JP2006329956A5 - - Google Patents

Description

Program timer

  The present invention relates to a program timer for sounding alarm sounds such as chimes, melodies, announcements, etc. and controlling external devices at a desired time in schools, private schools, public facilities, offices, factories and the like.

Conventionally, there has been a means for measuring the current time and a program timer for generating a notification sound when the current time matches the set time of the program stored in the storage means, or for controlling an external device. By attaching a setting device for setting a control program or a control program for an external device to the timer body in a detachable manner, it is possible to remove the setting device from the timer body and set the program, thereby simplifying the setting operation. (For example, see Patent Document 1)
JP-A-6-289158

  However, the conventional program timer cannot receive the standard time radio wave including the standard time signal and cannot correct the current time of the clock means based on the standard time.

  The present invention has been made in view of the above reasons, and the invention of claim 1 can receive a standard time radio wave including a standard time signal and correct the current time of the clock means based on the standard time. The purpose is to provide a program timer.

  It is an object of the present invention to provide a program timer that can automatically correct the current time of the clock means.

  A third object of the present invention is to provide a program timer capable of correcting the current time of the clock means by manual operation.

  An object of the present invention is to provide a program timer capable of displaying a radio wave intensity indicating the possibility that the received radio wave is a standard time radio wave.

  Another object of the present invention is to provide a program timer capable of displaying the success or failure of the correction of the current time of the clock means.

  An object of the present invention is to provide a program timer capable of displaying the reception day of the week with the current time of the clock means corrected.

  The invention of claim 7 is a program that can be installed by checking the position where the radio wave receiving unit can receive the standard time radio wave alone, and the program timer body can be installed at any position regardless of whether the standard time radio wave can be received or not. The purpose is to provide a timer.

  According to the first aspect of the present invention, there is provided clock means for measuring the current time, program setting means for setting a program for generating a notification sound or controlling an external device at a desired time, and a program for storing the set program Including a storage means, an output control means for generating a control sound for generating a notification sound or controlling an external device when the current time coincides with a set time of a program stored in the program storage means, and a standard time signal A radio wave receiving means for receiving standard time radio waves, a frequency selecting means for selecting standard time radio waves received from a plurality of standard time radio waves of different frequencies, and a pulse for forming a time code of standard time from the received standard time radio waves A time code forming pulse generating means for generating a time code forming pulse including the generated time code forming pulse A time encoding means for generating a time code of the sub-time, a time data generating means for generating a standard time from the time code, and a radio wave for giving an instruction for correcting the current time of the clock means based on the generated standard time to the time correcting means Receiving control means.

  According to the present invention, it is possible to receive a standard time radio wave including a standard time signal and correct the current time of the clock means based on the standard time.

  According to a second aspect of the present invention, there is provided the radio wave receiving operation control state storage means for storing the time encoding state in the time encoding means and the time data generation state in the time data generation means in the first aspect. The radio wave reception control means corrects the current time of the clock means based on the standard time generated from the time code. Features.

  According to the present invention, the current time of the clock means can be automatically corrected.

  According to a third aspect of the present invention, in the first aspect, the radio wave receiving unit includes a forced reception operation unit for manually receiving the standard time radio wave by manual operation, and the radio wave reception control unit generates a time code generated at the time of the forced reception. The time encoding means is controlled so as to try time encoding using a pulse as a time code of standard time, and the current time of the clock means is corrected based on the standard time generated from the time code. To do.

  According to the present invention, the current time of the clock means can be corrected by manual operation.

  According to a fourth aspect of the present invention, in any one of the first to third aspects, the reliability of the time code forming pulse is determined based on the electric field strength determining means for determining the electric field strength of the received radio wave and the pulse width of the time code forming pulse. A time code forming pulse reliability determining means, a radio field strength determining means for determining a radio field intensity indicating the possibility that the received radio wave is a standard time radio wave based on the electric field strength and the reliability of the time code forming pulse; And a radio wave intensity display means for displaying the intensity.

  According to the present invention, it is possible to display the radio field intensity indicating the possibility that the received radio wave is a standard time radio wave.

  A fifth aspect of the present invention provides the reception status determination means for determining success or failure of the correction of the current time of the clock means according to any one of the first to fourth aspects, and a reception completion state when the correction of the current time is successful. Receiving completion display means for displaying.

  According to the present invention, the success or failure of the correction of the current time of the clock means can be displayed.

  According to a sixth aspect of the present invention, in any one of the first to fifth aspects, the received day of the week storage means stores the received day of the week when the standard time radio wave is received and the current time of the clock means is corrected, and the received day of week storage means stores the received day of the week. A reception day of the week display means for displaying the received day of the week, and a reception day of the week confirmation operation means for displaying the reception day of the week on the reception day of the week display means by manual operation.

  According to the present invention, it is possible to display the reception day of the week with the current time of the clock means corrected.

The invention of claim 7 is the radio frequency reception means according to any one of claims 1 to 6, the frequency selection means, a reception frequency display means for displaying a frequency of a standard time radio wave selected by the frequency selection means, and the time. Code forming pulse generating means, time code forming pulse reliability determining means, electric field strength determining means, electric field strength display means for displaying electric field strength determined by the electric field strength determining means, and voltage of a signal to be transmitted A program timer body comprising: a radio wave receiving unit comprising a signal voltage converting means for converting the signal ; the clock means; the output control means; and a signal voltage converting means for converting the voltage of the signal transmitted from the radio wave receiving unit ; A setter including the clock means, the program setting means, and the program storage means, and a radio wave receiving unit. The bets and program timer body, characterized in that it is electrically connected via a cable.

  According to the present invention, the position where the standard time radio wave can be received by the radio wave receiving unit alone can be confirmed and installed, and the program timer body can be installed at any position regardless of whether the standard time radio wave can be received.

The invention of claim 8 is the radio wave receiving unit according to claim 7, wherein the radio wave receiving unit includes a receiving unit power source forming unit including an external power source connecting unit to which power is supplied from the outside and a switching unit for switching the external power source to be connected. The program timer main body and the radio wave receiving unit are each provided with a terminal block, and both ends of the cable are connected to the respective terminal blocks for electrical connection, or the cable timer is directly pulled out from the program timer main body and the radio wave receiving unit. Connect to the terminal block of the electrical connection, or directly from the radio wave reception unit, pull out the cable and connect to the terminal block of the program timer body, or make an electrical connection, or directly from the program timer body, Pull out the cable and pull the cable directly into the radio wave receiving unit for electrical connection. To.

The invention of claim 9 is the invention according to claim 8, wherein the program timer main body is provided with a power failure compensation battery used as a power source in the event of a power failure, and the external power connection means of the radio wave receiving unit can connect the power failure compensation battery. It is characterized by comprising.

A tenth aspect of the present invention provides the radio wave receiving unit connection state determining means for determining the connection state between the radio wave receiving unit and the program timer main body according to the eighth or ninth aspect, and the determination results of the radio wave receiving unit connection state determining means. And a radio wave receiving unit connection state display means for displaying.

The invention of claim 11 is the power supply state determination means for determining the state of the external power supply connected to the external power supply connection means of the radio wave receiving unit according to any of claims 8 to 10, and the determination result of the power supply state determination means And a power supply state display means for displaying.

According to a twelfth aspect of the present invention, in any one of the eighth to eleventh aspects, a time code forming pulse reliability display unit that displays a determination result of the time code forming pulse reliability determination unit of the radio wave receiving unit is provided. .

The invention of claim 13 provides the reception frequency identification signal generating means for generating a signal according to the frequency of the standard time radio wave selected by the frequency selection means in any of claims 8 to 12, The reception frequency display means displays the frequency of the standard time radio wave according to the output of the reception frequency identification signal generation means.

  As described above, the present invention has an effect that the standard time radio wave including the standard time signal is received and the current time of the clock means can be corrected based on the standard time.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment)
As shown in FIG. 1, the program timer according to the embodiment of the present invention includes a program timer main body 100, a setting device 200, and a radio wave receiving unit 300. FIG. 2 shows a perspective view of the program timer. The main body 100 is attached to a wall surface, the setting device 200 is detachably attached to the program timer main body 100, and the radio wave receiving unit 300 is electrically connected to the program timer main body 100 via the cable L. Then, the program timer body 100 controls the output of the notification sound and the operation control of the external device according to the program set by the setting device 200 and the external interrupt input from the human body detection sensor or the call switch provided outside. Further, the program timer main body 100 and the setting device 200 correct the current time based on the signal from the radio wave receiving unit 300 that receives the standard time radio wave. FIG. 3 shows a state where the setting device 200 is removed from the program timer main body 100.

  The program timer main body 100 includes an analog clock unit 101 in the upper part of the front surface, a speaker unit 102 including a speaker that generates a notification sound such as a chime sound is provided on the lower right side thereof, and a storage unit that stores the setting device 200 on the left side. 103 is formed. Also, two control outputs (referred to as “Circuit 1” and “Circuit 2”, respectively) for controlling external devices are provided, and the switches 104a and 104b below the storage unit 103 manually control the outputs of the respective circuits. The switch 104c is an analog clock adjustment switch for manually adjusting the analog clock unit 101. Furthermore, control output state indicators 105a and 105b made up of light emitting diodes or the like for displaying the state of control output by the operation of each switch are provided above the control output manual operation switches 104a and 104b.

