KR970004459Y1 - Output conversion of complex microwave oven - Google Patents

Abstract

None.

Description

Output converter of compound microwave

1 is a heater control circuit diagram of a conventional composite microwave oven.

2 is a control block diagram of the output converter of the composite microwave oven according to an embodiment of the present invention

3 is a detailed circuit diagram of the output converter of the composite microwave oven according to an embodiment of the present invention

4 is a flow chart showing the operation sequence of the output conversion control of the composite microwave oven according to an embodiment of the present invention

* Explanation of symbols for main parts of the drawings

10: cooking input means 20: control means

30: relay means 31: heater relay

40: heating means 41: the first heater

42: second heater

The present invention relates to a composite microwave oven that cooks using microwaves oscillated in a magnetron of the present invention and heat generated by a heater, and more particularly, to an output converter of a composite microwave oven capable of variously converting the output of the heater.

In general, in the conventional microwave oven, as shown in FIG. 1, the user places food in a cooking chamber formed at a predetermined portion inside the main body, and then cooks the oven 60 using the heating of the heater 60, cooking the grill, and the like. The corresponding cooking selection key is selected by the cooking input means 50.

When the key corresponding to the oven cooking and the grill cooking is selected by the cooking input means 50, the selected key signal is inputted from the control means 20 and the operation control is performed on the heater relay 31 according to the input key signal. Output the signal.

When the control means 20 outputs the operation control signal to the heater relay 31, the heater relay 31 is turned on while the relay coil L4 current connected to the control means 20 is induced.

When the heater relay 31 is turned on, the commercial AC voltage input from the AC power input terminal 1 is applied to the heater 60 through a plug, and the heater 60 starts to generate heat.

When the heater 60 starts to generate heat, it starts to cook food in the cooking chamber by blowing heat generated when the heater 60 generates heat into the cooking chamber.

However, in the conventional cooking method by the heater, the output according to the heating value of the heater is constant, so that the heat distribution state in the cooking chamber is always uniform regardless of the type and weight of food in the cooking chamber, so that the frozen food is thawed. For foods without fluidity such as pizza or pizza, there is a problem that the food is not cooked evenly and is partially heated.

In addition, regardless of the type and weight of food placed in the cooking chamber, by simply turning on / off the heater, the heating value of the heater is always uniform, so that the optimum cooking effect cannot be obtained and the user's reliability of the product is lowered. There was a problem.

Therefore, the present invention has been made to solve the above problems, the object of the present invention is to change the output of the heater by a simple key operation to adjust the heat distribution state in the cooking chamber in a variety of types and weight of food Accordingly, the present invention provides an output converter of the composite microwave oven which not only obtains the optimum cooking effect desired by the user, but also satisfies the user's reliability of the product.

In order to achieve the above object, an output converter of a composite microwave oven according to the present invention includes heating means for generating heat by receiving a commercial AC voltage input from an AC power input terminal, and cooking for inputting a key signal to convert an output amount of the heating means. Control means for controlling the overall operation by determining the output amount of the heating means in accordance with the input signal, the key signal input by the cooking input means, and the heating operation of the heating means in accordance with the control signal output from the control means Characterized in that consisting of a relay means for controlling.

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

As shown in FIGS. 2 to 3, the cooking input unit 10 selects various cooking functions (cooking time, cooking menu, output of the combined microwave, start / stop of the combined microwave, etc.) desired by the user. A number of function keys are provided on the front control panel of the microwave oven.

The control means 20 is a microcomputer which receives the key signal input by the cooking input means 10 to control the overall operation of the composite microwave oven and simultaneously controls the output calorific value of the heater. 20, of course, to control the high frequency output of the magnetron not shown.

In addition, the relay means 30 is a relay for receiving a control signal output from the control means 2 in accordance with the key signal input by the cooking input means 10 to control the heating operation of the heater, the relay means ( 30 is a heater relay 31 which is turned on / off by receiving a control signal output from the control means 20 to start the heating operation according to the key signal input by the cooking input means 10, and Directing the first and second heaters 41 and 42 according to the key signal input by the cooking input means 10. The first, second and third relays RY1, RY2 and RY3 are configured to receive the control signal output from the control means 20 so as to change the output amount in parallel.

In addition, in the figure, the heating means 40 receives the commercial AC voltage input from the AC power input terminal 1 during the on / off operation of the relays RY1, RY2, and RY3 under the control of the control means 20. As a heater for generating heat, the heating means 40 includes a first heater 41 for generating heat by receiving a commercial AC voltage input from the AC power input terminal 1 when the heater relay 31 is turned on, and the heater relay. It consists of a second heater 42 which generates heat by receiving a commercial AC voltage input from the AC power input terminal 1 at the time of turning on the 31. The first and second heaters 41 and 42 are arranged in parallel and in parallel. As a result, the heater output of the composite microwave oven varies.

