KR100601429B1 - Damper driving circuit of mechanical microwave range - Google Patents

Abstract

The present invention relates to a damper driving circuit of a mechanical microwave oven, comprising a damper switch for checking whether the damper is fully opened or closed in a mechanical microwave oven, and driving the damper according to whether the damper is fully opened or closed. A drive circuit is disclosed.

The damper driving circuit of the mechanical microwave oven is a damper driving circuit of a mechanical microwave oven which opens and closes a damper by selection of a magnetron or a heater. When the damper is completely opened by checking the open / closed state of the damper, the first input (FO) is performed. A damper switch connected to a stage and connected to a second input FC stage when the damper is completely closed, a first inverter for inverting and outputting an input signal of the first input terminal, and an input signal of the second input terminal. A second inverter to be outputted, a first end gate to which the magnetron selection signal and the output signal of the first inverter are applied, a second end gate to which the heater selection signal and the output signal of the second inverter are applied; An or gate outputting the driving signal of the damper in response to the output signal of the first and second end gate.

Microwave oven, damper, cam, drive circuit, intake vent, dielectric heating method, heater method

Description

Damper driving circuit of a mechanical microwave oven

1 is a block diagram schematically showing a configuration of a mechanical microwave oven having a damper driving circuit according to an embodiment of the present invention.

Figure 2 is a block diagram schematically showing the configuration of the damper portion used in the mechanical microwave oven according to an embodiment of the present invention

3 is a circuit diagram showing a driving circuit of a mechanical microwave oven according to an embodiment of the present invention.

<Description of Reference Symbols for Main Parts of Drawings>

110: control panel unit 120: control unit

130: oscillation unit 140: damper unit

142: switch 144: motor

146: cam 150: cooking chamber

200: drive circuit

The present invention relates to a microwave oven, and more particularly, to a damper driving circuit of a mechanical microwave oven capable of selectively opening and closing the inlet of the microwave oven.

In general, high frequency irradiation of food placed in the cooking chamber of a microwave oven generates a large amount of water vapor as the food is heated, which prevents steaming on the transparent inner plate of the door or condensation of water droplets on the wall. In order to inject the appropriate amount of wind into the cooking chamber is configured to discharge to the exhaust hole.

On the other hand, the wind flowing into the cooking chamber is mainly a part of the wind generated from the cooling fan provided in the rear of the battle room cools the heat generated by the magnetron, and then flows into the cooking chamber through the duct and stagnated in the cooking chamber It is configured to be discharged to the exhaust hole drilled in the cooking chamber rear portion together.

Therefore, when the food placed inside the cooking chamber is heated at high frequency, water vapor is discharged as described above.However, when heating food with a heater in a multi-functional microwave oven, a separate inlet of the cooking chamber may be used to reduce heat loss inside the cooking chamber. The damper of the damper is configured to selectively open and close the intake port.

The damper is configured to open and close the damper by manipulating the control panel. When the heater is operated, a solenoid operated by an electrical signal pushes the damper to block the inlet of the cooking chamber, or a plurality of gears interlock to operate the damper. Techniques for opening and closing the damper by a method such as a gear mechanism are used.

In the multi-functional microwave oven having a microcomputer, the damper is driven by checking whether the damper is opened or closed using the microcomputer. For example, when the food is cooked by using a high frequency dielectric heating method, the damper is checked to be completely open to control the damper to be opened, and when the food is cooked by using a heater, the damper is completely closed. Check to control the damper to close.

However, in a microwave oven without a microcomputer, it is not possible to check whether the damper is fully opened or closed, and thus malfunctions of the microwave oven, such as cooking of a dielectric heating method in a state where the damper is not fully opened, may occur. .

Therefore, a damper driving device that can check whether the damper is fully opened or closed in a mechanical microwave oven is essentially required.

Accordingly, an object of the present invention is to provide a damper driving circuit of a mechanical microwave oven capable of driving the damper by checking whether the damper is completely opened or closed in a mechanical microwave oven in order to solve the above-mentioned problems.