  The housing 106 of the program timer main body 100 is made of synthetic resin, and when mounted on the wall surface, the body 106a that faces the wall surface, the upper cover 106b to which the analog clock unit 101 is mounted, the storage unit 103, and the sound output hole 107 of the speaker. The lower cover 106c is formed. The upper cover 106b is openable and closable with respect to the body 106a. An openable / closable setting device cover 108 that closes the front surface of the stored setting device 200 is attached to the storage portion 103.

  The storage portion 103 for storing the setting device 200 is formed with a rectangular storage recess 103a, and notches 103b and 103b into which fingers are inserted when the setting device 200 is attached and detached above and below the opening edge of the storage recess 103a. Is forming. A connector 109 for electrically connecting the program timer main body 100 to the setting device 200 is provided at the center of the bottom of the housing recess 103a, and a rectangular cylindrical connector guide 110 is provided around the connector 109 so as to be set. A connector 207 (see FIG. 5) provided in the container 200 is guided to the connector 109. On both sides of the connector 109, guide bosses 112 and 112 are provided so as to guide to a predetermined position when the setting device 200 is stored. Further, locking pieces 111 and 111 for mechanically holding the setting device 200 are provided on the upper and lower sides of the connector 109. A locking claw 111a is formed inwardly at the tip of the locking piece 111, and the outer periphery of the tip surface of the locking claw 111a is bent or chamfered.

  Next, FIG. 4 is a front view of the setting device 200. The setting device 200 is formed in a rectangular box shape, and a display unit 201 made of a liquid crystal display is provided on the upper right side of the front surface, and various setting switches 202 (202a to 202s) and a recording jack 203 are arranged on the lower side thereof, and the left side portion. Is provided with a sliding mode changeover switch 204.

  The display of the display unit 201 in FIG. 4 is a display in the normal (time display) mode of the mode changeover switch 204, and a substantially central time display unit 201a for displaying the hour / minute and a day of the week display unit 201b provided at the upper part thereof. Furthermore, the radio wave receiving unit 300 is connected to the program timer main body 100 for the standard time radio wave receiving function, and therefore includes a receiving unit connection state display unit 201c, a radio wave intensity display unit 201d, and a reception completion display unit 201e. , Current time (day of the week, hour, minute, second), receiving unit connection status, radio wave intensity, reception completion is displayed. In addition, on the upper and lower surfaces of the setting device 200, when the setting device 200 is removed from the storage portion 103, a removal button 205 that is exposed to the notch 103b and is operated is provided. In addition, a nickel-hydrogen battery, a lithium battery, a dry battery, a solar battery, and the like are provided as a power source to enable operation even when the program timer body 100 is detached.

  FIG. 5 is a perspective view showing the back surface of the setting device 200. A guide receiver 206 formed in a rectangular recess is formed substantially at the center of the back surface of the setting device 200, a connector 207 is provided on the bottom surface of the guide receiver 206, and a locking piece 111 is inserted above and below the guide receiver 206. Insertion holes 208 and 208 are formed, and guide holes 209 and 209 through which the guide boss 112 is guided are formed on both sides of the guide receiver 206. A power switch 210 and a setting device speaker unit 211 are also arranged, and an external battery connecting connector 212 is arranged on one side surface. Further, the front surface and the back surface of the housing 220 of the setting device 200 are fixed at four locations by screws 213 screwed from the back surface.

  The setting device 200 is housed in the housing portion 103 in a retaining state, and the connector 207 of the setting device 200 is fitted and electrically connected to the connector 109 of the program timer main body 100. When removing the setting device 200 from the storage portion 103, a state in which the locking piece 111 can be inserted through the insertion hole 208 by inserting a finger into the notch portion 103b and pushing both the removal buttons 205, 205 inward. And the setting device 200 may be pulled forward.

  Next, the radio wave reception unit 300 includes a reception unit main body 301, a reception unit holding unit 302, and a reception unit base 303. The radio wave reception unit 300 has a rainproof structure made of synthetic resin, and can be installed outdoors.

  The receiving unit main body 301 forms an outer case by an upper case 304 and a lower case 305, and a receiving circuit unit incorporating an antenna is housed therein, and a power supply state display described later is exposed to the upper case 304 side. A power supply state display LED 310 serving as means 335d, a 40 kHz reception display LED 306a serving as a reception frequency display means 335b described later, a 60 kHz reception display LED 306b, four field strength display LEDs 307 serving as field strength display means 335a described later, and a time described later. A reliability display LED 308 serving as a code forming pulse reliability display means 335c is provided. Furthermore, the cable L is drawn out of the radio wave receiving unit 300 from the receiving circuit unit inside the receiving unit main body 301 through one receiving unit holding unit 302 and is formed in the upper surface of the body 106a of the program timer main body 100. The terminal is connected to the terminal block in the program timer main body 100 through the through-hole 113 to supply power to the radio wave receiving unit 300 from the program timer main body 100, and from the standard time radio wave received by the radio wave receiving unit 300 to the standard time. A pulse forming a time code is generated, and a signal indicating the time code forming pulse, the time code forming pulse reliability, and the electric field strength is transmitted to the program timer main body 100.

  The receiving unit holding unit 302 forms a U-shaped outline by the left case 309a and the right case 309b.

  The receiving unit base 303 is formed in a rectangular shape, and a receiving unit holding part 302 is detachably attached thereto, and the receiving unit main body 301 of the box is rotatably held between both ends of the receiving unit holding part 302. And after attaching the receiving unit base 303 to a wall surface or a ceiling, the radio wave receiving unit 300 is attached to the wall surface or the ceiling by fitting the receiving unit holding part 302 holding the receiving unit main body 301 into the receiving unit base 303. be able to.

  The radio wave receiving unit 300 is separated from the program timer main body 100 via the cable L so that the position where the radio time receiving unit 300 can receive the standard time radio wave can be confirmed. An external power supply connection means connectable to the power failure compensation battery of the program timer main body 100 is provided so that the battery can be used as an external power supply.

  Next, a schematic configuration of the program timer will be described with reference to FIG. The program timer shown in FIG. 1 includes a program timer main body 100, a setting device 200, and a radio wave receiving unit 300. The program timer main body 100 and the setting device 200 are electrically connected via connectors 145 and 229. The program timer main body 100 and the radio wave receiving unit 300 are electrically connected by a cable L connecting the terminal blocks 146 and 341.

  In FIG. 1, terminal blocks 146 and 341 are provided in the program timer main body 100 and the radio wave receiving unit 300, respectively, and electrical connection is performed by a cable L in which both ends are connected to the terminal blocks 146 and 341. The cable L is directly pulled out from the timer body 100 and connected to the terminal block 341 of the radio wave receiving unit 300 for electrical connection, or the cable L is directly pulled out from the radio wave receiving unit 300 and the terminal block 146 of the program timer main body 100 is connected. Alternatively, the cable L may be connected to be electrically connected, or the cable L may be directly pulled out from the program timer main body 100 and the cable L may be directly pulled into the radio wave receiving unit 300 to be electrically connected.

  The program timer main body 100 determines whether or not there is an external interrupt input from a switch operation determination means 130 for determining the operation of a manual switch such as the control output manual operation switches 104a and 104b and a human body detection sensor or a call switch provided outside. Output for selecting the external interrupt input determining means 131 to be determined and the operation state of the manual switches such as the control output manual operation switches 104a and 104b or the determination of the external interrupt input and displaying the selected output state Selection / display unit 132, switch operation determination unit 130, external interrupt input determination unit 131, determination of operation control of built-in speaker (speaker unit 102), external speaker, illumination, etc., based on outputs from setting device 200 And notification sounds such as melodies, chimes, announcements, etc. Output determination means 133 for determining the selection, output state determination storage means 134 for storing the determination result of the output determination means 133, clock means 135 for measuring the current time, the determination result of the output determination means 133 and Based on the time output of the clock means 135, the control output means 137 of "Circuit 1", the control output means 138 of "Circuit 2", the notification voice output means 139, the analog clock output means 140 (the analog clock part 101 with the clock means 135) Output control means 136 for controlling (which constitutes) as a basic configuration.

  The main body power generation means 147 of the program timer main body 100 supplies the power to each means of the program timer main body 100 with the commercial power from the AC power supply input means 143 as an input, and the setting device power generation means 248 of the setting device 200. Power is also supplied to the radio wave receiving unit power supply forming means 340 of the radio wave receiving unit 300.

  The manual switch operation display means 141 constitutes control output state indicators 105a and 105b composed of light emitting diodes or the like.

