JPH0515238B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field] The present invention relates to a time switch with a weekly setting function used for turning on and off power for machine tools, lighting equipment, etc.

[Background technology]

This type of time switch has a time switch that is turned on and off by a time setting knob that is detachably attached to the circumference of a dial that rotates once a day. For example, a day signal switch that operates at midnight and seven day selection switches are used to select whether to enable or disable the load, and is said to skip disabling.

As shown in Japanese Patent Application No. 57-191389, the conventional configuration of this type of time switch is that when setting the week (setting the day to skip), it is done entirely mechanically, or it is mechanically discrete. This is done by connecting several electronic circuits.
FIG. 11 shows a configuration diagram of a conventional example, which is configured as follows. That is, a time switch 52 is formed of a dial that rotates once a day and is turned on and off by a timer time setting setter that is detachably attached to the circumference of the dial. A switch 54 is turned on for a certain period of time at midnight in conjunction with the rotation of the dial to generate a day change pulse from a day change pulse generator 53, and a switch 54 inputs the day change pulse as a clock and sequentially cyclically operates each time the clock is input. A day-of-the-week signal generation circuit 56 consisting of a heptadary counter 55 having seven output terminals corresponding to each day of the week, which shifts the output terminal at which an output is generated, is connected at one end to the corresponding output terminal and at the other end. Seven day selection switches 57 commonly connected, and a transistor 59 that is turned on by the output signal of the day signal generation circuit 56 inputted via the day selection switches 57 to operate the relay 58.
A load 61 is connected to the load 61 through a series circuit between the relay contact 60 of the relay 58 and the time switch 52.
This is a time switch with a skip day function that is connected to a power source.

By the way, in the time switch of this conventional configuration, the day of the week selection switch 57 cannot select whether or not to cause the load 61 to skip. FIG. 12 shows a time chart of a time switch having a conventional configuration. As shown in the figure, the load 61 is turned on and off on Monday at the time set by the setter, but if Tuesday is skipped (the load is not driven), the load 61 is turned on and off at the time set by the setter. When the load is turned on in a so-called daily operation, the day selection switch 57 is turned off at 0:00 on Tuesday, so the output is turned off at 0:00 on Tuesday. In other words, a time switch with a skip day function has a problem in that it cannot perform day-to-day control (control to output across days of the week).

[Purpose of the invention]

The present invention has been provided in view of the above-mentioned points, and uses an arithmetic processing unit consisting of a microcomputer to take in signals from a day of the week change switch, a time setting state detection switch, and a day selection switch, and generate relay signals. The purpose of the present invention is to provide a time switch with a weekly setting function that is capable of day-to-day control even though it is possible to set the day of the week.

[Disclosure of the invention]

(Structure) The present invention comprises a timepiece groove having a dial that rotates once a day, and a time setting state detection switch that is driven on and off by a time setting setter attached to the circumference of the dial. , a day change switch that is turned on for a certain period of time around midnight in conjunction with the dial to generate a day change pulse, a day selection switch for weekly settings that selects seven days of the week, the time setting state detection switch, and the day of the week. an arithmetic processing unit consisting of a microcomputer that takes in signals from the change switch and the day selection switch and generates signal pulses to provide a relay to turn on and off the load at the time set by the setter on the day of the week selected by the day selection switch; , and a power supply circuit unit that supplies power to the arithmetic processing unit, and when performing day-to-day control of the load over the days of the week where the load is not driven through midnight, the day of the week on which the load is not driven. In addition, the arithmetic processing unit is provided with a control means for disabling the load when the signal from the time setting state detection switch changes to the OFF state, and the day-to-day control mode is changed to the normal mode that passes through midnight once. A mode changeover switch is provided that allows the mode to be switched freely between the mode and a continuous mode in which midnight is passed twice or more.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram of a time switch according to the present invention, which mainly includes a power supply circuit section 6, a latch relay Ry,
It is composed of a motor M, an arithmetic processing section 5 consisting of a microcomputer, and a switch section 10 consisting of mechanical switch mechanisms such as a time setting state detection switch, a day of the week change switch, a day of the week selection switch, etc. Also provided are a power failure detection circuit 7 for detecting a power failure, a reset circuit 8 for initializing the arithmetic processing section 5 after power is turned on, and the like. Battery 9 is for backup. The schematic configuration of the switch section 10 is as follows. The switch section 10 generates a day of the week change pulse, detects the time setting state, and detects the week setting state. The day of the week change pulse has a switch that is turned on once every 24 hours, and when this is turned on (for example, turned on at midnight), the day of the week is changed (to the next day).

