JP2555008B2 - Timer-circuit - Google Patents

Description

Description: TECHNICAL FIELD The present invention uses a battery power source to extinguish a petroleum stove, for example, and then rotates a fan motor for a certain period of time to absorb a dull odor that is generated, or in an OHP (overhead projector). The present invention relates to a timer circuit for rotating another load for a certain period after use of an apparatus, such as rotating a fan motor for a certain period for cooling a heater after use.

[Background Art] When an oil stove is extinguished, an innocent odor is generated due to incomplete combustion. In order to prevent this odor from being generated outside, it is necessary to suck it inside by a fan motor and cool the wick quickly. Here, a timer circuit for rotating the fan motor for about 1 minute after extinguishing the fire and then stopping the fan motor is required. Conventionally, a timer circuit as shown in FIG. 5 has been used. That is, a switch 42 that is switched and connected according to ignition and extinguishing, an integrating circuit 47 for timer operation, a reset circuit 4
6. A timer circuit is composed of two comparators 48, 49 and the like. By controlling the power supply of the timer circuit with the switching means 50 and controlling the power supply of the motor 43 with the switching means 51, the motor 43 is rotated for a certain period and then stopped, and at the same time, the power supply of the timer circuit is turned off to reduce current consumption. ing. A series circuit of an ignition heater 44 and an ignition switch 45 is connected to the battery 41 in parallel. In this timer circuit, the normally closed terminal NC of the switch 42 is on the fire extinguishing side, and when the battery 41 is newly inserted, the switching means 50 is turned on due to an instantaneous voltage fluctuation caused by inserting the battery 41. At that time, since the integrating circuit 47 is in the reset state,
Since the comparator 49 operates, the switching means 51 is turned on, the motor 43 rotates, and the motor 43 stops after a certain period of time, a malfunction occurs, which causes a problem that the current consumption increases and the user is unnecessarily confused. Also, when the switch 42 is on the normally open terminal NO side (during ignition combustion), the motor
Since it is necessary to keep the switching means 50 in the ON state without turning 43, the comparator 48 is required. Therefore, two comparators 48 and 49 are required, which complicates the circuit and increases the cost. There is.

[Object of the Invention] The present invention has been provided in view of the above points, and provides a timer circuit having a simple circuit configuration and for preventing malfunction of a load such as a motor. .

DISCLOSURE OF THE INVENTION (Structure) The present invention, as shown in FIG.
When the switch 18 connected to 16 and the normally closed terminal NC of one of the switches 18 are connected, and the other normally open terminal NO is connected to the normally closed terminal NC for a predetermined time from the reset state A constant circuit 21, first switching means 22 for detecting the output of the time constant circuit 21, and second switching means 23 for receiving the output of the first switching means 22 to drive and control the load of the motor 7 and the like. , The switch 18
The time-constant circuit 21 is reset by the output of the normally-opened terminal connected by switching, and the output of the first switching means 22 is maintained by the output of the first switching means 22. And a third switching means 24 for completely turning off the first switching means 22.

(Example) Hereinafter, the Example of this invention is described with reference to drawings. The timer circuit will be described using an oil stove as an example. Third
The figure shows a perspective view of an oil stove, and FIG. 4 shows a sectional view. When the ignition combustion lever 2 for ignition is pushed, the combustion core 15 in the combustion cylinder 1 is raised by the operation block 6 interlocked with this lever 2, and the combustion core position detection switch 18 installed in the operation block 6 is normally operated. Open terminal NO side. When the lever 2 is pushed to the lowest stage, the ignition switch 17 in the operation block 6 is turned on, electric power is supplied from the battery 16 to the ignition heater 5 to generate heat, and the combustion wick 15 is sucked up.
Set fire to 14. When the lever 2 is released after ignition, the lever 2 is stopped by high heat and the ignition switch 17 is turned off. The fire of the combustion wick 15 causes the combustion heater 4 to generate heat, and radiates heat to the front of the oil stove. Next, when the fire extinguisher switch 3 is pressed, the combustion core 15 falls to the fire extinguishing position by the operation block 6 to extinguish the fire, and the detection switch 18 enters the normally closed terminal NC side, and the timer circuit (Fig. 4) 8 operates, The motor 7 is driven to rotate the fan 9. By rotating the fan 9, the fuel tank 13
Combustion wick through air layer and combustion wick 15 above fuel 14 in
Smelling odor such as sulfur oxide around 15 is sucked from the suction port 10 and returned to the fuel tank 13 from the exhaust port 11. Since the fuel tank 13 is provided with the partition plate 12 between the intake port 10 and the exhaust port 11, the air layers in the fuel tank 13 are separated. Further, since the fuel core 15 is quickly cooled together with the odor, it is effective in suppressing the generation of odor. About 1 minute after extinguishing the fire, the timer circuit 8 operates to stop the motor 7.