  Further, a signal voltage converting means 142 for converting the voltage of the signal from the radio wave receiving unit 300, a time encoding means 126 for receiving the time code forming pulse signal from the radio wave receiving unit 300 and encoding the time, and a time encoding means 126 of time data generating means 127 for converting the time based on the time code obtained from 126, and the setting device 200 to be described later by determining the radio wave intensity based on the electric field intensity and radio wave reliability signals from the radio wave receiving unit 300. Radio wave intensity determining means 128 including a display control means for displaying the radio wave intensity on the radio wave intensity display means 235a, time correcting means 148 for correcting the current time of the clock means 135, time encoding means 126, time data generating means 127, etc. The time correction for correcting the current time of the clock means 135 based on the received standard time by controlling the reception of A radio reception control unit 129 gives instruction to the time adjustment means 148, and a signal reception operation control state storage means 149 for storing a control state of the radio wave reception control unit 129.

  The setter 200 includes a notification number setting means 231a, a notification voice signal number setting means 231b, and a playback / recording / editing operation means 231c, using the mode change switch 204 and various setting switches 202 to set the clock, program setting / calling, notification. Program setting means 230a for reproducing / recording / editing audio signals, program setting means 230b for performing radio wave reception processing at the time of standard time radio wave reception, including forced reception operation means 232a and reception confirmation operation means 232b (hereinafter referred to as program setting) The means 230a and 230b are collectively referred to as program setting means 230), the program storage means 234 for storing the program set by the program setting means 230a, the radio wave intensity display means 235a, the reception completion display means 235b, and the reception unit connection status display. Watch including means 235c It comprises a display means 235 for displaying a program / radio wave reception status, a display control means 238 for displaying the setting state of the program setting means 230a and the storage contents of the program storage means 234 on the display means 235, and various setting switches. A clock setting unit 239 for performing various settings relating to time, a clock unit 240 for measuring time, a notification voice signal storage unit 241 for storing a plurality of notification voice signals and a notification voice signal number corresponding to each notification voice signal; The notification voice input means 243 for inputting the notification voice signal to the notification voice signal storage means 241 through the notification voice control means 242 and the notification voice signal called from the notification voice signal storage means 241 through the notification voice control means 242 are converted into the notification voice. Notification voice confirmation means 244 (setting device speaker unit 211) to be output, Program determination means 245 for making a predetermined operation control and selection determination of a notification sound signal (melody, chime sound, announcement, etc.) based on the program stored in the program storage means 234 and the time generated by the clock means 240, and the program determination means 245 Control based on the determination result and the determination result of the output determination means 133 of the program timer main body 100, the reproduction processing of the notification voice signal stored in the notification voice signal storage means 241 according to the operation of the mode changeover switch 204, A notification voice control means 242 for controlling a recording process for converting a notification voice analog signal into a digital signal and storing it in the notification voice signal storage means 241, and an editing process for the notification voice signal stored in the notification voice signal storage means 241; The time correction means 233 for correcting the current time of the clock means 240 and the received standard A radio wave reception control unit 246 that gives a time correction instruction to correct the current time of the clock unit 240 based on the time, a radio wave reception control storage unit 247 that stores a control state of the radio wave reception control unit 246, and a setting A setting device power supply forming means 248 for supplying power to each means of the device 200 is provided as a basic functional configuration.

  The radio wave receiving unit 300 includes a radio wave receiving unit 331 that receives a standard time radio wave including a standard time signal, a frequency selection unit 332 that selects a standard time radio wave received from standard time radio waves having different frequencies, and a received radio wave. Time code forming pulse generating means 333 for generating a time code forming pulse including a pulse for forming a time code of a standard time, and a time code for determining the reliability of the time code forming pulse by determining the pulse width of the time code forming pulse Formation pulse reliability determination means 334, field strength display means 335a, field strength display means 335a including control means for displaying the field strength, field strength determination means 336 for determining the field strength of the received standard time radio wave, and reception A frequency identification signal generation means 337, a power supply state determination means 338, a reception frequency display means 335b, And time code form the pulse reliability display means 335c, and a power status display means 335 d, and the signal voltage conversion unit 339, and a receiving unit power supply forming means 340 for supplying power to each unit of the radio wave receiving unit 300. Further, the receiving unit power supply forming means 340 is provided with external power supply connecting means supplied with power from outside and switching means for switching the external power supply to be connected.

  In the configuration of FIG. 1, the program timer body 100 includes a time encoding unit 126, a time data generation unit 127, and a radio wave intensity determination unit 128, but the setting device 300 includes a time encoding unit, a time data generation unit, and a radio wave intensity. You may provide a production | generation means.

  Further, in order to synchronize the operation of the clock means 135 of the program timer main body 100 and the clock means 240 of the setting device 200, the program timer main body 100 outputs a synchronization signal based on the signal of the clock means 135. The setting device 200 includes a synchronization input determination unit 249 that determines a synchronization signal from the synchronization output generation unit 144, a synchronization start signal generation unit 236 that outputs a synchronization start signal based on the signal of the clock unit 240, and a setting Connector connection determining means 237 for determining that the connector is connected when the device 200 is attached to the program timer main body 100.

  Hereinafter, the synchronization operation of each clock means between the program timer main body 100 and the setting device 200 will be described in detail. First, when the setting device 200 is connected to the program timer main body 100, the setting device 200 determines that it is connected to the program timer main body 100 from the determination output of the connector connection determination means 237. Thereafter, when 30 seconds have elapsed as a result of the time measured by the clock means 240, a synchronization start signal is sent from the synchronization start signal generation means 236 to the synchronization output generation means 144 of the program timer body 100. Upon receiving the synchronization start signal, the synchronization output generating means 144 clears the count value of the built-in counter to 0, and thereafter sends the synchronization signal to the setting device 200 every minute. The setting device 200 corrects the time measured by the clock means 240 every minute according to the synchronization signal. Thereafter, the correction operation is continued while the setting device 200 is connected to the program timer main body 100.

In the setting device 200, the time of the control output ON operation from the control output means 137, 138 to the external device is set by a program. The control output ON operation from the control output means 137, 138 to the external device is set. In order to accurately match the timing of the analog clock means when the time measured by the analog clock means reaches the set time in the program, a little before the time when the control signal is actually output from the control output means 137, 138, The output from the program determination means 245 of the setting device 200 needs to be given to the program timer body 100. Therefore, the time ΔT required to give the output of the program determination means 245 to the program timer body 100 is set as follows.
ΔT> t1 + t2 + t3
(T1: Time required to detect the synchronization input by the program timer body 100, t2: Processing time from when the synchronization input is received by the setting device 200 until actual output is performed, t3: Synchronization input by the program timer body 100 (The difference between the clock times of the clock means 240 of the setting device 200 and the clocking device 135 of the program timer main body 100, which is generated from the detection until the output is actually performed by the setting device 200)
Note that the program timer main body 100 and the setting device 200 have a sub-clock provided from a crystal oscillation circuit (for example, the crystal oscillation circuit 155 in FIG. 15) as a synchronous input.

  For example, if the synchronization input is detected when the program timer body 100 and the setting device 200 receive the synchronization input given every 30 ms twice, the time t1 required to detect the synchronization input is 30 ms ≦ t1 ≦. 60 ms. If the internal processing time of the program determining means 245 of the setting device 200 is α (≦ 10 ms), the processing time t2 from when the setting device 200 accepts the synchronization input until the actual output is performed is 30 ms + α ≦ t2 ≦ 60 ms + α. It becomes. Furthermore, if the above-described time correction is performed every minute when 30 seconds have elapsed from every minute (when the second hand points to 12), the clock means 240 of the setting device 200 and the clock of the program timer main body 100 The time difference t3 with the means 135 is −5 ms ≦ t3 ≦ 5 ms. Here, 5 ms is the maximum value of the oscillation error of the crystal resonator constituting the crystal oscillation circuit of the program timer body 100.

  From the above, ΔT> 125 ms. Therefore, in the present embodiment, the program determination unit 245 of the setting device 200 sets the program timer body 100 to the program timer main body 100 500 ms before the set time of the program for turning on the control output from the control output units 137 and 138 to the external device. The output is given.

  Next, various settings of the program timer will be described. As shown in FIG. 4, the setting device 200 switches the display state on the display unit 201, sets a control program including a notification sound signal generation program stored in the notification sound signal storage unit 241, and based on the control program. A mode change switch 204 is provided for executing a program and switching modes such as recording / playback / editing.

  In addition, the program timer of this embodiment includes two control output units 137 and 138 for controlling the operation of external devices with different programs. The setting device 200 controls the output of the control output units 137 and 138. The control program to be set can be set, confirmed, and changed. In the following description, two circuits that can be controlled by the respective control output means 137 and 138 are referred to as “circuit 1” and “circuit 2”, respectively.

