JP3739199B2 - Electronic or electrical equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electronic device or an electric device such as an AV device or a washing machine provided with a power supply control circuit.
[0002]
[Prior art]
Conventionally, as a power supply control device for a washing machine, a technique as disclosed in Japanese Patent No. 2523798 is known. This is because when the power plug is inserted into the outlet, the AC power supply is connected to the control circuit and the control circuit is in an operating state, and then the relay contact provided between the load circuit and the AC power supply is closed by an operation start instruction, AC power is supplied.
[0003]
When the automatic power-off at the end of operation or the power-off is instructed by the user, the relay contact is opened by the control circuit and the supply of AC power to the load circuit is cut off, but the power plug is connected to the control circuit. It is configured to continue to supply AC power unless it is unplugged.
[0004]
In the power supply control device, AC power is supplied to the control circuit even during standby when the power is turned off, for example, after the operation is completed. In recent years, electric appliances such as washing machines in general households have built-in microcomputers. These devices generate standby power with power consumption just by being connected to a power supply, and the total is a value that cannot be ignored. It is coming. Considering the future shortage of power supply, it is necessary to reduce the standby power as described above in order to reduce energy consumption.
[0005]
In consideration of the above problems, a power supply control device that cuts off power supply to a load circuit such as a washing motor and a control circuit that controls the load circuit when the washing machine is on standby to reduce power consumption is disclosed in Japanese Patent Application No. No. 9-051379. A block diagram of the power supply control device disclosed here is shown in FIG.
[0006]
In FIG. 7, only the circuit portion related to the control for reducing the power consumption during standby to zero will be described. In this circuit, when the power switch 3 composed of a normally open push switch is pressed, the power switch 3 is closed and the AC power supply 4 is connected to the control circuit 2. Therefore, the control circuit 2 is in an operating state. When the control circuit 2 starts operating, the power relay contact 5 is closed and the power switch 3 returns to the open state when the pressing of the power switch 3 is stopped (a finger is released).
[0007]
When all steps of the operation by the control circuit 2 are completed, or when the power switch 3 is pressed during the operation of the control circuit 2, the load relay contact 5 is opened after the load operation is stopped. When the pressing is stopped, the power switch 3 returns to the open state. Thus, since all the circuits are cut off from the AC power supply 4 after the washing operation is completed, the power consumption during standby becomes zero.
[0008]
[Problems to be solved by the invention]
However, in the power supply control device disclosed in Japanese Patent Application No. 9-051379, the operation noise is generated when the power relay contact 5 is closed and opened, so that it is not quiet. In addition, when a reservation timer that is left for a predetermined time after the power is turned on (after the control circuit 2 is in an operating state) is used, the power relay 5 is closed in order to keep the control circuit 2 in an operating state. Need to keep on. Therefore, in this case, power continues to be consumed during standby.
[0009]
In view of the above problems, the present invention eliminates power consumption during standby and eliminates operation noise generated by the power relay when the power switch is operated and when the load circuit is finished in an electronic or electrical device such as a washing machine. With the goal. Furthermore, it aims at reducing the power consumption at the time of reservation standby.
[0010]
[Means for Solving the Problems]
In order to achieve the above object, according to the present invention , a first circuit, a second circuit, and a power supply are connected in series, and the first circuit is a load circuit of an electronic or electric device body and a control means for controlling the load circuit. The second circuit is a parallel circuit of a power switch means made of a normally open push switch and a first switching element made of a semiconductor element, and the connection between the first circuit and the power supply In an electronic or electric device which is a circuit for switching off , the first switching element and the power switch means connect the first circuit and the power supply when in the closed state, and the control means is the power switch as well as open and close switches the first switching element in response to the operation of the unit, further to the second circuit second consisting a small semiconductor device having current-carrying capacity than the first switching element 2 Switching elements are arranged in parallel, and when the second switching element is in a closed state, the first circuit and the power source are connected, and the control means responds to the operation of the power switch means. When both switching elements are in the open state, the second switching element is first closed and when the load circuit is operated, the first switching element is closed and then the second switching element is opened. When at least one of the switching elements is in a closed state, the closed switching element is in an open state .
[0011]
In the above configuration, when the control means is not energized, that is, when both the switching element and the switch are open, when the power switch means is closed, that is, pressed (operated), the power supply and the control means are connected, and the control means The means becomes operational. When the control means starts operation, the control means closes the first switching element (ON), and even if the power switch means returns to the opened state, the power is supplied to the control means via the first switching element. It is connected. The first switching element maintains the ON state until a signal for turning OFF is generated from the control means. Therefore, even if the power switch means is once closed and then opened, the control means can maintain the operation and operate the load circuit.
