KR100312917B1 - Heating Cooker - Google Patents

Abstract

The present invention relates to a heating cooker provided with a safety switch operating on the power line in accordance with the opening and closing of a door, which prevents an overcurrent from flowing when the safety switch fails, and at the same time makes it possible to determine whether one of the two safety switches has failed. In addition, to simplify the configuration and to reduce the product cost, the heating cooker of the present invention is provided with a door for opening and closing the opening of the heating chamber, so that the anodes of the power lines 31 and 32 can be cut off, respectively. Two safety switches (24, 25) that operate according to the opening and closing of the door, and when the door is opened, the door (b) connected to each common contact (c) of the two safety switches (24, 25) is opened. The control circuit 35 which detects the conduction state between the contact b on which the door is opened and the door is opened, the door switch 29 which detects the open / closed state of the door, and the safety switch 24, when the door is opened, And a control circuit 35 for detecting a fault such as 25). According to this configuration, the conduction between the side contacts b of the doors of the safety switches 24 and 25 is opened when the door is opened. It is possible to determine whether at least one of the safety switches 24 and 25 has failed based on the state.

Description

Heating Cooker

The present invention relates to a heating cooker provided with a safety switch operating in accordance with opening and closing of a door on a power line.

In the microwave oven which is this type of cooking heater, an example of the structure of the partial electric circuit which provided the safety switch is shown in FIG. As shown in FIG. 8, power lines 2 and 3 are drawn from a power plug 1 connected to a commercial AC power source, and safety switches 4 and 5 are provided to these power lines 2 and 3, respectively. have. A fuse 6 is provided between the safety switch 4 and the power plug 1 on one power line 2.

In addition, the monitor switch 7 is connected to the site opposite to the safety switch 4, 5 between the power supply lines 2, 3, and the primary winding 8a of the transformer 8 is connected. The safety switches 4 and 5 are switches that are turned off when the door is opened and turned on when the door is closed. The monitor switch 7 is a so-called short switch that is turned on when the door is opened and turned off when the door is closed. Moreover, the transformer 8 is a transformer which comprises the power supply circuit which supplies power to a magnetron.

In the case of the above configuration, in the case where the safety switches 4 and 5 fail and continue to be turned on, a short circuit is formed because the monitor switch 7 is turned on when the door is opened, and an overcurrent flows and the fuse 4 Melt and break Thereby, the structure which can prevent the use of a microwave oven in the state which the safety switches 4 and 5 failed is provided.

However, in the conventional configuration, when the fuse 4 melts and is cut off, it can be said to be a short time, but since the overcurrent flows, it cannot be said that it is very preferable for safety reasons. Moreover, the breaker of the wiring board might interrupt | block operation when the said overcurrent flows. In addition, when any one of the two safety switches 4 and 5 has failed, a short circuit is not formed. Therefore, there is a problem in that the microwave oven is used as it is while one safety switch has failed.

In addition, it was necessary to provide a time difference between the switch operation of the two safety switches 4 and 5 and the switch operation of the monitor switch 7. Specifically, the monitor switch 7 is turned on after the safety switches 4 and 5 are turned off when the door is opened, and the safety switches 4 and 5 are turned off after the monitor switch 7 is turned off when the door is closed. Had to be turned on. For this reason, there is a drawback that a dedicated lever member for staggering the time difference is required, which complicates the configuration and increases the product cost.

9 shows an example of the configuration in which the switches 4, 5, 7 are provided in the main body of the microwave oven. As shown in FIG. 9, the safety switch 4 on one side is operated by the operation unit 10 installed on the door 9, and the safety switch 5 on the other side is operated on the door 9. 11) and the operation lever 12, it is configured to switch operation. And the monitor switch 7 is comprised so that switch operation is carried out by the door operating part 11 and the exclusive lever 13 for providing time difference.

Accordingly, an object of the present invention is to prevent overcurrent from flowing when a safety switch fails, and to determine that either one of the two safety switches has failed, and also to simplify the configuration and reduce the product cost. It is to provide a heat cooker that can be.