  The mode change switch 204 is provided on the left side of the display and is configured by using a slide switch 204a that is slid in the vertical direction. Various modes are selected depending on the slide position of the slide switch 204a. In this mode switch 204, (1) a normal (time display) mode in which time display (displays day of the week, hour, minute, etc.) is performed on the time display unit 201a, and (2) year / month / day or hour / minute / second are displayed. Clock adjustment mode that allows you to set and change the date or hour / minute / second, and (3) “Circuit 1” weekly program setting that accepts the display and switch operations necessary to set the weekly program of “Circuit 1” (4) “Circuit 1” weekly program call mode that accepts display and switch operations necessary for confirming / changing the setting contents of the weekly program of “Circuit 1” or canceling the setting contents; ) “Circuit 1” holiday program setting mode for accepting display and switch operations necessary for setting the “Circuit 1” holiday program; and (6) “Circuit 1” holiday program. "Circuit 1" holiday program call mode that accepts display and switch operations necessary to confirm / change the setting contents of the program and cancel the setting contents, and (7) To set the weekly program of "Circuit 2" "Circuit 2" weekly program setting mode that accepts the necessary display and switch operation, and (8) Display necessary to confirm / change or cancel the setting contents of the weekly program setting of "Circuit 2" “Circuit 2” weekly program call mode for accepting switch operation; (9) “Circuit 2” holiday program setting mode for accepting display and switch operation necessary for setting the holiday program of “Circuit 2”; 10) Display and switch operation necessary to confirm / change the setting contents of the holiday program of “Circuit 2” or cancel the setting contents "Circuit 2" holiday program call mode, (11) Reproduction of notification sound signal (chime sound, melody, announcement) stored as digital signal, recording of sound signal converted from analog signal into digital signal and stored Reproduction / Recording / Editing for Accepting Display and Switch Operations Necessary for Editing Notification Audio Signals Stored as Digital Signals, and Adjusting Output Levels between Multiple Notification Audio Signals Stored in Notification Audio Signal Storage 241 Switches to and from mode.

  The various setting switches 202a to 202s are assigned to the respective functions in each mode. With the setting device 200 attached to the program timer body 100, the (1) normal (time display) mode is used. A reception day confirmation switch is assigned to the switch 202a, and a forced reception setting switch is assigned to the switch 202b.

  Each of the switches 202m to 202r is composed of a push button that allows a seesaw operation in the vertical direction and two switches that are turned on and off by the operation of the push button. When the upper side is pressed, 1 is added, and when the lower side is pressed, 1 is subtracted. When the push button is kept pressed, the value is continuously added or subtracted, and processing corresponding to the added value and the subtracted value is performed. Further, the switches 202a to 202i are well-known push switches composed of push buttons and switches. These switches are mounted on a printed circuit board.

  Hereinafter, the operation of correcting the current time of the clock means 135 and 240 based on the standard time will be described with reference to FIGS.

  First, a long wave that conveys Japan Standard Time with high accuracy is a radio wave operated by the National Institute of Information and Communications Technology, which is called a standard radio wave by the National Institute of Information and Communications Technology. Is called a standard time radio wave to clearly express that it is a radio wave including time information. This standard time radio wave is transmitted at a frequency of 40 KHz from the Fukushima long wave station (Otakadoyayama) and at a frequency of 60 KHz from the Kyushu station (mountain Hagane). This standard time radio wave varies depending on the distance from the long wave station, and the location of the antenna (for example, terrain, buildings, etc.), the influence of the weather and ionospheric conditions, and the transmission of power towers, high voltage lines, television and radio In addition to being affected by electric or magnetic fields from towers, train overhead lines, etc., they are blocked or reflected by operations of aircraft, trains, automobiles, and the like.

  When such a standard time radio wave is received by the radio wave receiving means 331, radio wave noise close to the frequency of the standard time radio wave generated from an electronic device in an aircraft, train, automobile, factory, office, etc. is also captured at the same time. The electric signal in the means 331 includes not only an electric signal based on the standard time radio wave but also an electric signal due to radio noise close to the frequency of the standard time radio wave, a partially missing electric signal, and the like. There is a signal.

  Then, the time code forming pulse generating means 333 generates a time code forming pulse including a pulse for forming a time code of the standard time from the standard time radio wave. The time code forming pulse includes the signal voltage converting means 339 and the terminal block 341. , 146, and signal voltage conversion means 142, and input to time encoding means 126 of program timer body 100.

  The time encoding unit 126 uses the time code forming pulse as the time code of the standard time, the time data generating unit 127 generates the standard time from the time code of the standard time, and the radio wave reception control unit 129 generates the generated standard. Based on the time, an instruction to correct the current time of the clock means 135 is given to the time correction means 148, and the time correction means 148 corrects the current time of the clock means 135 according to this instruction.

  Further, the generated standard time is input to the radio wave reception control means 246 of the setting device 200 via the connectors 145 and 229, and the radio wave reception control means 246 determines the time of the clock means 240 based on the generated standard time. An instruction to correct the current time is given to the time adjusting means 233, and the time adjusting means 233 corrects the current time of the clock means 240 according to this instruction.

  The time encoding state in the time encoding unit 126 and the time data generation state in the time data generation unit 127 are stored in the radio wave reception operation control state storage unit 149.

  The current time adjustment operation is performed by an automatic reception operation or a forced reception operation. During the automatic reception operation, the standard time radio wave is periodically received by the radio wave reception unit 331, and the radio wave reception control unit 129 is in a radio wave reception operation control state. If the time encoding state stored in the storage unit 149 is a state in which the generated time code forming pulse is the time code of the standard time, the clock unit 135 is configured based on the standard time generated from the time code. An instruction to correct the current time is given to the time correction means 148, and the radio wave reception control means 246 also gives an instruction to correct the current time of the clock means 240 to the time correction means 233.

  At the time of forced reception, if the forced reception setting switch 202b is manually operated, the radio wave receiving means 331 forcibly receives the standard time radio wave. Then, the radio wave reception control unit 129 causes the time encoding unit 126 to try the time encoding using the time code forming pulse generated by the forced reception as the time code of the standard time, and the standard generated from the time code. Based on the time, an instruction to correct the current time of the clock means 135 is given to the time correction means 148, and the radio wave reception control means 246 also gives an instruction to correct the current time of the clock means 240 to the time correction means 233.

  FIGS. 6A to 6D are diagrams showing schematic signal waveforms until a time code forming pulse is generated from the standard time radio wave of the program timer according to the embodiment of the present invention. From the long wave station, a standard time signal with a pulse width of 0.2 s ± 5 ms as a marker (M) and a position marker (P0 to P5), a standard time signal with a pulse width of 0.8 s ± 5 ms as a binary number, and a binary number 1, a standard time radio wave having a pulse width of 0.5 ms ± 5 ms is transmitted by a carrier wave having a frequency of 40 KHz or 60 KHz. 6A to 6D show examples in which the time code of the standard time of the long wave station is 25 minutes.

  FIG. 6A shows a standard time radio wave in the long wave station, and since the transmission output of the long wave station is determined, the strength of the standard time radio wave is constant.

  FIG. 6B shows an electric signal waveform obtained from the standard time radio wave received by the radio wave receiving means 331. The electric signal waveform of the radio wave receiving means 331 includes an electric signal waveform including signal level noise (0 second to 1 second), an electric signal waveform including swell (1 second to 2 seconds), and an electric signal waveform including narrow noise. (2 seconds to 3 seconds), electrical signal waveform including low level noise (3 seconds to 4 seconds), weak standard time radio signal waveform (4 seconds to 5 seconds), strong standard time radio signal waveform ( 5 seconds to 6 seconds), an electric signal waveform including high level noise (6 seconds to 7 seconds), a standard time signal waveform lacking a signal (7 seconds to 8 seconds), and the like.

  FIG. 6C shows a rectangular pulse in which the time code is inverted with the output waveform of the decoder circuit input to the decoder circuit after full-wave rectification by performing gain control on the electric signal waveform of the radio wave receiving means 331 and envelope detection. This is an electric signal waveform including In this decoder circuit, an electric signal waveform of 48 dB or more and 110 dB or less and having a pulse width longer than 0.1 s and shorter than 0.3 s is recognized as a marker (M) or a position marker (P0 to P5). An electric signal waveform having a pulse width longer than 0.35 s and shorter than 0.55 s is recognized as a binary number 1, and an electric signal waveform having a pulse width longer than 0.65 s and shorter than 0.85 s is binary. It is recognized as 0. Also, the noise of the electric signal waveform whose pulse rise is not 1 second apart, the electric signal waveform with a narrow width, and the electric signal waveform of a low level are ignored.

  From the electric signal waveform of the radio wave receiving means 331 (FIG. 6B) to the formation of an electric signal waveform (FIG. 6C) including a rectangular pulse obtained by inverting the time code is performed by the time code receiving IC. . This receiving IC has a function of confirming the pulse width or the rising interval of the rectangular pulse of the time code, and an inappropriate rectangular pulse due to a change in noise or electric field strength is not output from the decoder circuit.