FIG. 2 shows a plan view of the time switch according to the present invention, and the time setting state is detected by tilting down or standing up the setter embedded in the dial 11, and detecting the state by using a micro switch via an arm or a lever. To detect. This micro time switch constitutes a time setting state detection switch.
Weekly settings are set and detected using a sliding day selection switch 4. Each time the day of the week setting button 12 is pressed, the day of the week light emitting diodes _LED1 ...LED7 corresponding to the day selection switches 4a, 4b... _4g advance by one. The day selection switches 4a...4g correspond to "Sunday", "Monday"..."Saturday", respectively.
When the manual on/off switch 13 is in the off position and on position, the output is output when it is off, regardless of the state of the time setting state detection switch and the normal/continuous changeover switch (mode changeover switch) 14 of the day selection switch 4. When turned off, the output is turned on and set to the center automatic position, the processing unit 5 determines the status of the time setting state detection switch, day of the week selection switch 4, and normal/continuous changeover switch 14 and outputs it. Turn off. The signal from the day of the week setting button 12 is also taken into the arithmetic processing section 5, and the day of the week light emitting diode is
It is also used to control the lighting of LED ₁ ... and to determine the output when the manual on/off switch 13 is set to automatic. Day of the week light emitting diode LED ₁ ...displays the current day of the week.
The signal from the day of the week setting button 12 and the signal from the day selection switch 4 are taken into the arithmetic processing section 5, and the lighting is controlled by the arithmetic processing section 5. Also, when the day of the week light emitting diode LED ₁ ... is lit or blinking, it indicates that the AC input is in a power-on state.
Output light emitting diode LED ₀ indicates the output status,
Lights up when the output is on, and turns off when the output is off. This output light emitting diode LED ₀ also lights up,
Turning off the light is also controlled by the arithmetic processing unit 5. Manual on/
Off switch 13, normal/continuous changeover switch 14,
Signals from the time setting state detection switches, which are microswitches driven by the rotation of the dial 11, are respectively input to the arithmetic processing section 5 and controlled.

In this way, the arithmetic processing unit 5 detects the state of each switch 4... and turns on the latch relay Ry.
Turn it off. The on/off conditions for the latch relay Ry are based on the flowchart shown in FIG. 3, which will be described later.
Further, the arithmetic processing section 5 controls the rotation of the motor M that drives the dial 11 that sets and detects the time setting state of the timepiece groove section 1, the lever, the arm, and the like.

FIG. 4 shows an exploded perspective view of the time switch. There is a stepping motor (not shown) controlled by an arithmetic processing section 5 in the clock groove section 1, which is a moving block. Dial 11 rotates once a day. 96 setting elements are attached to the circumference of the dial 11. Lever 1
5, the arm 16, the switching cam 18, and several gears are arranged between the upper plate 24 and the lower plate 25. A latch relay Ry and a power supply circuit section 6 are mounted on the printed board 21, and an arithmetic processing section 5, light emitting diodes _LED0 , _LED1 , etc. are mounted on the printed board 22. Further, the printed board 23 is equipped with a day of the week selection switch 4, a day of the week setting button 12, a manual on/off switch 13, a normal/continuous changeover switch 14, and the like. The day change switch 3 that generates the day change pulse at midnight has two contact pieces 26 and 2.
6 is also composed of a driving gear 28 and the like. Each of these members is housed in a lower case 19, and an upper case 20 is placed over the upper surface of the lower case 19.
A terminal block 30 provided with terminal screws 28 and terminal fittings 29 is attached to the lower surface of the lower case 19 , and the lower case 19 and the upper case 20 are fixed by mounting fittings 31 . A nameplate 32 is attached to the upper surface of the upper case 20.

FIG. 5 shows a perspective view of the main part of the structure for detecting the time setting state.
7 is mounted rotatably in the radial direction of the dial 11. A claw piece 17a is integrally formed at the bottom of the setter 17, and can be used to keep the setter 17 upright.
By tilting it down, the lever 15 in contact with the circumference of the dial 11 rotates with or without the claw piece 17a on the circumference of the dial 11.
When the lever 15 rotates, the arm 16 moves, and the drive lever 33 in contact with it rotates, driving the push button 2a of the time setting state detection switch 2, which is a micro switch in the clock groove 1, to set the time. Turn the state detection switch 2 on and off.