Another object of the present invention is to provide a damper driving circuit of a mechanical microwave oven having a damper switch capable of checking whether the damper is fully opened or closed in a mechanical microwave oven to drive the damper according to whether the damper is fully opened or closed.

In order to achieve the above object, the structure of the damper drive circuit of the mechanical microwave oven according to the present invention,

In the damper drive circuit of the mechanical microwave oven for opening and closing the damper by the choice of magnetron or heater,

A damper switch connected to a first input (FO) terminal when the damper is completely open by checking an open / closed state of the damper, and connected to a second input (FC) terminal when the damper is completely closed;

A first inverter for inverting and outputting an input signal of the first input terminal;

A second inverter for inverting and outputting an input signal of the second input terminal;

A first AND gate to which the magnetron selection signal and the output signal of the first inverter are applied;

A second AND gate to which the heater selection signal and the output signal of the second inverter are applied; And

An or gate outputting the driving signal of the damper in response to the output signal of the first and second end gate.

The magnetron selection signal is a data signal generated when the dielectric heating method using the magnetron is selected, and the heater selection signal is a data signal generated when the heater method is selected.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE INVENTION Since the following descriptions are only for example, without intention other than the intention to help those of ordinary skill in the art to understand the present invention, it is to be interpreted as limiting the scope of the present invention. Will not be.

1 is a block diagram schematically showing a configuration of a mechanical microwave oven having a damper driving circuit according to an embodiment of the present invention. Referring to the accompanying FIG. 1, a microwave oven having a damper driving circuit according to the present invention will be described. Same as

Referring to FIG. 1, a mechanical microwave oven according to the present invention includes a control panel 110, a controller 120, an oscillator 130, a damper 140, and a heating chamber 150.

The control panel 110 includes a timer knob, an output control knob, a selection knob, etc., and serves to select a cooking time and a high frequency output using the timer knob and the output control knob.

The control unit 120 includes a safety switch for preventing an overcurrent from flowing in the microwave oven, a timer switch for turning on a timer motor by adjustment of the timer knob, a selection switch for selecting a driving of a magnetron and a heater, and the like. The controller 120 operates the oscillator 130 and the damper 140 according to the selected time, output control and function.

The oscillator 130 includes a magnetron generating high frequency, a cooling fan for cooling the magnetron, a heater voltage required for the operation of the magnetron, a high voltage transformer for forming a DC high voltage, a high voltage capacitor, and a high voltage diode.

The damper unit 140 plays a role of discharging air in the cooking chamber to the outside through an intake port. The damper part is driven when the food is cooked by the dielectric heating method using a high frequency, so that the damper must be completely opened and then opened and closed. In addition, when the food is cooked by the heater method using a heater, the damper must be completely closed, and thus, it is driven to be completely closed by checking whether it is opened or closed.

The structure and operation of the damper portion will be described in more detail in the following description of FIGS. 2 and 3.

The cooking chamber 160 may include a heating plate for heating food, a tray into which food is inserted, a tray motor for rotating the tray, a lamp, and the like.

2 is a block diagram schematically showing a configuration of a damper part used in a mechanical microwave oven according to an embodiment of the present invention, and FIG. 3 is a circuit diagram showing a driving circuit of the mechanical microwave oven according to an embodiment of the present invention.

2 and 3, the configuration and operation of the damper unit and the damper driving circuit of the mechanical microwave oven according to the present invention will be described in detail.

2 and 3, the damper unit 140 includes a switch 142 which is largely performed according to a dielectric heating method or a heater method, a driving circuit 200 for driving a motor, and a cam to rotate. A motor 144 and a cam 146 having a groove or protrusion.

The switch 142 is connected to the magnetron when the dielectric heating method is selected by the control panel according to the food, and is connected to the heater when the heater method is selected by the control panel.

The driving circuit 200 receives a control signal for operating the magnetron or the heater according to a function selected by the control panel unit, and provides a driving signal to the motor by checking whether the current damper is fully opened or closed.

The motor is connected to an output terminal of the driving circuit to drive the cam when the output signal of the driving circuit is a '1' data signal, and to drive the cam when the output signal of the driving circuit is a '0' data signal. Otherwise, the state of the cam is maintained.