  FIG. 6D shows a time code forming pulse after signal voltage conversion of a time code pulse generated by inverting the output waveform of the decoder circuit. This time code forming pulse is a delay of the standard time radio wave, a delay due to the rise characteristic of the electronic circuit for gain control of the electric signal waveform, and a rectangular pulse of the electronic circuit that detects the electric signal waveform after gain control to make a rectangular pulse. Although a slight delay occurs compared to the rising of the standard time radio wave of the long wave station due to a delay due to the rising characteristic, etc., this slight delay is not mentioned in the present invention.

  FIG. 4 shows the state of the display unit 201 in the (1) normal (time display) mode in a state where the setting device 200 is attached to the program timer main body 100. The display unit 201 includes a time display unit 201a. In addition to the current time (time, day of the week) displayed on the day of the week display unit 201b, a unit connection state display unit 201c, a radio wave intensity display unit 201d, and a reception completion display unit 201e are displayed.

  The reception unit connection state display unit 201c is lit when the radio wave reception unit 300 is correctly connected, the power is normally supplied from the program timer main body 100, and the signal is normally transmitted from the radio wave reception unit 300. Further, it blinks at 2 Hz when the connection state such as erroneous connection or non-connection is abnormal, when the signal from the radio wave reception unit 300 is abnormal, or when there is no signal from the radio wave reception unit 300. The reception unit connection state display unit 201c corresponds to the reception unit connection state display unit 235c in FIG. 1, and the radio wave reception control unit 246 includes a radio wave reception unit connection state determination unit and performs display control.

  The radio wave intensity display unit 201d determines the radio wave state in four stages based on the data of the electric field intensity and the radio wave reliability from the radio wave receiving unit 300, and displays them with three bars according to the determination result. Three bars are lit when the radio wave condition is the best, two bars are lit when the level is medium, one bar is lit when the level is low, and it is not lit when the level is worst. In FIG. 1, the radio field intensity display unit 201 d corresponds to the radio field intensity display unit 235 a, and the radio field intensity determination unit 128 includes the electric field intensity determined by the electric field intensity determination unit 336 and the time code formation pulse reliability determination unit 334. The radio wave reception control means 246 displays the radio wave intensity on the radio wave intensity display means 235 based on the reliability of the time code forming pulse determined in step S2.

  The reception completion display unit 201e can obtain the standard time signal from the standard time radio wave received by the radio wave receiving unit 300 during the forced reception operation or automatic reception operation, and can correct the current time of the clock means based on the standard time. Turns on when it is possible, and turns off when the standard time cannot be obtained and the time cannot be corrected. When the forced reception setting switch 202b is pressed, the reception completion display unit 201 blinks. The reception completion display unit 201e corresponds to the reception completion display unit 235b in FIG. 1, and the radio wave reception control unit 246 displays a reception status determination unit that displays a reception completion state when the current time is successfully corrected. Provide display control.

  Further, FIG. 7 is a diagram showing the display unit 201 during confirmation of reception day of the week that displays the day of the week when the standard time radio wave is received and the current time of the clock means is corrected. When the setting device 200 is attached to the program timer main body 100, when the mode selector switch 204 is switched to the normal (time display) mode and the reception day confirmation switch 202a is pressed, the standard time signal is received one week before that day. The standard time signal is obtained from the day of the week (day of the week display unit 201b) for which the current time of the clock means can be corrected based on the standard time, and is displayed blinking at 1 Hz together with the reception day confirmation in-progress display unit 201f. The blinking display of the day of the week is performed only for a predetermined time (for example, 30 seconds) after the reception day confirmation switch 202a is pressed, and when the predetermined time is passed, the display of the current day of the week is returned. If the reception day confirmation switch 202a is pressed while the day of the week is blinking, the blinking day of the week is turned off and the current day of the present time is turned on. In the reception day confirmation operation in FIG. 1, the reception day of the week when the standard time radio wave is received and the current time of the clock means is corrected is stored in the radio wave reception control storage means 247 and operated by the reception confirmation operation means 232b. The reception day of the week is displayed on 235 and controlled by the radio wave reception control means 246.

  In addition, the frequency selection means 332 in FIG. 1 can select which radio wave is received among standard time radio waves with a carrier frequency of 40 KHz or 60 KHz. Further, a signal corresponding to the frequency selected by the reception frequency identification signal generation means 337 is generated, and the selected frequency is displayed on the reception frequency display means 335b. In the present embodiment, any one of the 40 KHz reception display LED 306a and the 60 KHz reception display LED 306b is lit.

  The reliability of the time code formation pulse determined by the time code formation pulse reliability determination means 334 is displayed on the time code formation pulse reliability display means 335c. In the present embodiment, the reliability display LED 308 shown in FIG.

  The state of the external power source connected to the receiving unit power source forming unit 340 is determined by the power source state determining unit 338 and displayed on the power source state display unit 335d. In the present embodiment, the power supply status display LED 310 shown in FIG.

  FIG. 8 is a flowchart showing a part of the main routine of the program for controlling the operation of the program timer. Initial processing (step S1), power failure mode processing (step S2), analog clock processing (step S3), radio wave reception processing (Step S4), manual switch control (Step S5), and the like.

  In the initial processing of step S1, the state of the internal registers is reset to the initial state.

  In the power failure mode processing of step S2, the operation is switched to the operation by the power failure compensation battery at the time of commercial power failure.

  In the analog clock control in step S3, a process of periodically sending a notification voice storage update command from the setter control circuit 253 to the notification voice control circuit 273 is performed.

  In the radio wave reception process of step S4, the current time of the clock means 135 and 240 is corrected based on the standard time radio wave received by the radio wave receiving unit 300.

  In the manual switch control in step S5, the switch operation of the program timer body 100 is determined.

  FIG. 9 is a flowchart showing the radio wave reception process in step S4 in the program timer body 100. First, it is determined whether or not the radio wave receiving function is provided (step S10). In this embodiment, it is determined that the radio wave receiving unit 300 is connected to the program timer main body 100 and has a radio wave receiving function. However, if the radio wave receiving unit 300 is not connected, it is determined that the radio wave receiving unit 300 is not equipped with a radio wave receiving function. Then, the process ends.

  If it is determined that the radio wave reception function is provided, detection data processing is performed based on the time code forming pulse transmitted from the radio wave reception unit 300 (step S11), and then the electric field strength and radio wave reliability from the radio wave reception unit 300 are processed. Radio wave intensity data processing is performed to determine the radio wave intensity based on each signal (step S12). Next, whether or not the radio wave receiving unit 300 is correctly connected to the program timer main body 100, a signal from the radio wave receiving unit 300 is determined. A receiving unit connection state check is performed to determine whether or not is normal (step S13), and this process ends.

  FIG. 10 is a flowchart showing the detection data processing in step S11 in the program timer body 100. First, it is determined whether or not the noise prevention timer is operating (step S20). This noise prevention timer ignores a signal input during 900 ms from the rise of the time code forming pulse transmitted from the radio wave receiving unit 300. If the noise prevention timer is in operation, this process ends. . If the noise prevention timer is not in operation, the operation proceeds to each operation according to the current phase 1 operation (step S21).

  Hereinafter, the operation of Phase 1 will be described using the pulse waveform of 200 ms in FIG. First, if it is in the instruction waiting (initial value) state, it shifts to a pulse-off waiting state (step S22) (this state is indicated by a in FIG. 11), and this processing is terminated.

  If it is in the pulse-off waiting state, it is determined whether or not the pulse is off (step S23). If the pulse is not off, this process is terminated. If the pulse is off (this state is indicated by b in FIG. 11), the process shifts to a pulse-on waiting state (step S24) and the process is terminated.

  If it is in the pulse-on waiting state, it is determined whether or not the pulse is on (step S25). If the pulse is not on (this state is indicated by c in FIG. 11), this process is terminated. If the pulse is on (this state is indicated by d in FIG. 11), the process proceeds to the pulse measurement (step S26), the pulse length measurement is started (step S27), and this process is terminated.

  If the pulse measurement is in progress, it is determined whether or not the pulse is off (step S28). If the pulse is not off, this processing is terminated (this state is indicated by e in FIG. 11). If the pulse is off (this state is indicated by f in FIG. 11), the process shifts to a pulse-on waiting state (step S29), and the pulse length is determined (step S30). The determination of the pulse length is OK if it is 200 ms ± 100 ms, 500 ms ± 100 ms, 800 ms ± 100 ms, NG if it is outside the above range, and if the determination of the pulse length is OK, the pulse interval is determined. (Step S31) If the determination of the pulse length is NG, this process is terminated.

  To determine the pulse interval, the pulse interval checker is operated for 1800 ms from the falling edge of the pulse, and when the falling edge of the next pulse occurs outside the range of 1800 ms (NG), the block work buffer BB described later is initialized. (Step S32).

  Then, after initialization of the block work buffer BB or when the next pulse falls within the range of 1800 ms in the determination of the pulse interval (OK), data analysis processing is performed (step S33), and the noise prevention timer Is started (step S34), and this process is terminated.

  Note that the check interval T1 in FIG. 11 is several ms.