Hereinafter, the effect of the output converter of the composite microwave oven configured as described above will be described with reference to FIG.

FIG. 4 is a flowchart showing the operation procedure of the output conversion control of the composite microwave according to the present invention, and in FIG. 4, S denotes a step.

First, when the power of the composite microwave is supplied, the control unit 20 converts the commercial AC voltage input from the AC power input terminal 1 into a predetermined constant voltage required for driving the composite microwave in the DC power supply unit (not shown). And output to each driving circuit.

Therefore, in step S1, the constant voltage output from the DC power supply means is applied by the control means 20 to initialize the composite microwave oven in accordance with the cooking operation.

At this time, the user places the food to be cooked in the cooking chamber, and then proceeds to step S2 and inputs a key signal and a cooking time corresponding to the output amount of the heater and the heat distribution state by the cooking input means 10.

Accordingly, in step S3, the key signal input by the assembly input means 10 is received from the control means 20 to determine the output amount and heat distribution state of the heater desired by the user.

Subsequently, in step S4, a control signal is output to the relay means 30 so as to convert the output amount of the heater in accordance with the output amount determined by the control means 20 and the heat distribution state.

In step S5, the heater relay 31 and the first, second, and third relays RY1, RY2, and RY3 are turned on and off in accordance with the control signal output from the control means 20. The two heaters 41 and 42 are operated in series, in parallel or individually.

A detailed embodiment of converting the output amount of the heater by turning on / off the operation of the relays RY1, RY2, and RY3 in steps S4 to 5 will be described in detail with reference to the circuit diagram shown in FIG.

First, when the user selects an output amount that the first heater 41 can output, the control means 20 outputs a high level control signal to the heater relay 31 so that the heater can operate. In response to a high level control signal output from the control means 20, a current is applied to the relay coil L4 connected to the output terminals 01 and 02 of the control means 20 while the heater relay 31 Is on.

When the heater relay 31 is turned on, the control means 20 outputs a high level control signal to the first and third relays RY1, RY2, and RY3 to operate the first heater 41. The low level control signal is output to the second relay RY2.

The current is induced in the relay coils L1 and L3 connected to the output terminals 03, 04, and 07 and 08 of the control means 20 according to the high level control signal output from the control means 20. The first and third relays RY1 and RY3 are turned on.

When the first and third relays RY1 and RY3 are turned on, current flows from the heater relay 31 to the first relay RY1 to the first heater by a commercial AC voltage input from the AC power input terminal 1. A closed circuit is formed by flowing from (41) to the third relay RY3.

When the closed circuit is configured as described above, the first heater 41 receives a commercial AC voltage input from the AC power input terminal 1 and generates heat by the output amount of the first heater 41 desired by the user.

Next, when the user selects the output amount that the second heater 42 can produce, the control means 20 causes the heater relay 31 to operate in the same manner as in the operation of the first heater 41. A high level control signal is output to

In response to a high level control signal output from the control means 20, current is induced in the relay coil L4 connected to the output terminals 01 and 02 of the control means 20, and the heater relay 31 Is on.

When the heater relay 31 is turned on, the control means 20 outputs a high level control signal to the second and third relays RY1, RY2, and RY3 to operate the second heater 42. The low level control signal is output to the first relay RY1.

The current is induced in the relay coils L2 and L3 connected to the output terminals 05, 06, 07 and 08 of the control means 20 in accordance with the high level control signal output from the control means 20. The second and third relays RY1, RY2, and RY3 are turned on.

When the second and third relays RY1, RY2, and RY3 are turned on, current flows from the heater relay 31 to the second heater 42 by a commercial AC voltage input from the AC power input terminal 1. The closed circuit is constructed.

When the closed circuit is configured as described above, the second heater 42 generates heat by the output amount of the second heater 42 desired by the user input from the AC voltage input terminal 1.

In addition, when the user selects an output amount that can be output by the parallel combination of the first and second heaters 41 and 42, the control means 20 is different from the operation of the first or second heaters 41 and 42. Similarly, a high level control signal is output to the heater relay 31 so that the heater can operate.

In response to a high level control signal output from the control means 20, current is induced in the relay coil L4 connected to the output terminals 01 and 02 of the control means 20, and the heater relay 31 Is on.

When the heater relay 31 is turned on, in the control means 20, the first, second and third relays RY1, RY2, and RY3 are configured to operate in parallel with the first and second heaters 41 and 42. Outputs a high level control signal.

Relay coils L1 and L2 connected to the output terminals 03, 04, (05, 06) and (07, 08) of the control means 20 in accordance with the high level control signal output from the control means 20. The first, second and third relays RY1, RY2, and RY3 are turned on as a current is induced at L3.