Next, the operations of the day selection switch 4 and the normal/continuous changeover switch 14 in the normal mode and continuous mode will be explained. The day of the week selection switch 4 is a switch for setting the operation on each day of the week, and the normal/continuous changeover switch 14 is a switch for setting the operation mode, and changes the meaning of the day of the week selection switch 4. First, FIG. 6 shows a time chart showing daily operation in the normal mode, with the day selection switch 4 set to "auto" for Sunday, Monday, and Thursday, and "off" for Tuesday and Wednesday. On days of the week set to "Auto," the output is turned on (8:00) when the time setting state detection switch (micro switch) 2 changes from off to on.
Turn off the output when it changes from on to off (16:00). On days of the week set to "off", even if the time setting state detection switch (micro switch) 2 changes from off to on, the output does not turn on and remains off. When the time setting state detection switch 2 changes from on to off, the output is turned off. Also,
If the time setting state detection switch 2 changes during the day (for example,
If it is on during the period from 20:00 to 0:00 to 4:00), the time setting state detection switch 2 on the day of the week set to "off" will change from on to off (4:00). The output will remain on until changed.

Next, the continuous mode will be explained. Figure 7 shows
This shows a time chart of daily operation in continuous mode. In Fig. 7, day selection switch 4
I set Monday, Tuesday, and Thursday to "Auto" and set Wednesday to "Off" by operating the .
On days of the week set to "automatic", even if the time setting state detection switch 2 changes from on to off, the output does not turn off and remains on. When the time setting state detection switch 2 changes from off to on, the output is turned on. On days of the week set to "off", the state does not change even if the time setting state detection switch 2 changes from off to on. When the time setting state detection switch 2 changes from on to off, the output is turned off. Therefore, in continuous mode, Monday 8:
The output is on from 00:00 to 4:00 on Wednesdays.

Next, the overall operation will be schematically explained using the flowchart shown in FIG. When the power is turned on, the reset circuit 8 initializes the arithmetic processing section 5, and if the test mode is released, it is checked to see if there is a timer interrupt. If there is a timer interrupt, one pulse is output to the stepping motor of the clock machine groove section 1. Here, if the day of the week change switch 3 is turned on from off, the day of the week light emitting diode
LED ₁ ... advances by one. If the day of the week change switch 3 is off, a power outage detection circuit 7 detects a power outage. If there is a power outage, the light emitting diode LED ₁ ..., the output light emitting diode LED ₀ will turn off, and the latch relay will turn off.
Turn Ry off. If there is no power outage, the manual on/off switch 13, day selection switch 4, and micro switch (the micro switch shown in Figure 3 is the time setting state detection switch 2)
The data is taken into the arithmetic processing section 5. The arithmetic processing unit 5 repeats this routine if each piece of data taken in is the same as the previous data. If the data is not the same as last time, it is determined whether the state of the manual on/off switch 13 is "on", "automatic", or "off". If the manual on/off switch 13 is “off”,
Turn off the latch relay Ry. Also, if it is "on", the latch relay Ry is turned on. If the manual on/off switch 13 is "auto", the normal/continuous changeover switch 14 determines whether it is "normal mode" or "continuous mode", and if the normal/continuous changeover switch 14 is "normal mode", the As shown in Figure 6, if the micro switch changes from OFF to ON, and the current day selection switch 4 is ON, the latch relay Ry
Turn on. When latch relay Ry is on, output light emitting diode LED ₀ lights up. Also,
When the micro switch changes from on to off, turn off the latch relay Ry. If the normal/continuous changeover switch 14 is in the "continuous mode", as shown in FIG. 7, the micro switch is turned on from off, and if the current day of the week selection switch 4 is on, the latch relay Ry is turned on. Further, if the micro switch is turned from on to off and the current day of the week selection switch 4 is off, the latch relay Ry is turned off.
Incidentally, the above-mentioned micro switch refers to the time setting state detection switch 2 as described above.

Next, day-to-day control will be explained. In FIGS. 6 and 7, the time setting on the dial 11 is in the daytime setting (on setting state), 20:00 to 4:00. Conversely, when the ON setting is from 4:00 to 20:00, the time chart when the normal/continuous changeover switch 14 is in the normal mode is set to 8.
Figure 9 shows the time chart for continuous mode.
They are shown in the figure. In the case of Figure 8, Monday is set to "Automatic".
The 9th day of the month is the 9th
In the case shown in the figure, Monday and Tuesday are set to "Auto" consecutively. In this way, dial 11
By having different time settings, different output operation patterns can be provided.