The cam is connected to the intake port so that when the motor rotates, the cam rotates accordingly to open and close the intake port according to the movement of the protrusion or groove.

Looking at the configuration and operation of the drive circuit in more detail, as shown in Figure 3, the drive circuit 200 is a current source 202, a switch element 203, two inverters (204, 206), It consists of two end gates 208 and 210 and an or gate 212.

The current source 202 is connected to one end of the switch element 203 to supply current, and the other end of the switch element 203 is selectively connected to the first and second connection terminals FO and FC.

The switch element 203 checks whether the damper is opened or closed, and when the damper is fully open, the switch element 203 is connected to a first connection terminal (FO) terminal so that a '1' data signal is input to the FO terminal. When the damper is completely closed, the damper is connected to a second connection (FC) terminal, so that a zero data signal is input to the FC terminal.

In addition, the first inverter 204 is connected to the FO terminal to invert the data signal of the FO terminal to provide to the first end gate 208, the second inverter 206 is connected to the FC terminal to the The data signal of the FC terminal is inverted and provided to the second AND gate 210.

In addition, the first end gate 208 receives the output signal of the first inverter 204 and the magnetron selection signal M, and the second end gate 210 outputs the second inverter 206. The signal and the heater selection signal H are received. In addition, the or gate 212 provides a driving signal MT to the motor in response to the output signals of the first and second end gates 208 and 210.

Therefore, when the magnetron is selected and the damper is completely open, the first end gate 208 outputs '0' data, and the second NAND gate 210 also outputs '0' data to the or gate. The output MT becomes '0' data so that the motor is not driven. Therefore, the damper remains fully open during the magnetron operation.

However, when the magnetron is selected and the damper is not fully open, the first end gate 208 outputs '1' data, and the second NAND gate 210 outputs '0' data, thereby providing the OR. The output MT of the gate outputs '1' data so that the motor is driven to completely open the damper that is not fully open.

On the other hand, when the heater is selected and the damper is not completely closed, the first end gate 208 outputs '0' data, and the second NAND gate 210 outputs '1' data to the OR. The output MT of the gate becomes '1' data so that the motor is driven to completely close the damper.

However, when the heater is selected and the damper is completely closed, the first end gate 208 outputs '0' data, and the second NAND gate 210 also outputs '0' data to the or gate. The output MT becomes '0' data so that the motor is not driven. Thus, the damper remains in a completely closed state.

As described above, according to the damper driving circuit of the mechanical microwave oven according to the embodiment of the present invention, the damper switch element is operated by checking the open / closed state of the damper, so that the selector is selected when the damper is not completely open. When the damper is completely open, the damper is completely closed when the heater is selected while the damper is not completely closed.

Therefore, after the cooking method is selected in the mechanical microwave oven, the damper may be driven by checking the open / closed state of the damper.

The damper driving circuit of the mechanical microwave oven according to the embodiment of the present invention is not limited to the above embodiment, and can be variously designed and applied without departing from the basic principles of the present invention. It will be obvious to those who have ordinary knowledge.

As described above, the present invention has the effect of driving the damper by checking whether the damper is completely opened or closed in a mechanical microwave oven.

In addition, the present invention has a damper switch for checking whether the damper is fully opened or closed in the mechanical microwave oven has the effect of driving the damper according to whether the damper is fully opened or closed.

Claims (2)

In the damper drive circuit of the mechanical microwave oven for opening and closing the damper by the choice of magnetron or heater, A damper switch connected to a first input (FO) terminal when the damper is completely open by checking an open / closed state of the damper, and connected to a second input (FC) terminal when the damper is completely closed; A first inverter for inverting and outputting an input signal of the first input terminal; A second inverter for inverting and outputting an input signal of the second input terminal; A first AND gate to which the magnetron selection signal and the output signal of the first inverter are applied; A second AND gate to which the heater selection signal and the output signal of the second inverter are applied; And And an or gate for outputting a driving signal of the damper in response to the output signals of the first and second end gates. The method of claim 1, The magnetron selection signal is a data signal generated when the dielectric heating method using the magnetron is selected, and the heater selection signal is a data signal generated when the heater method is selected.

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