  Next, FIGS. 12A to 12I show the flow of the data analysis process in step S33 in the time encoding unit 126 and the time data generation unit 127 at the time of automatic reception. First, data is sequentially stored in the 60-digit block back buffer BB until the minute position is determined (FIG. 12A). When the marker M is generated twice and the marker M is generated 9 seconds after the second marker M and the minute position is determined, only the minute data is transferred to the first-stage buffer FB (FIG. 12B). ).

  Next, the subsequent data is stored in the first stage buffer FB (FIG. 12C).

  Next, when the data in the first stage buffer FB is completed, the data is digitized and stored in the reception buffer RB (FIG. 12 (d)).

  Next, it is checked whether or not there is an impossible value in the data in the reception buffer RB, and the validity is checked. If the data is valid, a carry is performed for one minute (FIG. 12 (e)).

  Next, the data in the reception buffer RB is stored in the comparison buffer CB (FIG. 12 (f)).

  Then, the processing shown in FIGS. 12A to 12D is performed on the next one-minute data, and the data in the reception buffer RB is compared with the data in the comparison buffer CB (FIG. 12G). If the results match, the date is calculated from the total date of the data in the reception buffer RB and stored in the communication buffer AB (FIG. 12 (h)). Only when the “hour”, “day”, “month”, or “year” has changed, the data in the communication buffer AB is carried by one minute, and the data is transmitted to the setting device 200 at the next 0 second timing ( FIG. 12 (i)).

  During automatic reception, the above operation is repeated every minute.

  Further, FIGS. 13A to 13G show the flow of the data analysis process in step S33 during forced reception. First, data is stored in order in the 60-digit block back buffer BB until the minute position is determined (FIG. 13A). When the marker M is generated twice and the marker M is generated 9 seconds after the second marker M and the minute position is determined, only the minute data is transferred to the first-stage buffer FB (FIG. 13B). ).

  Next, the subsequent data is stored in the second-stage buffer SB (FIG. 13C).

  Next, when the marker M is stored in the second-stage buffer SB, it is determined whether the first-stage buffer FB and the second-stage buffer SB are valid. If the second-stage buffer SB is valid, the second-stage buffer SB is determined. The data in the buffer SB is stored in the first stage buffer FB (FIG. 13 (d)).

  Next, the processing in FIG. 13D is repeated, and when the data in the first-stage buffer FB is completed, the data is digitized and stored in the reception buffer RB (FIG. 13E).

  Next, it is checked whether or not there is a numerical value that is not possible in the data of the reception buffer RB, and the validity is checked. If the data is valid, a one-minute carry is performed (FIG. 13 (f)).

  Next, the data in the reception buffer RB is stored in the comparison buffer CB, and a carry is performed for every 0 second until the comparison data is completed in the reception buffer RB (FIG. 13 (g)).

  Then, the processes shown in FIGS. 13A to 13E are performed on the data after the next one minute.

  Next, the data in the reception buffer RB and the data in the comparison buffer CB are compared (FIG. 13 (h)). If the comparison results match, the date is calculated from the total date of the data in the reception buffer RB, The data is stored in the communication buffer AB (FIG. 13 (i)), the data in the communication buffer AB is carried by one minute, and the data is transmitted to the setting device 200 at the next 0 second timing (FIG. 13 (j)). .

  If there is no data in the communication buffer AB even after 15 minutes from the start of forced reception, the reception operation is forcibly terminated.

  In FIG. 14, a program timer is installed in an office or the like, and lighting control of the lighting 530 is controlled via the control panel 520 in the factory C by the control of the program timer (the power for lighting is supplied from the distribution board 510). Alternatively, a configuration example is shown in which generation control of a chime sound that notifies start time, end time, and rest time from the speaker unit 500 or a melody that is played as BGM such as rest time is shown through the notification sound signal amplifying apparatus 400. The program timer main body 100, the setting device 200, and the notification sound signal amplifying device 400 are installed in the office A, and a human body sensor 410 and a call switch 420 are set at the entrance of the office A to detect the visitor.

  In another office B, a radio wave receiving unit 300 is arranged and connected to a terminal block TBA of the program timer main body 100 in the office A via a cable L. Make corrections. The notification sound output from the speaker unit 600 in the separate office B is turned on / off not only by the set time by the program but also by external interrupt control by the non-voltage contact output of the human body sensor 410 and the call switch 420.

  In the system explanatory diagram of FIG. 14, the radio wave receiving unit 300 is installed in another office B. However, the radio wave receiving unit 300 according to the present embodiment can be attached to the vicinity of the program timer body 100 or to the outdoor side wall of the building. It has a rainproof structure.

  Next, FIGS. 15 to 17 show the schematic configuration of the program timer of FIG. 1 with specific circuits. FIG. 15 shows a specific circuit configuration of the program timer body 100, FIG. 16 shows a specific circuit configuration of the setting device 200, FIG. 17 shows a specific circuit configuration of the radio wave receiving unit 300.

  The program timer body 100 and the setting device 200 are connected via connectors CN6a-CN6b (connectors 109-207), and the setting device 200 and the radio wave receiving unit 300 are connected via terminal blocks TB2-TB3 (terminal blocks 146-341). Connected.

  The program timer body 100 includes a power supply board 100a, a control board 100b, and a switch board 100c. The power supply board 100a and the control board 100b are connected by connectors CN3a and CN3b, and the control board 100b and the switch board 100c are connected by connectors CN4a and CN4b. And connectors CN5a to CN5b.

  The power supply board 100a is mounted with a main body power supply circuit 150, a notification sound signal amplification circuit 165, a relay drive circuit 169, a reception circuit 171, and a notification sound signal jack 173, and is connected to both ends of the transformer 151 via connectors CN7 and CN8. Yes.

  The control board 100b includes a main body signal power supply circuit 152, a power failure compensation battery 153, a main body control circuit 154, a crystal oscillation circuit 155, a test frequency oscillation circuit 157, a main body / setting device switching circuit 158, a liquid crystal 160, a key matrix 163, and a notification sound. An amplifier circuit 164, an amplifier circuit (microphone) 168, a main body I / O unit 172, and a reset circuit 174 are mounted, and an analog clock unit 159 is connected.

  The switch board 100c is mounted with a manual output changeover switch 159, a microphone signal input jack 167, and a relay output display circuit 170.

  The setting device 200 includes a setting device power supply circuit 250, a power failure compensation battery 251, a notification voice recording / reproducing circuit 252, a setting device control circuit 253, a main body / setting device switching circuit 254, a clock oscillation circuit mounted on the setting device board 200a. 255, 267, 274, reset circuit 256, test frequency oscillation circuit 257, liquid crystal 261, storage circuit 262, operation unit 265, key matrix 266, amplification circuit 269, key reception sound oscillation circuit 271, setting device I / O unit 272, A notification voice control circuit 273, a recording signal input jack 268, and a setter built-in speaker 270 connected to the setter board 200a via a connector CN7 are provided.

  The radio wave reception unit 300 includes a reception unit power supply circuit 350, a radio wave reception control circuit 351, a bar antenna 352, a radio wave reception circuit 353, a communication circuit 354, a reset circuit 355, a clock oscillation circuit 356, and a reception frequency display. An LED 306 (306a, 306b), an electric field intensity display LED 307, and a time code forming pulse reliability display LED 308 are mounted on the reception unit substrate 300a.

  First, the program timer body 100 will be described. The main body power supply circuit 150 supplies power from a commercial power source to each circuit to be described later, and includes a rectifying / smoothing circuit that rectifies and smoothes the output of the transformer 151 that steps down the commercial power source, and a step-down circuit that further steps down the main power source circuit 150. Power is also supplied to each circuit such as the signal power circuit 152, the setting device power circuit 250 of the setting device 200, and the receiving unit power circuit 350 of the radio wave receiving unit 300.

  The main body signal power supply circuit 152 and the setting device power circuit 250 of the setting device 200 are connected to power failure compensation batteries 153 and 251 such as nickel / hydrogen batteries as emergency power supplies in the event of a power failure. Charging / discharging of the batteries 153 and 251 is switched by a charging / discharging switching circuit (not shown). In other words, the charging / discharging switching circuit charges the power failure compensation batteries 153 and 251 with the output of the main power supply circuit 150 when supplying commercial power, and the power failure is performed with the setting device 200 and the radio wave receiving unit 300 attached to the program timer main body 100. When this happens, the power failure compensation battery 153 of the program timer main body 100 is supplied to the setting device power supply circuit 250 and the receiving unit power supply circuit 350 as an external battery. In the setting device 200, when the power failure compensation battery 153 of the program timer main body 100 is exhausted, power is supplied from its own power failure compensation battery 251. When the setting device 200 is detached from the program timer main body 100, the charging / discharging circuit operates to supply power from the own power failure compensation battery 251.