1 is an electric circuit diagram for explaining the principle of the detection operation showing an embodiment of the present invention;

2 is a schematic longitudinal side view of a microwave oven;

3 is an electric circuit diagram showing a main part of a control circuit and a safety switch;

4 is an equivalent of FIG. 1 when one safety switch has failed;

5 is a flowchart,

6 is an electric circuit diagram of a microwave oven with a heater,

7 is a flowchart,

8 is an equivalent view of FIG. 1 showing a conventional configuration, and

9 is an equivalent view of FIG. 2.

* Explanation of symbols for main parts of the drawings

21: body 22: door

24, 25: safety switch 29: door switch (door detection means)

31, 32: power line 34: transformer

34a: primary winding 35: control circuit (switch detection means, control means)

40: printed wiring board 41: microcomputer

46: main relay 50: grill relay

53: oven relay 55: fan motor relay

56: range relay

The heating cooker of the present invention is provided with a door for opening and closing the opening of the heating chamber, at least two safety switches which are installed to be able to cut off the anode of the power line, respectively, and operate according to the opening and closing of the door, and each of the safety switches when the door is opened. When the door connected to the common contact of the door is connected to the open contact, the switch detecting means for detecting the conduction state between the open contacts, the door detecting means for detecting the opening and closing state of the door, and when the door is open The switch detecting means is characterized in that it is provided with control means for executing a detecting operation.

According to the above configuration, the switch detecting means causes the detecting operation to be performed when the door is open. Therefore, when one of the two safety switches has failed, the door is opened based on detecting the conduction state between the contacts on the open side. The failure of one safety switch can be determined. In this configuration, overcurrent does not flow even if the safety switch fails. In addition, since the monitor switch can be made unnecessary and the lever for the monitor switch can be made unnecessary, the configuration is simple and the product cost is reduced. As a door detecting means for detecting the open / closed state of the door, for example, a door switch is separately required. However, since the door switch may be operated in synchronization with the safety switch, a lever dedicated to the monitor switch is unnecessary.

Further, in the above configuration, it is preferable that the switch detecting means performs a predetermined time detecting operation at the time when the door is opened. When it is determined that the abnormality is determined by the switch detecting means, the abnormality may be notified and the heating operation may be prohibited.

It is also preferable that the switch detecting means is configured to detect the resistance between the contacts of the open side of the two safety switches and, at the same time, determine that the safety switch is broken when the detected resistance value is infinite. In this case, it is better to determine that the switch detecting means is the second abnormal state when the detected resistance value is larger than the set value. In addition, when the detected resistance value is smaller than the set value, it is good to judge that it is a 3rd abnormal state.

On the other hand, it is preferable that a plurality of loads and a plurality of relays for turning on and off each load are provided between the power lines, and the switch detecting means is configured to judge failure of each load by sequentially turning on the plurality of relays. . In this configuration, it is more preferable that the switch detecting means performs the detecting operation when the key of the operation panel is specially operated while the door is open.

Hereinafter, an embodiment in which the present invention is applied to a microwave oven will be described with reference to FIGS. 1 to 7. First, the failure detection principle of the safety switch of the present embodiment will be described with reference to Figs. 2 is a diagram showing a schematic structure around a safety switch in a machine room of a microwave oven. In this FIG. 2, the front opening part of the heating chamber (not shown) provided in the main body 21 of the microwave oven is comprised so that the door 22 may open and close. In the main body 21, a machine room 23 is provided adjacent to the heating chamber, and two safety switches 24 and 25 are provided in the machine room 23.

These safety switches 24 and 25 are comprised by micro switches, for example. The safety switch 24 of one (upper part) is comprised so that switch operation may be carried out by the operation part 26 provided in the upper end part of the door 22. As shown in FIG. Moreover, the safety switch 25 of the other side (lower) is comprised so that a switch operation may be carried out via the interlocking lever 28 by the operation part 27 provided in the lower end part of the door 22. As shown in FIG.

The safety switches 24 and 25 have a common contact c and two contacts a and b as shown in the electrical circuit diagram of FIG. 1 and are turned on between the contacts ca when the door 22 is closed. , When the door 22 is opened, the contact cb is turned on. In this case, each contact point b of the safety switches 24 and 25 constitutes a contact point on which the door is opened.