When the first, second, and third relays RY1, RY2, and RY3 are turned on, current flows through the heater relay 31 through the heater relay 31 by a commercial AC voltage input from the AC power input terminal 1. It is simultaneously applied to the two relays RY1 and RY2 and flows through the first heater 41 and the second heater 42 to the third relay RY3 to form a closed circuit.

When the closed circuit is configured as described above, the first and second heaters 41 and 42 are configured in parallel, and are supplied with a commercial AC voltage input from the AC power input terminal 1 to the first and second heaters desired by the user. 41, 42) generates heat by the parallel output.

Next, when the user selects an output amount that can be output in series combination of the first and second heaters 41 and 42, the control means 20 at the time of operation of the first or second heaters 41 and 42. Similarly, a high level control signal is output to the heater relay 31 so that the heater can operate.

In response to a high level control signal output from the control means 20, current is induced in the relay coil L4 connected to the output terminals 01 and 02 of the control means 20, and the heater relay 31 Is on.

When the heater relay 31 is turned on, the control means 20 outputs a high level control signal to the first relay RY1 so that the first and second heaters 41 and 42 are configured and operated in series. The low level control signals are output to the second and third relays RY2 and RY3.

In response to the high level control signal output from the control means 20, current is induced in the relay coil L1 connected to the output terminals 03 and 04 of the control means 20, so that the first relay RY1 Is on.

When the first relay RY1 is turned on, current flows through the heater relay 31 from the first relay RY1 to the first heater 41 by the commercial AC voltage input from the AC power input terminal 1. The closed circuit is configured while flowing to the second heater 42.

When the closed circuit is configured as described above, the first and second heaters 41 and 42 are configured in series, and are supplied with a commercial AC voltage input from the AC power input terminal 1 to the first and second heaters desired by the user. The heat is generated by the output amount according to the series combination of 41 and 42).

As described above, the first and second heaters 41 and 42 may be combined with each other alone or in series or in parallel according to a desired output amount, thereby variously converting the output amount of the heater.

Subsequently, in step S6 the first and second heaters 41 in accordance with the output amount of the heating means 40 changed by controlling the relay in the control means 20 according to the key signal input by the cooking input means 10. , 42) is started to uniformly cook the food placed in the cooking chamber by blowing the heat generated during the heating of the cooking chamber into the cooking chamber.

At this time, in step S7, the cooking input means 10 determines whether the cooking time set by the user has elapsed. If the cooking time has not elapsed (NO), the process returns to step S6 to continue the cooking operation. While performing, the operation below Step S6 is repeatedly performed.

On the other hand, when the cooking time has elapsed (YES), the control means 20 outputs a low level control signal to the heater relay 31 so as to block the heating operation of the heater. do.

Accordingly, the heater relay 31 is turned off while no current is induced in the relay coil L4 connected to the output terminals 01 and 02 of the control means 20.

Accordingly, the commercial AC voltage supplied from the AC power input terminal 1 to the first or second heaters 41 and 42 is cut off so that the first and second heaters 41 and 42 stop the heating operation. To exit.

On the other hand, in one embodiment of the present invention has been described a variable output amount of the heater corresponding to the oven cooking and grill cooking of the composite microwave, the present invention is not limited to this function of the output variable of the magnetron that the general composite microwave oven has Of course it includes.

According to the output conversion device of the composite microwave oven according to the present invention as described above, the user can change the heat distribution in the cooking chamber by varying the output of the heater by a simple key operation according to the type and weight of food In addition to obtaining the optimum cooking effect desired, there is an excellent effect that can satisfy the user's reliability of the product.

Claims (3)

A heating means (40) for generating heat by receiving a commercial AC voltage input from the AC power input (1), cooking input means (10) for inputting a key signal to convert an output amount of the heating means (40), and the cooking The control means 20 determines the output amount of the heating means 40 in accordance with the key signal input by the input means 10 and controls the entire operation, and according to the control signal output from the control means 20 Output conversion device of the composite microwave oven, characterized in that consisting of a relay means for controlling the heating operation of the heating means (40). The method of claim 1, wherein the heating means 40 is a first to generate a heat generated by receiving a commercial AC voltage input from the AC power input terminal 1 during the on / off operation of the relay by the control of the control means 20 And a second heater (41, 42). According to claim 1, The relay means 30 is output from the control means 20 so that the first and second heaters (41, 42) generates heat in accordance with the key signal input by the cooking input means (10) The control to convert the output amount of the first and second heaters (41, 42) in accordance with the key signal input by the heater relay 31 and the cooking input means 10 is turned on / off receiving the control signal And a first, second and third relay (RY1, RY2, RY3) which are turned on / off by receiving a control signal output from the means (20).