  Further, the connector CN1a is connected to the power failure compensation battery 153, and this connector CN1a can be connected to the connectors CN1b and CN1c connected to the inputs of the setting device power supply circuit 250 and the receiving unit power supply circuit 350. The compensation battery 153 can be easily connected to the setter power supply circuit 251 or the reception unit power supply circuit 350 as an external battery. For example, power is supplied from the power failure compensation battery 153 of the program timer body 100 to the setter power supply circuit 250 via the CN1a and CN1c in the playback / recording / editing mode in which the power consumption of the setter 200 increases. Further, in order to detect battery exhaustion, the main body signal power supply circuit 152 and the setter power supply circuit 250 are provided with a battery voltage detection circuit, and the charge / discharge switching circuit is also operated when checking the battery capacity.

  The main body control circuit 154 is used as a main body control function because one microcomputer that performs a central function incorporates two control functions of the program timer main body 100 and the setting device 200. A main body / setting device switching circuit 158 is provided as a peripheral configuration of the microcomputer. Furthermore, a crystal oscillation circuit 155 that oscillates a main body control circuit clock, a test frequency oscillation circuit 157, and a reset circuit 174 that resets the main body control circuit 154 at the time of start-up are similarly provided as peripheral configurations of the microcomputer, and the main body control circuit 154 Performs signal processing such as ringing control of a chime sound, control of an external device, or drive control of the analog clock unit 159.

  The main body control circuit 154 has a built-in liquid crystal drive circuit 156, which selects the output state by operating the manual output changeover switch 159 (control output manual operation switches 104a and 104b) or determining external interrupt input, and each program. Is displayed on the liquid crystal 160.

  The main body control circuit 154 is provided with operation input of each switch and input signals from the setting device 200, the radio wave receiving unit 300, and an external device. For example, the manual output changeover switch 159 (control output manual operation switches 104a and 104b), the operation input of the analog clock adjustment switch 104c, the input signal from each switch of the setting device 200, and the manual output changeover switch 159 operate the external device. Input signal from an external interrupt output selection switch that selects whether or not to output a notification sound, an input signal of a melody selection switch that selects whether or not a notification sound rings and a melody number, a human body detection sensor 410, These include an external interrupt input signal corresponding to a non-voltage contact output of an external device such as a call button 420, an input signal of an external interrupt melody selection switch for selecting a melody number in accordance with the external interrupt input signal, and the like. The external interrupt output selection switch, melody selection switch, and external interrupt melody selection switch are provided inside the program timer main body 100. An input from the switch board 100c is input through a key matrix 163, and the key matrix 163 is provided as a peripheral configuration of the microcomputer.

  Also, the main body control circuit 154 includes a manual output changeover switch 159 (control output manual operation switches 104a and 104b), an operation state of the analog clock adjustment switch 104c, an external interrupt input determination state, a melody selection switch, and an external interrupt output selection. A memory circuit 162 for storing the setting states of the switches and the external interrupt melody selection switch, and a communication circuit for performing communication between the main body I / O unit 172 and the setting unit I / O unit 272. 161 is built-in.

  Further, the communication circuit 161 communicates with the communication circuit 354 provided in the radio wave receiving unit 300, and receives a signal indicating a time code forming pulse, a time forming pulse reliability, and an electric field strength. The communication circuit 161 includes signal voltage conversion means 142 that converts the voltage of the electric signal sent from the radio wave receiving unit 300.

  Further, the program timer main body 100 includes a notification sound amplification circuit 164 that amplifies notification sound signals such as various chime sounds or melody by amplifying the notification sound signal from the notification sound recording / reproducing circuit 252 of the setting device 200. The audio amplification circuit 164 is connected to the notification audio signal amplification circuit 165, and the notification audio signal amplification circuit 165 is connected to the built-in speaker 166 via the connector CN2.

  Furthermore, the microphone audio signal from the microphone is input to the notification audio signal amplification circuit 165 via the microphone signal input jack 167 and the amplification circuit (microphone) 168, and the output of the notification audio signal amplification circuit 165 is an internal speaker. 166 and the external speaker output terminal of the terminal block TB1 can be connected, and an external speaker such as the speaker unit 600 can be connected to the external speaker output terminal to output the notification sound.

  The relay drive circuit 169 provided for the program timer main body 100 to generate a control output for controlling the external devices of the circuit 1 and the circuit 2 is used for controlling the relay composed of a two-winding type latching relay and the main body control circuit 154. Accordingly, the relay drive control circuit that controls the drive of the relay is configured, and the control output is output from the terminal block TB1. The main body control circuit 154 is provided with a stable relay driving means so that a single winding type stable relay can be used instead of a two winding type latching relay.

  In addition, a relay output display circuit 170 including a light emitting diode or the like for displaying the state of the relay drive circuit 169 by operation of the manual output changeover switch 159 (control output manual operation switches 104a and 104b) is provided.

  An analog timepiece drive circuit 171 that drives an analog timepiece 159 that includes a motor as a drive source includes a motor drive circuit that drives and controls the motor.

  The main body power supply circuit 150 and the main body signal power supply circuit 152 constitute the main body power supply forming means 147 shown in FIG. 1, the liquid crystal drive circuit 156 and the liquid crystal 160 constitute the output selection / display means 132, and the storage circuit 162 outputs the output. The determination state storage unit 134 is configured, and the main body control circuit 154 performs a time encoding unit 126, a time data generation unit 127, a radio wave intensity determination unit 128, a radio wave reception control unit 129, a switch operation determination unit 130, an external interrupt input determination unit. 131, output selection / display unit 132, output determination unit 133, output determination state storage unit 134, clock unit 135, output control unit 136, signal voltage conversion unit 142, synchronous output generation unit 144, time correction unit 148, radio wave reception operation The control state storage means 149 is configured, and a notification sound amplification circuit 164, a notification sound signal amplification circuit 165, the built-in speaker 166 constitutes a notification voice output means 139 for generating a notification voice, the relay drive circuit 169 constitutes a control output means 137, a control output means 138, and the relay output display circuit 170 provides a manual switch operation display means. 141, the analog timepiece driving circuit 171 forms the analog timepiece means 140, the connector CN3a forms the connector 145, and the terminal block TB2 forms the terminal block 146.

  Next, the setting device 200 will be described. The setter control circuit 253 is used as a main body control function because one microcomputer that performs a central function incorporates two control functions of the program timer main body 100 and the control function of the setter 200. A main body / setting device switching circuit 254 is provided as a peripheral configuration of the microcomputer for switching between the case and the case of using as a setting device control function. Further, a clock oscillation circuit 255, a reset circuit 256 that resets the setter control circuit 253 at the time of startup, and a test frequency oscillation circuit 257 are similarly provided as peripheral configurations of the microcomputer.

  Further, the setter control circuit 253 includes a storage circuit 258 that stores the operation state of the operation unit 265 (switch 202, mode changeover switch 204), and includes a main body I / O unit 172, a setter I / O unit 272, and the like. The communication circuit 259 for performing communication with the program timer main body 100 via the communication terminal 259 is incorporated.

  In addition, a key matrix 266 is provided as an input unit of the setting device control circuit 253, and the key matrix 266 is connected to the operation unit 265.

  Further, the setting device 200 is a storage circuit for reproducing, recording and editing a plurality of notification sound signals such as a chime sound, a melody and an announcement stored in the notification sound storage unit 263 and adjusting an output level between the notification sound signals. 262 is provided with a notification sound control circuit 273 composed of a microcomputer that performs a central function such as a control for calling a notification sound signal stored in 262 and outputting it to the notification sound recording / reproducing circuit 252, and a clock oscillation circuit 267 as its peripheral circuit. , 274 and the reset circuit 256 described above.

  The storage circuit 262 includes a notification sound storage unit 263 that stores a plurality of notification sound signals, and a program storage unit 264 that stores a program set by the operation unit 265.

  When recording the notification sound from an external device, the notification sound signal input from the recording signal input jack 268 of the setting device 200 is input to the notification sound recording / reproducing circuit 252 via the amplifier circuit 269 and recorded. This is performed by being stored in the notification voice storage unit 263 from the circuit 252 via the notification voice control circuit 273.

  Further, when the notification sound is reproduced, the notification sound signal stored in the notification sound storage unit 263 is called, and the notification sound is output from the setting device built-in speaker 270 via the notification sound control circuit 273 and the notification sound recording / reproducing circuit 252.

  In addition, a key reception sound oscillation circuit 271 is provided, so that a reception sound is output from the speaker 270 when the key matrix 266 is operated in accordance with the operation of the operation unit 265, and an alarm sound is output from the speaker 270 when an operation error occurs. Yes.

  Note that the program setting means 230a and 230b, time adjustment means 233, display control means 238, clock setting means 239, clock means 240, notification voice control means 242, program judgment means 245, radio wave shown in FIG. The reception control unit 246, the synchronization input determination unit 249, the synchronization start signal generation unit 236, the connector connection determination unit 237, and the radio wave reception control unit 246 are configured, and the display unit 235 is configured by the LCD drive circuit 260 and the liquid crystal display (LCD) 261. The storage circuit 262 constitutes the program storage means 234 and the notification voice signal storage means 241, and the speaker 270 constitutes the notification voice confirmation means 244.