[0012]
When the power switch means is pressed during the operation of the control means, the control means outputs a signal for opening (OFF) the first switching element, and turns off the first switching element. In the above operation, since the switching element is made of a semiconductor element, unpleasant mechanical noise associated with the opening / closing operation of the switching element does not occur.
[0014]
When the power switch means is operated in the open state, that is, when the control means is not energized, the power supply and the control means are connected and the control means is in the operating state. When the control means starts operation, the second switching element is first closed, so that the power source is connected to the control means via the second switching element even if the power switch means returns to the open state. At this time, since the load circuit is not operating, the energization capacity of the second switching element is small, and the current for controlling this is small. For example , when waiting for reservation of the load circuit operation in a state where only the second switching element is closed, the power consumption is reduced as described above.
[0015]
When the load circuit operates, the control means closes the first switching element having a capacity corresponding to the load such as a motor and opens the second switching element. In this state, the load circuit can be operated.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0018]
(Embodiment 1)
FIG. 1 is a block diagram of Embodiment 1 in which the present invention is applied to a washing machine, and portions corresponding to the conventional example shown in FIG. In FIG. 1, a first circuit composed of a load circuit 1 and a control circuit 2, a second circuit composed of a first semiconductor switching element 16 and a power switch 3, and an AC power source 4 are connected in series. In the first circuit, the load circuit 1 and the control circuit 2 are connected in parallel, and in the second circuit, the first semiconductor switching element 16 and the power switch 3 are connected in parallel.
[0019]
The load circuit 1 includes a load 10 including a drain valve 7, a water supply valve 8, and a washing machine motor 9, and a load control element group 11 that controls the load 10. In the figure, 12 is a control instruction device for instructing the control circuit 2 of the control state of the load 10, 13 is a display device for displaying the control state of the washing machine instructed by the control instruction device 12, and 14 is a power switch. 3 is a detection circuit for detecting an open / closed state 3, and 17 is a first semiconductor switching element control circuit for controlling ON / OFF of the first semiconductor switching element 16 by a control signal from the control circuit 2. The control circuit 2, the control instruction device 12, the display device 13, the power switch open / close detection circuit 14, and the first semiconductor switching element control circuit 17 are collectively referred to as control means.
[0020]
According to the configuration shown in FIG. 1, when the power switch 3 comprising a normally open push switch is pressed, the power switch 3 is closed and the AC power supply 4 and the control circuit 2 are connected to bring the control circuit 2 into an operating state. To do. When the operation starts, the control circuit 2 supplies a signal to the first semiconductor switching element control circuit 17 so as to output a control current so as to turn on the first semiconductor switching element 16. Then, the first semiconductor switching element 16 is turned on.
[0021]
When the first semiconductor switching element 16 is turned on, the pressing of the power switch 3 is released, and even if the power switch 3 returns to the open state, the control circuit 2 and the load circuit 1 are connected via the first semiconductor switching element 16. AC power supply 4 is supplied. The ON state of the first semiconductor switching element 16 as described above is self-maintained until a signal for turning off the first semiconductor switching element 16 is output from the control circuit 2 to the first semiconductor switching element control circuit 17. Is done.
[0022]
Therefore, once the power switch 3 is closed, the control circuit 2 can maintain the operating state even if it is opened thereafter. The control circuit 2 controls the load circuit control element group 11 to operate the load 10 and enables input from the control instruction device 12 and output to the display device 13 so that a series of washing machine operations can be performed. Become.
[0023]
For example, a series of washing operations such as washing, rinsing, and dehydration are started and executed by the input from the control instruction device 12, and when all the steps are completed, the control circuit 2 sends the first semiconductor switching element control circuit 17 to the first semiconductor switching element control circuit 17. A signal is output to turn off the first semiconductor switching element 16. Then, the first semiconductor switching element 16 is turned off. Thereby, AC power supply 4 is interrupted by control circuit 2 and load circuit 1, and a series of washing operations are completed. And after this washing operation is completed, the power consumption of the washing machine can be made zero.
[0024]
When the power switch 3 is closed during the operation of the control circuit 2, the detection circuit 14 that detects opening / closing of the power switch 3 detects this and transmits a detection signal to the control circuit 2. The control circuit 2 receives the detection signal, stops the load circuit if it is in operation, and then outputs a signal to the first semiconductor switching element control circuit 17 to turn off the first semiconductor switching element 16. To do. Then, the first semiconductor switching element 16 is turned off.
[0025]
When the first semiconductor switching element 16 is turned off, the control circuit 2 and the load circuit 1 are disconnected from the AC power supply 4, and the power consumption of the washing machine becomes zero. As described above, since the switching element 16 of the present embodiment is made of a semiconductor element, no unpleasant mechanical sound is generated in the switching operation of the switching element.