In this way, the day of the week change pulse from the day of the week change switch 3, signals from the time setting state detection switch 2, etc. are taken in, and the generation of relay signals, motor drive pulses, etc. is performed by the arithmetic processing unit 5, which is a micro switch having a control means. Although it is possible to set the day of the week, it is possible to control the number of days.
As described above, by setting the modes of the day selection switch 4 and the normal/continuous changeover switch 14 to off, normal, and continuous, various output operation patterns can be obtained. In addition, since the time setting of the dial 11 by the setter 17 and the changeover switches 4 and 14 for other modes are independent, the setting is easy. Even if it is turned on or off, it can perform a predetermined daily operation.

FIG. 10 shows a plan view of a time switch according to another embodiment. Normal/continuous switch 1
Instead of defining 4 only as “normal” and “continuous”,
An operating section for "off" is provided, and for this "off", the 12th
``Normal'' mode allows for the skipping shown in the figure, and ``Normal'' mode allows for normal mode as shown in Figures 6 and 8. ``Continuous'' mode allows day-to-day movement as shown in Figures 7 and 9. This is how it was done.

〔Effect of the invention〕

As described above, the present invention includes a timepiece groove having a dial that rotates once a day, and a time setting state detection switch that is driven on and off by a time setting setter attached to the circumference of the dial. a day change switch that is turned on for a certain period of time around midnight in conjunction with a dial to generate a day change pulse; a day selection switch for weekly settings that selects seven days of the week; and a time setting state detection switch; An arithmetic processing unit consisting of a microcomputer that takes in signals from the day of the week change switch and the day of the week selection switch and generates signal pulses that provide a relay that turns the load on and off at the time set by the setter on the day of the week selected by the day of the week selection switch. and a power supply circuit unit that supplies power to the arithmetic processing unit, and when performing daily control of the load over the days of the week in which the load is not driven through midnight, the load is not driven. The arithmetic processing section is provided with a control means for disabling the load when the signal from the time setting state detection switch changes to the OFF state on any day of the week, and the day-to-day control mode is passed through once at midnight. Since a mode changeover switch is provided that allows the user to freely switch between the normal mode and the continuous mode that passes midnight twice or more, it has the effect of easily realizing day-of-the-week settings and daily control of various operating patterns. Since day-to-day control is performed by an arithmetic processing unit consisting of a microcomputer based on signals from each switch, the configuration of the control unit is simplified.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of a time switch according to an embodiment of the present invention, FIG. 2 is a plan view of the same, FIG. 3 is a flowchart of the same, and FIG. 4 is an exploded perspective view of the same.
Figure 5 is a perspective view of the main parts of the same as above, Figure 6 is a time chart showing the daily operation in normal mode, and Figure 7 is
Figure 8 is a time chart showing daily operation in continuous mode as above, Figure 8 is a time chart showing normal mode operation from 4:00 to 20:00 as above, and Figure 9 is a time chart showing operation in normal mode from 4:00 to 20:00 as above.
The figure is a time chart showing the operation in the continuous mode from 4:00 to 20:00 as above, Figure 10 is a plan view of another embodiment of the same as above, Figure 11 is a block diagram of the conventional example, and Figure 12 is the conventional example. This is an example time chart. 1 is a clock groove section, 2 is a time setting state detection switch, 2 and 3 are day change switches, 4 is a day selection switch, 5 is an arithmetic processing section, 6 is a power supply circuit section, 11
is a dial, and 17 is a setter.

Claims (1)

[Claims] 1. A clock groove having a dial that rotates once a day, a time setting state detection switch that is turned on and off by a time setting setter attached to the circumference of the dial, and a time setting state detection switch that is linked to the dial. 0am
a day change switch that is turned on for a certain period of time before and after the hour to generate a day change pulse; a day selection switch for weekly settings that selects seven days of the week; An arithmetic processing section consisting of a microcomputer that takes in signals and generates signal pulses that drive the relay to turn on and off the load at the time set by the setter on the day of the week selected by the day selection switch, and a power supply to the arithmetic processing section. and a power supply circuit section that supplies a time setting state detection switch on the day of the week when the load is not driven, when controlling the load on a daily basis over the days of the week when the load is not driven after midnight. The arithmetic processing unit is provided with a control means for disabling the load when the signal from A time switch with a weekly setting function, characterized in that it is equipped with a mode changeover switch that can freely switch between a continuous mode that passes through two or more times.