  Next, the radio wave receiving unit 300 will be described. The radio wave reception control circuit 351 is composed of one microcomputer that performs a central function, and the bar antenna 352 is connected to the program timer main body 100 via the communication circuit 354 as well as being connected via the radio wave reception circuit 353. In addition, a clock oscillation circuit 356, a reset circuit 355 for resetting the radio wave reception control circuit 351 at the time of activation, and the like are provided as peripheral circuits of the radio wave reception control circuit 351.

  The radio wave reception control circuit 351 includes an LED drive circuit, and turns on and off LEDs such as a reception frequency display LED 306, an electric field strength display LED 307, a time code formation pulse reliability display LED 308, and a power supply status display LED 310.

  Further, the receiving unit power supply circuit 350 supplies power to each circuit of the radio wave receiving unit 300. When the power is supplied to the program timer body 100, the cable L is connected between the terminal blocks TB2 and TB3, and the program timer. When the main body 100 and the radio wave reception unit 300 are electrically connected, power is supplied from the main body power supply circuit 150 of the program timer main body 100 to the reception unit power supply circuit 350, and each circuit of the radio wave reception unit 300 operates. To do.

  Further, the receiving unit power circuit 350 includes a connector CN1c to which an external power source can be connected so that it can be used even when the radio wave receiving unit 300 is separated from the program timer body 100. Further, the connector CN1c of the radio wave receiving unit 300 and the connector CN1a of the program timer body 100 are configured to be connectable to each other so that the power failure compensation battery 153 of the program timer body 100 can be used as this external power source.

  Further, the communication circuit 354 transmits signals indicating the time code forming pulse, the time forming pulse reliability, and the electric field strength to and from the communication circuit 161 provided in the program timer main body 100. The communication circuit 354 includes signal voltage conversion means 339 that converts the voltage of the electric signal sent from the radio wave reception control circuit 351.

  The radio wave reception control circuit 351 constitutes the frequency selection means 332, time code formation pulse reliability determination means 334, electric field strength determination means 336, reception frequency identification signal generation means 337, and power supply state determination means 338 in FIG. Frequency display LED 306, electric field strength display LED 307, time code formation pulse reliability display LED 308, and power supply status display LED 310 provide electric field strength display means 335a, reception frequency display means 335b, time code formation pulse reliability display means 335c, and power supply status display means 335d. The radio wave receiving circuit 353 and the bar antenna 352 constitute radio wave receiving means 331 and the time code forming pulse generating means 333, and the radio wave receiving unit power supply circuit 350 constitutes radio wave receiving unit power supply forming means 340.

It is a figure which shows schematic structure of the program timer of embodiment of this invention. It is a perspective view which shows the program timer same as the above. It is a disassembled perspective view which shows a program timer main body and a setting device same as the above. It is a front view which shows the setting device same as the above. It is a perspective view which shows the back surface of the setting device same as the above. (A)-(d) It is a wave form diagram which shows the production | generation operation | movement of the time code formation pulse same as the above. It is a figure which shows the display part during reception day confirmation same as the above. It is a flowchart figure which shows a part of main routine of operation | movement of a program timer main body. It is a flowchart figure which shows an electromagnetic wave reception process. It is a flowchart figure which shows a detection data process. It is a pulse waveform diagram showing detection data processing. (A)-(i) It is a figure which shows the flow of the data analysis process at the time of automatic reception. (A)-(j) It is a figure which shows the flow of the data analysis process at the time of forced reception. It is a figure which shows the example of 1 structure of control using a program timer same as the above. It is a figure which shows the specific circuit structure of a program timer main body same as the above. It is a figure which shows the specific circuit structure of a setting device same as the above. It is a figure which shows the specific circuit structure of a radio wave receiving unit same as the above.

Explanation of symbols

100 Program timer body 200 Setting device 300 Radio wave reception unit 126 Time encoding means 127 Time data generation means 129, 246 Radio wave reception control means 135, 240 Clock means 136 Output control means 148, 233 Time correction means 230a, 230b Program setting means 234 Program storage means 331 Radio wave reception means 332 Frequency selection means 333 Time code forming pulse generation means

Claims (13)

Clock means for measuring the current time, program setting means for setting a program for generating a notification sound or controlling an external device at a desired time, program storage means for storing the set program, and current time Output control means for outputting a control output for generating a notification sound or controlling an external device when it coincides with a set time of a program stored in the program storage means, and a radio wave for receiving a standard time radio wave including a standard time signal Receiving means; frequency selecting means for selecting standard time radio waves received from a plurality of standard time radio waves of different frequencies; and a time code forming pulse including a pulse for forming a time code of standard time from the received standard time radio waves. The time code forming pulse generation means to generate and the generated time code forming pulse to the time code of the standard time A time encoding means, a time data generating means for generating a standard time from the time code, and a radio wave reception control means for giving the time adjusting means an instruction to correct the current time of the clock means based on the generated standard time. A program timer comprising: Radio wave receiving operation control state storage means for storing a time encoding state in the time encoding means and a time data generation state in the time data generation means, and the generated time code forming pulse as a time code of a standard time 2. The program timer according to claim 1, wherein, in the time encoding state, the radio wave reception control unit corrects the current time of the clock unit based on a standard time generated from the time code. Forcibly receiving a standard time radio wave by the radio wave receiving means by manual operation, wherein the radio wave reception control means converts the time code forming pulse generated at the time of forced reception into a time code of a standard time. 2. The program timer according to claim 1, wherein the time encoding means is controlled so as to try and the current time of the clock means is corrected based on a standard time generated from the time code. Electric field strength determining means for determining the electric field strength of the received radio wave, time code forming pulse reliability determining means for determining the reliability of the time code forming pulse based on the pulse width of the time code forming pulse, electric field strength and time code A radio wave intensity determining means for determining a radio wave intensity indicating the possibility that the received radio wave is a standard time radio wave based on the reliability of the formed pulse, and a radio wave intensity display means for displaying the radio wave intensity are provided. The program timer according to any one of claims 1 to 3. The reception status determining means for determining success or failure of the correction of the current time of the clock means, and the reception completion display means for displaying the reception completion status when the correction of the current time is successful. The program timer according to any one of 1 to 4. A reception day of the week storage means for storing the reception day of the week when the standard time radio wave is received and the current time of the clock means is corrected, a reception day of the week display means for displaying the reception day of the week stored in the reception day of week storage means, and manual operation 6. The program timer according to claim 1, further comprising reception day confirmation operation means for displaying the reception day on the reception day display means. The radio wave reception means, the frequency selection means, a reception frequency display means for displaying the frequency of a standard time radio wave selected by the frequency selection means, the time code formation pulse generation means, and the time code formation pulse reliability determination means A radio wave receiving unit comprising: the electric field strength determining unit; an electric field strength displaying unit that displays the electric field strength determined by the electric field strength determining unit; and a signal voltage converting unit that converts a voltage of a signal to be transmitted ;
A program timer body comprising the clock means, the output control means, and a signal voltage conversion means for converting the voltage of the signal transmitted from the radio wave receiving unit ;
The timepiece means, the program setting means, and a setting device comprising the program storage means,
7. The program timer according to claim 1, wherein the radio wave receiving unit and the program timer main body are electrically connected via a cable. The radio wave receiving unit includes a receiving unit power source forming unit including an external power source connecting unit to which power is supplied from the outside, and a switching unit for switching the external power source to be connected.
  A terminal block is provided for each of the program timer main body and the radio wave receiving unit, and both ends of the cable are connected to each terminal block for electrical connection.
  Or, pull out the cable directly from the program timer body and connect it to the terminal block of the radio wave receiving unit to make an electrical connection.
  Or, pull out the cable directly from the radio wave reception unit and connect it to the terminal block of the program timer body to make an electrical connection.
  Or, pull out the cable directly from the program timer body and directly connect the cable to the radio wave receiving unit for electrical connection.
  8. The program timer according to claim 7, wherein: 9. The program timer main body includes a power failure compensation battery used as a power source during a power failure, and the external power connection means of the radio wave receiving unit is configured to be connectable to the power failure compensation battery. Program timer described. Radio wave receiving unit connection status determining means for determining a connection status between the radio wave receiving unit and the program timer main body, and radio wave receiving unit connection status display means for displaying a determination result of the radio wave receiving unit connection status determining means. The program timer according to claim 8 or 9, characterized in that A power supply state determination unit that determines a state of an external power supply connected to an external power supply connection unit of the radio wave reception unit, and a power supply state display unit that displays a determination result of the power supply state determination unit. Item 11. A program timer according to any one of Items 8 to 10. 12. The program timer according to claim 8, further comprising time code forming pulse reliability display means for displaying a determination result of the time code forming pulse reliability determination means of the radio wave receiving unit. The radio wave receiving unit includes reception frequency identification signal generation means for generating a signal corresponding to the frequency of the standard time radio wave selected by the frequency selection means, and the reception frequency display means is output by the output of the reception frequency identification signal generation means. 13. The program timer according to claim 8, wherein the frequency of a standard time radio wave is displayed.