A block diagram of the timer circuit 8 of the present invention is shown in FIG. 1, and a concrete circuit diagram is shown in FIG. That is, the battery 16 is connected to the common terminal C of the detection switch 18, and the normally closed terminal
Time constant circuit of CR through diode D for temperature compensation in NC
21 and a first switching means 22 for detecting the output voltage of the time constant circuit 21 are connected. Further, the output of the switching means 22 is input to the second switching means 23 inserted in series with the motor 7, and
It is input to the OR circuit 25 together with the normally open terminal NO output of the detection switch 18. The output of this OR circuit 25 is the time constant circuit 21.
Is input to the third switching means 24 which also serves as a reset input of the above and an ON drive of the first switching means 22. On the other hand, the ignition heater 5 and the ignition switch 17 are connected in series to the normally open terminal NO of the detection switch 18.

Next, the operation will be described. First, the combustion core position detection switch
When 18 is on the normally closed terminal NC side, that is, when a new battery 16 is attached in a fire extinguishing state, the power supply voltage V _CC of the battery 16 drops through the diode D and the forward voltage V _D of the diode D decreases. It is supplied to the base of the transistor Q ₂ via the capacitor C ₁ . Here, the threshold voltage V _BE of the transistor Q ₂ is V _BE ≈ V _D (≈ 0.6 V)
The base-emitter Q ₂ 'is applied voltage higher than the voltage the transistor Q ₂ is turned on, therefore, the transistor
Motor 7 is not rotated to Q _3, Q ₄ are turned off. Since the transistor Q _{1 is} also off, the transistor Q ₂ is immediately turned off, and the current from the battery 16 flows through the diode D, the resistor R ₃ and the capacitor C ₂ , and the capacitor C ₂ is charged.

When the ignition combustion lever 2 is in the ignition position, the detection switch
18 is switched to the normally open terminal NO side, the ignition switch 17 is also turned on, the electric power is supplied to the ignition heater 5, and the voltage divided by the resistors R ₁ and R ₂ becomes the base of the transistor Q ₁ . Transistor Q ₁ turns on. The electric charge of the capacitor C ₂ is instantly discharged through the transistor Q ₁ , the capacitor C ₁ is charged through the transistor Q ₂ and the resistor R ₃ (about V _CC −V _BE ), and the transistor Q ₂ is turned on. , The transistors Q ₃ and Q ₄ are turned off, and the motor 7 remains stopped. This state is the state in which the time constant circuit 21 is reset. When the combustion wick 15 is ignited, the lever 2 stops at the combustion position, the ignition switch 17 is turned off, the detection switch 18 remains at the position of the normally open terminal NO side, and the timer circuit remains inactive.

Next, when the fire extinguishing switch 3 is pressed to extinguish the fire, the detection switch 18 is in the position of the normally closed terminal NC, and when the power supply voltage V _CC is passed to the capacitor C ₁ through the diode D, the base voltage of the transistor Q ₂ becomes the capacitor C 2. ₁ charge voltage (V _CC
−V _BE ) and the voltage applied from the diode D (V _CC −V _D ), and since V _BE ≈V _D , 2 (V _CC −V _BE ). Therefore, transistor Q ₂ turns off instantly, and transistor Q ₃
Is turned on, the transistors Q ₁ and Q ₄ are turned on and the motor 7 rotates. The charge voltage of the capacitor C ₁ is discharged through the resistor R ₄ with the time constant of C ₁ R ₄ . Transistor
Since the threshold voltage of Q ₂ is (V _CC −V _BE ), the time t until the transistor Q ₂ turns on is given by the following equation.

