supply unit, even if any one of the first and second driving control units 410 and 420 is damaged, There is an advantage in that the operation of the other drive control unit can be stably cooled the heating source drive unit 40 without being affected.

1 is a perspective view showing a disassembled top plate in an electric hob according to an embodiment of the present invention.

2 is a configuration diagram of a fan driving circuit of the electric hob according to the embodiment of the present invention.

Claims (11)

A power supply unit; A heating source heated by receiving power from the power supply unit; A heating source driver for controlling power supply to the heating source and driving output of the heating source; A fan motor for rotating the fan for cooling the heating source driver; And And a fan driving circuit for driving the fan motor. The fan drive circuit, A microcomputer outputting a driving signal of the fan motor in accordance with an operation state of the heating source driver; A first connection connected to the power supply unit and selectively supplying power supplied from the power supply unit to the fan motor according to the driving signal to apply power to the fan motor so that the fan motor is driven in a first driving mode; A first driving controller including a switching element; It is connected to the power supply unit independently from the first driving control unit, and selectively supplies power supplied from the power supply unit to the fan motor to supply power to the fan motor so that the fan motor is driven in the second driving mode. A second driving controller including a second switching element to be applied; And The fan driving circuit may include a voltage drop unit configured to be supplied to the fan motor in a state where a voltage of power supplied from the first driving controller is dropped; Including, The power of the fan motor is controlled by supplying the power applied by the first switching element to the fan motor by dropping the voltage dropping part and supplying the power applied by the second switching element to the fan motor. Electric cooker. delete The method of claim 1, And the first and second switching elements are respectively turned on and off according to a drive signal of the microcomputer to selectively supply power to the fan motor. The method of claim 1, The other end of the first switching device is connected to one end of the voltage drop unit for dropping the voltage of the current supplied from the power supply unit to which one end of the first switching device is connected. And the other end of the first switching element is connected to a node to which the other end of the voltage drop and a fan motor are connected. The method of claim 4, wherein The voltage drop unit includes at least one diode, And an anode end of the diode is arranged at one end of the voltage drop portion, and a cathode end of the diode is arranged at the other end side of the voltage drop portion. The method of claim 4, wherein The first and second drive control unit, First and second buffers for buffering a difference between voltages of currents supplied from the power supply unit to the first and second switching elements and voltages of driving signals output from the microcomputer to the first and second switching elements. An electric cooker each comprising a portion. A fan motor for rotating the fan for cooling the heating source driver; A microcomputer outputting a driving signal for the fan motor according to an operating state of the heating source driver; First and second switching elements, one end of which is connected to a power supply and supplied with power, and turned on / off according to the input driving signal; And And a voltage drop unit connected to the other end of the first switching device to reduce the voltage of the current supplied from the other end of the first switching device. The fan motor is connected to the other end of the second switching element and the other end of the voltage drop part so that the first switching element is turned on or the first and second switching elements are turned on so that power of different voltage is supplied to the fan motor. The fan drive circuit of the electric cooker which is driven by a plurality of drive modes by being applied. The method of claim 7, wherein The first and second switching elements, the fan driving circuit of the electric cooker is supplied with a current of the same voltage magnitude from the power supply. The method of claim 8, The first and second switching elements, respectively, the fan drive circuit of the electric cooker connected in parallel with the power supply. delete delete

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