Moreover, the door switch 29 (not shown in FIG. 2, but shown in FIG. 1) is provided in the vicinity of the lower safety switch 25 so that this safety switch 25 may run side by side. The door switch 29 is made of, for example, a micro switch and is configured to be operated by the operating unit 27 of the door 22 through the interlocking lever 28, that is, to be operated in synchronization with the safety switch 25. It is. And the door switch 29 is for example configured to be on when the door 22 is closed and off when the door 22 is open. Thereby, the structure which can detect the opening / closing state of the door 22 by the ON / OFF of the door switch 29 is comprised. In this case, the door switch 29 constitutes the door detecting means. In addition, the door switch 29 may be configured in the on-off operation in the inverse of the above-described on-off operation with respect to opening and closing of the door 22.

In Fig. 1 showing the electrical configuration, power lines 31 and 32 are drawn from a power plug 30 connected to a commercial AC power source, and a fuse is connected to one of the power lines 31 and 32. The 33 and the safety switch 24 are provided, and the safety switch 25 is provided in the other power supply line 32. The primary winding 34a of the transformer 34 is connected between the power supply lines 31 and 32.

Specifically, the contact a of the safety switch 24 is connected to one end of the fuse 33 and the common contact c is connected to one end of the primary winding 34a. The contact a of the safety switch 25 is connected to the power plug 30, and the common contact c is connected to the other end of the primary winding 34a. As a result, the safety switches 24 and 25 are configured to cut off the positive poles of the power supply lines 31 and 32, respectively. The contact b of the safety switch 24 is also connected to the first terminal 36 of the control circuit 35 and the contact b of the safety switch 25 is the second terminal 37 of the control circuit 35. Is connected to. In addition, the two contacts c and a of the door switch 29 are connected to the third terminal 38 and the fourth terminal 39 of the control circuit 35.

On the other hand, the transformer 34 is a transformer constituting a power supply circuit for supplying driving power to a magnetron (not shown), and the secondary winding 34b has various electrical components constituting a power supply circuit for driving a main relay and a magnetron. (Furthermore, magnetron) is connected.

The control circuit 35 has respective functions as the switch detecting means and the control means of the present invention. And the control circuit 35 is comprised from the microcomputer 41 provided in the printed wiring board 40, and various electrical components, as shown in FIG. The microcomputer 41 has a function of controlling the overall operation of the microwave oven, and stores a control program therefor. The control circuit 35 is configured to supply a constant voltage (for example, a DC voltage of 5V) output from the DC power supply circuit 42 as shown in FIG. The DC power supply circuit 42 has a portion between the fuse 33 of the power supply line 31 and the contact a of the safety switch 24, the power plug 30 of the power supply line 32, and the safety switch. It is connected to the part between contact point a of (25).

Next, the structure for detecting abnormality (failure) of the safety switches 24 and 25 by the microcomputer 41 is demonstrated with reference to FIG. As shown in FIG. 3, the contact point b of the safety switch 24 is connected to the input terminal 41a of the microcomputer 41 through the resistor 43 and at the same time, the microcomputer ( It is connected to the output terminal 41b of 41, and is connected to the grounding conductor provided on the printed wiring board 40 again via the noise prevention capacitor 45, and is grounded. The contact b of the safety switch 25 is connected to the grounding conductor provided on the printed wiring board 40 and grounded.

In this configuration, the microcomputer 41 outputs (applies) a DC constant voltage (for example, a DC voltage of 5 V) at the output terminal 41b, and simultaneously outputs an analog voltage signal input to the input terminal 41a. D conversion and the A / D changed digital voltage signal are input to perform signal processing (e.g., a process of judging a voltage value).

In the above configuration, the microcomputer 41, as shown in Figs. 3 and 1, is turned on between the contacts cb of the safety switches 24 and 25 in the state in which the door 22 of the microwave oven is opened. Ground between the resistor 44, the contact cb of the safety switch 24, the primary winding 34a of the transformer 34, and the contact cb of the safety switch 25 at the output terminal 41b of The conduction path flowing in the furnace is formed.