[0026]
FIG. 2 is a flowchart of this embodiment. Hereinafter, this flowchart will be described. When the power switch 3 is pressed in step S1, the control circuit 2 starts operating in step S2, and the first semiconductor switching element 16 is turned on in step S3. Next, in step S4, it is determined whether the power switch 3 is opened or closed. If the power switch 3 is closed, the process returns to the step of waiting for the opening signal. If it is opened, the process proceeds to the next step S5, and if the power switch 3 is open, the process proceeds to step S6. Wait for process instructions.
[0027]
When the closing signal indicating that the power switch 3 is closed is input in step S5, the process proceeds to step S13 to wait for the opening signal. If the opening signal is input, the first semiconductor is detected in step S10. The switching element 16 is turned off. When an instruction to start the washing process is given by the control device 12 in step S6, the process proceeds to step S7 where a series of processes is started. When a reservation operation for starting operation after a certain time has been instructed, the process proceeds to step S7 after a certain time has elapsed.
[0028]
When a closing signal for closing the power switch 3 is input during the washing process in step S8, the control circuit 2 first stops the load circuit 10 by controlling the load circuit element group 11 in step S12. Then, in step S13, the process waits for an opening signal indicating that the power switch 3 is opened. When this opening signal is input, the first semiconductor switching element 16 is turned off in step S10.
[0029]
When it is detected in step S8 that the power switch is opened, the process proceeds to the next step S9, and it is determined whether or not the washing process is completed. If the washing process has not ended, the process returns to step S8. When the washing process is completed, the process proceeds to step S10 and the first semiconductor switching element 16 is turned off.
[0030]
(Embodiment 2)
FIG. 3 is a block diagram of the second embodiment in which the present invention is applied to a washing machine. Parts corresponding to those in FIG. A difference of the present embodiment from the first embodiment is that a second semiconductor switching element 18 having a smaller current carrying capacity than the first semiconductor switching element 16 is connected in parallel to the first semiconductor switching element 16, and further the second The second semiconductor switching element control circuit 19 for supplying a control current to the semiconductor switching element 18 is configured as a control means.
[0031]
When the first semiconductor switching element 16 and the second semiconductor switching element 18 are both OFF, that is, when the control circuit 2 and the load circuit 1 are disconnected from the AC power supply 4, the power switch 3 is pressed and closed, as described above. Then, the control circuit 2 starts operation. When the operation starts, the control circuit 2 supplies a signal to the second semiconductor switching element control circuit 19 to turn on the second semiconductor switching element 18. Then, the second semiconductor switching element 18 is turned on.
[0032]
The control circuit 2 self-holds the ON state of the second semiconductor switching element 18. Since the second semiconductor switching element 18 is not turned on when the load circuit 1 is operated, the energizing current rating is small, and the current for controlling it is also small.
[0033]
When a series of washing operations such as washing, rinsing, and dehydration are started by an input from the control instruction device 12, the control circuit 2 firstly has the rated first semiconductor switching element 16 corresponding to the current of the load 10. A signal is output to the first semiconductor switching element control circuit 17 to turn ON the first semiconductor switching element 16. Next, a signal is output to the second semiconductor switching element control circuit 19 to turn off the second semiconductor switching element 18, and the second semiconductor switching element 18 is turned off.
[0034]
As a result, the control circuit 2 self-holds the operation state via the first semiconductor switching element 16 and controls the load circuit control element group 11 to operate the load 10 to perform a series of washing operations. With the configuration as described above, in the present embodiment, in addition to the effects of the first embodiment, for example, the control current of the semiconductor switching element during the reserved operation standby where the washing operation is started after a certain time has elapsed can be reduced, and the power consumption can be reduced. Can be reduced.
[0035]
FIG. 4 is a flowchart of this embodiment. Only the differences from FIG. 2 will be described. When the control circuit 2 starts operating in step S2, the second semiconductor switching element 18 is turned on in step S31. When an instruction to start the washing process is given in step S6, the first semiconductor switching element 16 is turned on in step S61, the second semiconductor switching element 18 is turned off in step S62, and the process proceeds to the washing process in step S7.
[0036]
In addition, when the reservation driving | operation which starts the driving | operation after progress for a fixed time is instruct | indicated in step S6, it transfers to step S61 after progress for a fixed time. If it is determined in step S9 that the washing process has been completed, the first semiconductor switching element 16 in the ON state is turned off in step S11. When the power switch is opened in step S15, in step S11, one of the first semiconductor switching element 16 and the second semiconductor switching element 18 is turned off.