∴t = C ₁ R ₄ ln2 Therefore, it is constant regardless of the voltage V _{CC of the} battery 16. In addition, since V _D and V _BE are the same PN junction ON voltage and therefore have the same voltage, and since the temperature characteristics are the same, the time t is constant regardless of the temperature. Accordingly, the base voltage of the transistor Q ₂ after a time t seconds reaches the threshold voltage, the transistor Q ₃ to the transistor Q ₂ is turned off, the motor 7 to be turned off the transistor Q ₄ are stopped. That is, the motor 7 rotates for a fixed time regardless of the voltage V _{CC of the} battery 16 and the ambient temperature. Further, since the transistor Q ₁ is also turned off when the transistor Q ₃ is turned off, the capacitor C ₂ is charged and the transistor Q ₂ is also turned off. Therefore, after the motor 7 is stopped, all the transistors are turned off. Only the leakage current of the transistor is almost eliminated, and it is a power saving design. In this way, the timer circuit is reset only when the normally open terminal NO side (ignition, combustion side) of the detection switch 18 is set, and the timer circuit does not work unless it is reset with the battery 16 inserted. Therefore, the timer circuit works when a new battery 16 is inserted,
The malfunction that the motor 7 rotates does not occur. Further, since the power supply control and reset of the time constant circuit 21 and the switching means 22 can be shared by the OR circuit 25 and the switching means 24, the configuration is simplified, the number of parts is reduced, and the cost is reduced. The capacitor C ₂ is for reliably turning on the transistor Q ₃ when the detection switch 18 is switched from the normally open terminal NO side to the normally closed terminal NC side, and the emitter of the transistor Q ₃ is the detection switch 18 side.
The normally closed terminal of is connected to the detection switch 18
This is to ensure that the transistor Q ₃ is turned off and the motor 7 is not rotated when is on the normally open terminal NO side. Further, the capacitor C ₃ is for absorbing the noise of the motor 7. In addition, by inserting the diode D between the normally closed terminal NC of the detection switch 18 and the time constant circuit 21, the temperature characteristic of the threshold level of the transistor Q ₂ can be compensated, and the rotation time of the motor 7 does not depend on the ambient temperature. It is possible to achieve a timer circuit with a good system in which is constant.

[Effects of the Invention] As described above, the present invention connects a switch in which a common terminal is connected to a battery power source, is connected to one normally closed terminal of the switch, and is connected from the other normally open terminal to the normally closed terminal. The time constant circuit that operates for a predetermined time from the reset state, the first switching unit that detects the output of the time constant circuit, and the output of the first switching unit that controls the drive of a load such as a motor The time constant circuit is reset by the second switching means and the normally open terminal output of the switch that is switched and connected, and the output of the first switching means is maintained by the output of the first switching means, and at the same time, a predetermined value is maintained. After the time operation, it is composed of the third switching means for completely turning off the first switching means, so that the battery power source is connected. The time constant circuit is not reset unless the switch is switched from the normally open terminal to the normally closed terminal in this state, so even if a momentary voltage change occurs when a new battery is inserted, the time constant circuit does not operate, unlike the conventional case. Therefore, the first and second switching means are not driven, the load such as the motor does not operate, and the time constant circuit and the first switching means are reset and controlled by the third control circuit. Since it can be shared by the switching means, the circuit configuration can be simplified, the number of parts can be reduced, and the cost can be reduced.

[Brief description of drawings]

FIG. 1 is a block diagram of an embodiment of the present invention, FIG. 2 is a detailed circuit diagram of the same as above, FIG. 3 is a perspective view of an oil stove above, FIG. 4 is a sectional view of the same as above, and FIG. It is a specific circuit diagram of. 7 is a motor, 16 is a battery, 18 is a detection switch, 21 is a time constant circuit, 22 is a first switching means, 23 is a second switching means, 24 is a third switching means, C is a common terminal, NC is Normally closed terminal, NO is a normally open terminal, and D is a diode.

Claims (2)

(57) [Claims] 1. A switch in which a common terminal is connected to a battery power source and a switch which is connected to one of the normally closed terminals of the switch and which is reset when the other normally open terminal is connected to the normally closed terminal. A time constant circuit that operates in time, and a first switching means that detects the output of the time constant circuit,
The time constant circuit is reset by the second switching means that receives the output of the first switching means and drives and controls the load of the motor and the like, and the normally open terminal output that is switch-connected to the switch to reset the time constant circuit. A timer circuit configured to maintain the output of the first switching means by the output of the switching means and to turn off the first switching means completely after a predetermined time of operation, and a third switching means. 2. A diode for compensating the temperature characteristic of the threshold level of the first switching means is provided between the normally closed terminal of the switch and the time constant circuit. Timer circuit.