In the state where the conduction path is formed, the DC voltage applied from the output terminal 41b of the microcomputer 41 is between the resistor 44 and the contact cb of the safety switch 24 and the primary winding 34a of the transformer 34. ) Is divided to the conduction resistance of the conduction path A passing through the contact cb of the safety switch 24. The divided voltage signal is provided to the input terminal 41a of the microcomputer 41. Therefore, the microcomputer 41 can detect the magnitude | size of the electricity supply resistance of the said electricity supply path A by the voltage signal applied to the input terminal 41a.

Here, a case where the safety switches 24 and 25 are broken (contact fusion) will be described. As shown in Fig. 4, for example, when the safety switch 24 is broken, when the door 22 of the microwave oven is opened, the contact between the contacts cb of the safety switch 24 is turned off as it is. The configuration is such that the resistance 44 connected to the output terminal 41b of the computer 41 is disconnected from the ground. In this circuit state, since the DC voltage applied from the output terminal 41b of the microcomputer 41 is divided by the resistor 44 and the infinite resistance, the microcomputer 41 receives the divided voltage signal. It is possible to determine that the conduction resistance of the conduction path A is infinite, that is, at least one of the safety switches 24 and 25 is broken (or the wiring constituting the conduction path A is disconnected). It becomes the structure that I can do.

Moreover, the microcomputer 41 is comprised so that the ON / OFF state of the door switch 29 can be detected. For example, one end of the door switch 29 is grounded and a DC constant voltage is applied to the other end through a resistor, and the connection point between the other end of the door switch 29 and the resistor is input to the input terminal of the microcomputer 41. It is configured to connect to. As a result, the microcomputer 41 is configured to detect whether the door switch 29 is on or off in accordance with the level of the voltage signal applied to the input terminal. The microcomputer 41 is configured to judge that the door 22 of the microwave oven is closed when the door switch 29 is on, and determine that the door 22 is open when the door switch 29 is off. .

Next, the control of judging the action of the above-described configuration, in particular, the failure of the safety switches 24 and 25 will be described with reference to the flowchart shown in FIG. This flowchart of FIG. 5 shows the contents of the control portion for determining the failure of the safety switches 24 and 25 among the control programs stored in the microcomputer 41.

First, in step S1 of FIG. 5, the microcomputer 41 determines whether the door 22 is opened based on detecting the on-off state of the door switch 29. If the door 22 is opened here, the process proceeds to "Yes" in step S1, and the microcomputer 41 performs a predetermined time (for example, a detection operation for detecting a failure of the safety switches 24 and 25). For a few seconds).

Specifically, the process proceeds to step S2, and the microcomputer 41 outputs the DC constant voltage at the output terminal 41b and at the same time, based on the voltage signal received at the input terminal 41a, the energization path A (safety switch ( The resistance of the conduction path between the contact cb of 24) and between the primary winding 34a of the transformer 34 and the contact cb of the safety switch 25 is detected. Subsequently, the microcomputer 41 determines whether the detected resistance value R is infinite (step S3).

When the resistance value R detected here is infinity, it is determined that at least one of the safety switches 24 and 25 is broken (or that the wiring constituting the conduction path A is broken), and the step S3 is performed. In step S4, the first abnormality report is performed (step S4). In this case, as the first abnormality report, for example, "EEEE" is displayed on an indicator (specifically, a seven-segment indicator for time display) of the operation panel, and configured to sound a buzzer. This first abnormality report indicates that at least one of the safety switches 24 and 25 is broken. Next, it progresses to step S5 and it is comprised so that all the subsequent operation | movement operation | movement may be stopped, ie, the heating operation operation | movement is prohibited.

In step S3, if the detected resistance value R is not infinity, the flow advances to NO, and it is determined whether the resistance value R is larger than the predetermined upper limit resistance value Rmax (step S6). )). Here, when the two safety switches 24 and 25 are normal, the resistance value of the conduction path A is almost determined from the resistance value of the primary winding 34a of the transformer 34, and there is an error depending on the product, but the predetermined constant It is a value in the range. On the other hand, when the wear of an electrical component progresses and the consumption of the primary winding 34a of the transformer 34 progresses, for example, the resistance value R of the electricity supply path A is a predetermined range, i.e., the predetermined upper limit resistance value Rmax. Is greater than). Moreover, when the insulation deterioration of an electrical component advances, for example, and the insulation deterioration of the primary winding 34a of the transformer 34 advances, the resistance value R of the electricity supply path A will be the said predetermined range, ie, predetermined lower limit. The value becomes smaller than the resistance value Rmin.