[0037]
(Embodiment 3)
FIG. 5 is a block diagram of a third embodiment in which the present invention is applied to a washing machine. Parts corresponding to those in FIG. In the present embodiment, as the first semiconductor switching element 16 and the first semiconductor switching element control circuit 17 in the first embodiment, a triac 16a and a gate drive circuit 17a that specifically drives the gate of the triac 16a are used. Yes. Other configurations are the same as those in the first embodiment.
[0038]
If the power switch 3 is pressed and closed in a state where the gate is turned off by the gate drive circuit 17a, that is, the control circuit 2 and the load circuit 1 are disconnected from the AC power supply 4, the control circuit 2 operates as described above. Start. When the control circuit 2 starts operation, it supplies a signal to the gate drive circuit 17a to turn on the triac 16a, and the triac 16a is turned on. The control circuit 2 self-holds the ON state of the triac 16a.
[0039]
Note that the control circuit 2 drives the gate to be turned on with the zero point of the AC power supply 4 current sandwiched between them in order to hold the triac 16a in the ON state. The timing chart of the gate drive circuit 17a is illustrated. FIG. 6A is a waveform diagram of the power supply current. At this time, the timing of gate drive by the gate drive circuit 17a is set as shown in the waveform diagram of FIG. 6B, for example. By driving the gate in this way, the triac 16a is kept on without being turned off.
[0040]
In this embodiment, since the gate is driven with a pulse, the power consumption for holding the triac 16a in the ON state is reduced. Of course, this also reduces power consumption during reserved operation standby. Since other control methods are the same as those in the first embodiment, description thereof is omitted.
[0041]
The above description is about the case where the present invention is applied to a washing machine, but the present invention can be applied not only to general electric devices but also to electronic devices such as AV devices. In the embodiment, an AC power source is used as the power source, but a DC power source can be similarly applied.
[0042]
【The invention's effect】
Since the present invention has the above configuration, when the power is turned on, the control means is energized through the power switch, and thereafter, the energization is held by the semiconductor switching element controlled by the control means, and the semiconductor is operated when the operation of the load is completed or interrupted. Since the switching element is turned off and all power to the load and the control means is cut off, the standby power can be reduced to zero, and since mechanical contacts are not used for the semiconductor switching element, unpleasant mechanical noise is generated when opening and closing. Does not occur.
[0043]
Also, if the load is not in operation, so it holds the operating state of the control means with a small semiconductor switching element with electric current rating, the control current of the semiconductor switching element can be reduced, when the load is not operating for example constant It is possible to reduce power consumption during standby operation for which the washing process starts after a lapse of time.
[Brief description of the drawings]
FIG. 1 is a block diagram of a first embodiment.
FIG. 2 is a flowchart according to the first embodiment.
FIG. 3 is a block diagram of a second embodiment.
FIG. 4 is a flowchart according to the second embodiment.
FIG. 5 is a block diagram of a third embodiment.
FIG. 6 is a waveform diagram for explaining the third embodiment.
FIG. 7 is a block diagram of a conventional example.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Load circuit 2 Control circuit 3 Power switch 4 AC power supply 5 Power relay contact 7 Drain valve 8 Water supply valve 9 Motor 10 Load 11 Load control element group 12 Control instruction device 13 Display device 14 Power switch open / close detection circuit 15 Power relay control coil 16 First semiconductor switching element 17 First semiconductor switching element control circuit 18 Second semiconductor switching element 19 Second semiconductor switching element control circuit 16a Triac 17a Gate drive circuit

Claims (2)

A first circuit, a second circuit, and a power source are connected in series. The first circuit is a parallel circuit of a load circuit of an electronic or electric device body and a control means for controlling the load circuit, and the second circuit is In an electronic or electrical device that is a parallel circuit of a power switch means composed of a normally open push switch and a first switching element composed of a semiconductor element and is a circuit that switches connection / disconnection between the first circuit and the power source ,
The first switching element and the power switch means connect the first circuit and the power source when in the closed state, and the control means responds to the operation of the power switch means. along with the opening and closing switch the,
Further, the second circuit is arranged in parallel with a second switching element made of a semiconductor element having a smaller current carrying capacity than the first switching element. When the second switching element is in a closed state, The circuit is connected to the power source, and the control means first closes the second switching element when all the switching elements are open in response to the operation of the power switch means. Is operated, the first switching element is closed and then the second switching element is opened. When at least one switching element is closed, the closed switching element is opened. Electronic or electrical equipment characterized by that. 2. The electronic or electrical device according to claim 1 , wherein the second switching element is in a closed state and the first switching element is in an open state at the time of reservation waiting for the operation of the load circuit.

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