Therefore, when the primary winding 34a of the transformer 34 is exhausted, it progresses to "Yes" in the judgment of the said step S6, and reports a 2nd abnormality (step S7). In this case, as a 2nd abnormal report, it is comprised so that a buzzer may sound simultaneously, for example, displaying "E01" on the display of an operation panel. This second abnormality report indicates that the primary winding 34a of the transformer 34 is being consumed. In this second or more case, even if the heating operation is performed as it is, there is no problem so that the execution of the control routine (inspection operation) for determining the failure of the safety switches 24 and 25 is completed, and the operation returns to the main routine. And a state in which the various operation keys of the operation panel are waited for to be operated.

On the other hand, in step S6, when the resistance value R is not larger than the upper limit resistance value Rmax, it progresses to "No", and it is determined whether the resistance value R is smaller than the lower limit resistance value Rmin (step). (S8)). If the insulation deterioration of the primary winding 34a of the transformer 34 is in progress here, since the resistance value R becomes smaller than the lower limit resistance value Rmin, it progresses to "Yes" in step S8, and it is 3rd or more A report is performed (step S9). In this case, it is comprised so that a buzzer may be sounded as a 3rd abnormality report, for example, displaying "E02" on the display of an operation panel. This third abnormality report indicates that the insulation of the primary winding 34a of the transformer 34 is deteriorated.

Subsequently, even in this third abnormality case, even if the heating operation is performed as it is in the second or more case, there is no problem so that execution of the control routine (inspection operation) for determining the failure of the safety switches 24 and 25 is performed. It is configured to complete and return to the main routine to enter the standby state.

In addition, although it is comprised so that heating operation can be performed when it is determined that it is the said 2nd abnormality and a 3rd abnormality, you may comprise so that all subsequent operation | movement operation | movement may be prohibited instead.

According to the above configuration, however, when either of the two safety switches 24 and 25 has failed, the detection operation is performed when the door 22 is opened and the conduction state between the contact points b of the safety switches 24 and 25 is performed. Specifically, on the basis of detecting the resistance value of the energizing path A, for example, when the detected resistance value is infinite, the failure of the one safety switch 24, 25 (ie, the first abnormal state). You can judge. In this configuration, overcurrent does not flow even if the safety switches 24 and 25 fail, resulting in higher safety. Moreover, since the monitor switch 7 of the conventional structure (refer FIG. 8 and FIG. 9) can be made unnecessary, the lever 13 dedicated to a monitor switch can be made unnecessary, and a structure can be simplified and Product cost can be reduced.

In addition, although the said structure was set as the structure which installed the door switch 29 as a door detection means which detects the opening / closing state of the door 22, this door switch 29 synchronizes with the safety switch 25. Since the switch may be operated, the lever 13 dedicated to the monitor switch can be reliably eliminated. Moreover, since the door switch 29 is normally provided separately from a monitor switch in the microwave oven of a conventional structure, the manufacturing cost does not become high by installation of the door switch 29. FIG. The reason why the door switch 29 is provided in the conventional configuration is for the microcomputer to confirm the opening and closing of the door.

In addition, when the above configuration is determined to be a failure of the safety switches 24 and 25, it is possible to prevent all subsequent operation operations thereafter. Therefore, it is possible to prevent the heating operation from being executed while either of the safety switches has failed. In this case, because the user cannot operate the microwave oven, the microwave oven must be repaired, thereby improving safety.

In addition, the said structure is a structure which judges that it is a 2nd abnormal state (for example, the state in which the primary winding 34a of the transformer 34 was consumed) when the detected resistance value R is larger than the upper limit resistance value Rmax which is a set value. As a result, this second abnormal state can be reported and the user can be sure that the microwave oven has become the second abnormal state. In addition, when the detected resistance value R is smaller than the lower limit resistance Rmin which is a set value, it is set as the structure which judges that it is a 3rd abnormal state (for example, the state in which the primary winding 34a of the transformer 34 deteriorated insulation). It is possible to report this third abnormal condition and the user can be sure that the microwave oven has become the third abnormal condition.

In addition, the above-mentioned structure of the microwave oven is a structure for demonstrating the principle of abnormality detection of a safety switch, and the structure of an actual microwave oven is equipped with the above-mentioned structure, various loads, and the relay which energizes this load. In addition, it is comprised. So, as an actual microwave oven, the specific structure of the microwave oven with a heater is demonstrated, for example with reference to FIG. 6 and FIG. In addition, in the electrical circuit diagram shown in FIG. 6, the same code | symbol is attached | subjected to the component same as the component in the electrical circuit diagram of FIG.

In FIG. 6, the main relay 46 is provided in the power supply line 32 in the transformer 34 side portion rather than the safety switch 25. As shown in FIG. In the microwave oven 47 between the portion of the transformer 34 side of the power supply line 31 than the safety switch 24 and the portion of the power line 32 of the transformer 34 side than the main relay 46. And a RT motor 48 for rotationally driving the turntable are connected in parallel.

In addition, the microwave oven lamp 47 and the motor 48 are connected in parallel between the power supply line 31 and the power supply line 32, and the grill cooking heater 49 and the heater 49 are connected to each other. The electric charge is connected to a series circuit connecting the grill relay 50 in series, and at the same time, a parallel circuit in which the heater 51 for cooking the oven and the hot air fan motor 52 are connected in parallel, and the heater 51 and the motor ( A series circuit for series connection of the oven relay 53 for energizing 52 is connected, and a blower fan motor 54 for blowing air in the heating chamber and a fan motor relay 55 for energizing the motor 54 in series. The series circuit to be connected is connected.

A range relay 56 for energizing and energizing the magnetron is provided at a portion of the power supply line 31 connected to one end of the primary winding 34a of the transformer 34. The main relay 46, the grill relay 50, the oven relay 53, the fan motor relay 55, and the range relay 56 are each controlled by the control circuit 35 (microcomputer 41). It is configured to be controlled on and off. In addition, the RT motor relay for energizing the RT motor 48 is configured to be connected in series with the RT motor 48, and the RT motor relay is turned on and off by the control circuit 35 (microcomputer 41). By controlling the power supply, the RT motor 48 may be controlled independently.

The control circuit 35 is configured to drive control of the indicator 57 provided on the operation panel and to input a switch signal from various operation keys 58 provided on the operation panel. The display unit 57 is composed of an indicator for displaying the current time and cooking time, an indicator for displaying a cooking menu, and the like. In addition, as the various operation keys 58, a cooking menu selection key, a time setting key, a start key and a cancel key are set.

Next, a control (detection operation when the door is opened) for determining the action of the above-described structure, in particular, the failure of the safety switches 24 and 25 and the like will be described with reference to the flowchart shown in FIG. This flowchart of FIG. 7 shows the contents of the control portion for determining the failure of the safety switches 24 and 25 among the control programs stored in the microcomputer 41 of the control circuit 35.

First, in step S101 of FIG. 7, the microcomputer 41 determines whether the door 22 is opened based on detecting the on / off state of the door switch 29. If the door 22 is opened here, the process proceeds to "Yes" in step S101, and the microcomputer 41 detects failures such as safety switches 24 and 25 described below (steps S102 to S102). S113) is configured to be executed at a predetermined predetermined time (for example, 1 to 2 seconds).

Specifically, the process proceeds to step S102, whereby the microcomputer 41 turns on the main relay 46, and then proceeds to step S103, where the microcomputer 41 first fails the safety switches 24, 25. The detection process is performed. This detection process is performed in the same manner as the process of steps S2 and S3 described above. Specifically, when the conduction resistance between the contacts b of the safety switches 24 and 25 is detected, and the detected resistance value is infinite, it is determined that at least one of the safety switches 24 and 25 is broken. The microcomputer 41 stores the determination result.

Subsequently, the process proceeds to step S104 and a check (detection) of whether the microwave oven lamp (lamp) 47 and the RT motor 48 is consumed or deteriorated is performed based on the detected resistance value. This detection process is performed similarly to the process of step S6 and S8 mentioned above. That is, the microcomputer 41 judges that if the detected resistance value R is larger than the upper limit set value Rmax1, it is the second abnormality (consumption of the microwave oven lamp 47 and the RT motor 48, which are electrical components). If the resistance value R is smaller than the lower limit set value Rmin1, it is determined that it is the third abnormality (deterioration of insulation of the electrical component), and the determination result is stored.

Thereafter, after turning off the main relay 46, the process proceeds to step S105, and the microcomputer 41 turns on the main relay 46 and the grill relay 50, and then proceeds to step S106, and the microcomputer. Reference numeral 41 performs a process of checking (detecting) whether the grill cooking heater 49 is consumed or whether the insulation deteriorates. This detection processing is performed in the same manner as the processing in the above-described steps S6 and S8. That is, the microcomputer 41 detects the energization resistance between the contacts b of the safety switches 24 and 25, and if the detected resistance value R is larger than the upper limit set value Rmax2, the second abnormality (electric If it is determined that the heater 49, which is a component, is consumed and the resistance value R is smaller than the lower limit set value Rmin2, it is determined to be the third abnormality (deterioration of insulation of the heater 49), and the determination result is stored.

Then, after turning off the main relay 46 and the grill relay 50, it progresses to step S107 and the microcomputer 41 turns on the main relay 46 and the oven relay 53, and continues step S108. The microcomputer 41 executes a process of checking (detecting) whether or not the heater 51 and the motor 52 for oven cooking or the insulation deterioration are present. This detection process is performed similarly to the process of step S6 and S8 mentioned above. That is, the microcomputer 41 detects the conduction resistance between the contacts b of the safety switches 24 and 25, and if the detected resistance value R is larger than the upper limit set value Rmax3, the second abnormality (electric If the resistance value R is smaller than the lower limit set value Rmin3, it is determined to be the third abnormality (deterioration of insulation of the electrical component) and the result of the determination is stored. .

Then, after turning off the main relay 46 and the oven relay 53, the process proceeds to step S109, and the microcomputer 41 turns on the main relay 46 and the range relay 56 and continues to step S110. The microcomputer 41 executes a process of checking (detecting) whether the primary winding 34a of the transformer 34 for range cooking is consumed or whether the insulation deteriorates. This detection processing is performed in the same manner as the processing in the above-described steps S6 and S8. That is, the microcomputer 41 detects the energization resistance between the contacts b of the safety switches 24 and 25, and if the detected resistance value R is larger than the upper limit set value Rmax, the second abnormality (electric If the resistance value R is smaller than the lower limit set value Rmin, it is determined to be the third abnormality (deterioration of insulation of the electrical component), and the determination result is stored.

Thereafter, the main relay 46 and the range relay 56 are turned off, and the flow proceeds to step S111, and the microcomputer 41 turns on the main relay 46 and the fan motor relay 55 and continues with the step S112. The microcomputer 41 executes a process of checking (detecting) whether the fan motor 54 is exhausted or whether the insulation deteriorates. This detection process is performed similarly to the process of step S6 and S8 mentioned above. That is, the microcomputer 41 detects the energization resistance between the contacts b of the safety switches 24 and 25, and if the detected resistance value R is larger than the upper limit set value Rmax4, the second abnormality (electric If the resistance value R is smaller than the lower limit set value Rmin4, it is determined to be the third abnormality (deterioration of insulation of the electrical component), and the determination result is stored.

Subsequently, after turning off the main relay 46 and the fan motor relay 55, the process proceeds to step S113, where the microcomputer 41 stores one or more kinds of abnormalities as a result of the stored judgment. One or more kinds of abnormalities are configured to be displayed on the display unit 57. When the safety switches 24 and 25 fail, all the subsequent operation operations are stopped, that is, the heating operation operation is prohibited. In this case, when abnormality other than the failure of the safety switches 24 and 25 is detected, the control routine for determining the failure of the safety switches 24 and 25 is not performed even if the heating operation is performed as it is. Operation) and return to the main routine to be ready for operation. Moreover, you may comprise so that all the operation | movement operation | movement after this may also be stopped, when the abnormality other than the failure of the safety switches 24 and 25 is detected.

According to this embodiment of such a configuration, it is possible to obtain an operation effect such that the detection operation can be obtained by the configuration for principle explanation. In particular, in the above embodiment, abnormalities and failures of a plurality of electrical parts that are a plurality of loads can be easily determined by turning on a plurality of relays in sequence. In addition, in the above embodiment, since the safety checks 24 and 25 and the failure checking operations of the plurality of electrical components are configured in about 1 to 2 seconds, if the two safety switches 24 and 25 fail together, each contact point is broken. Even if (ca) is on, it takes about 3 seconds for the magnetron to start oscillation, so that the check operation can be completed before the magnetron starts oscillation, thereby ensuring sufficient safety.

In the above embodiment, the failure detection of the safety switches 24 and 25 and the failure detection of a plurality of electrical parts are performed when the door 22 is opened, but instead the door 22 is opened. The failure detection of the safety switches 24 and 25 may be executed, and the failure detection of a plurality of electrical parts may be configured to be executed when the operation keys of the operation panel are operated in a predetermined special operation while the door 22 is open. In this way, since the driving sound of the relay hardly occurs when the door 22 is opened, the ear trouble is eliminated. In addition, the detection method of starting the failure detection operation of a plurality of electrical parts by special operation of the operation key can be used as one of the diagnostic methods when the serviceman repairs the microwave oven.

Further, in the embodiment, the faults of the safety switches 24 and 25 are detected, and then the fault detection of the plurality of electrical components is continuously performed. However, the faults of the safety switches 24 and 25 are not limited thereto. If so, the operation may be stopped there so that failure detection of a plurality of electrical components is not executed. In addition, in the said embodiment, although the failure of safety switches 24 and 25 was detected when the door 22 was opened, it is not limited to this, For example, in the state in which the door 22 is open, The failure detection operation such as the safety switches 24 and 25 may be performed on the condition that a predetermined operation key is operated among the operation keys of the operation panel. In the above embodiment, two safety switches 24 and 25 are provided in the power supply lines 31 and 32, but three or more safety switches may be provided instead. In this case, it is particularly preferable to configure two or more safety switches in one power line.

As can be seen from the above description, the door has switch detection means for detecting the conduction state between the open side contacts when the door is connected to the common contact of the at least two safety switches when the door is opened. At the same time, the switch detecting means has a control means for executing the detecting operation when the door is open. Thus, overcurrent can be prevented when the safety switch fails, and one of the two safety switches There is an excellent effect that it is possible to determine that the failure has occurred, and that the configuration can be simplified and the product cost can be reduced.

Claims (8)

A door for opening and closing the opening of the heating chamber; At least two safety switches installed so as to cut off the positive poles of the power lines, respectively, and operating in a switch according to opening and closing of the door; Switch detection means for detecting a conduction state between the side contacts (b) at which the doors are connected to the open side contacts (b) connected to the common contact (c) of the respective safety switches when the doors are opened; Door detecting means for detecting an open / closed state of the door; And And a control means for causing the switch detecting means to perform a detecting operation when the door is opened. The method of claim 1, And the control means causes the switch detecting means to perform a predetermined time detecting operation at the time when the door is opened. The method according to claim 1 or 2, And the control means reports an abnormality when it is determined that the abnormality is determined by the switch detecting means, and prohibits the heating operation operation. The method according to claim 1 or 2, And the switch detecting means is configured to detect a resistance between the contacts of the open side of the two safety switches, and determines that the safety switch is broken when the detected resistance value is infinite. The method of claim 4, wherein And said switch detecting means judges that it is said second abnormal state when the detected resistance value is larger than the set value. The method of claim 4, wherein And said switch detecting means judges that it is a third abnormal state when the detected resistance value is smaller than a set value. The method according to claim 1 or 2, A plurality of loads and a plurality of relays for turning on and off each load are provided between the power lines, And said switch detecting means determines the failure of each load by sequentially turning on said plurality of relays. The method of claim 7, wherein And the control means causes the switch detecting means to perform the detecting operation when the operation key of the operation panel is specially operated while the door is opened.

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