JP2006234717A - Facility equipment control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a facility equipment control system capable of easily setting time-of-day and compensating time-of-day without using a clock terminal with a crystal oscillator with high precision. <P>SOLUTION: A remote controller 30, when the time-of-day excluding a unit of second is set by an operating section 31, maintains the time-of-day, and transmits the time-of-day to a control unit 10, when transmission operation is confirmed, and also starts timing from a zero-second with the time-of-day as the present time. When the transmission operation is confirmed during timing, the time-of-day including the unit of second is transmitted to the control unit 10. The control unit 10, when the time-of-day excluding the unit of second is received, starts timing from a zero-second with receipt time as the present time and, when the time-of-day including the unit of second is received, continues the receipt time as the present time. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a facility equipment control system that automatically controls lighting fixtures and the like of equipment equipment based on a control schedule, and more particularly to a facility equipment control system that sets a time for accurately executing a control schedule. Is.

As a system for performing time schedule control, there is a system comprising a general-purpose personal computer having a time schedule as data, and a clock terminal and a control terminal connected to the personal computer via a transmission line. The general-purpose personal computer transmits control data to the control terminal based on the time schedule, and the control terminal turns on or turns off the lighting device of the load based on the control data. On the other hand, the clock terminal counts the time with a time counting unit using the temperature compensated crystal oscillator as a reference clock so that the general-purpose personal computer can execute the time schedule at an accurate time. A synchronization signal is transmitted to the general-purpose personal computer every time “second” and “30” seconds), and the time of the clock circuit of the personal computer is corrected (for example, see Patent Document 1).
JP 2002-14186 (Page 3-4, FIGS. 1 and 2)

In the conventional system described above, in order to make the time of the clock circuit built in the general-purpose personal computer accurate, a clock terminal equipped with a high-precision crystal oscillator is used on the system. However, the system as a whole is expensive. It has become.
The present invention has been made to solve such a problem, and can easily set the time and correct the time without using a clock terminal equipped with a high-precision crystal oscillator. An object is to provide a control system.

  The equipment control system according to the present invention includes a plurality of control devices connected to a plurality of equipment and controlling each equipment based on a preset control schedule, and a control schedule based on operation of an operation unit. The setting unit holds the time when the time excluding the second unit is set by the operation of the operation unit, and holds the time when the transmission operation is confirmed. When sending to the control device, the time is started from zero seconds with the current time as the current time, and when the transmission operation is confirmed during the time measurement, the time including the second unit is sent to the control device. When a time other than is received, the time starts from zero seconds with the received time as the current time, and when a time that includes seconds is received, the time continues with the received time as the current time. And discrimination information of the current time control schedule execution.

  The setter has correction data for shifting the time by a predetermined time every predetermined period, and transmits the correction data to the control device when the time correction operation is confirmed. The control device receives the correction data. Then, the time is corrected by shifting by a predetermined time every predetermined period.

  In the present invention, the setting device holds the time when the time excluding the second unit is set by the operation of the operation unit, and transmits the time to the control device when the transmission operation is confirmed, and sets the time. Start timing from zero seconds as the current time, and when the transmission operation is confirmed during timekeeping, the time including the second unit is sent to the control unit, and the control unit receives when the time excluding the second unit is received. Time measurement is started from zero seconds with the current time as the current time, and when the time including the second unit is received, the time measurement is continued with the reception time as the current time. Time can be set easily.

  In the present invention, when the setting device confirms the time correction operation, the setting device transmits correction data for shifting the time by a predetermined time every predetermined period to the control device, and the control device receives the correction data, Since the time is corrected by shifting the time by a predetermined time every predetermined period, even if a crystal oscillator with relatively low accuracy is used for the control device 10, the time error during that time can be suppressed as much as possible.

FIG. 1 is a schematic configuration diagram of an equipment control system showing an embodiment of the present invention.
This system includes a plurality of control devices 10, a lighting fixture 20 that is a plurality of equipment connected to each control device 10 via a transmission line 40, and a setting device remote control 30. Each control device 10 includes, for example, a transmission I / F 11 to which a transmission line 40 for distributing a control signal to a plurality of lighting fixtures 20 is connected, a modem (such as an infrared transmitter / receiver) that modulates / demodulates a radio signal, and a signal amplifier. And the like, a time counting unit 13 having a crystal oscillator, an illuminance sensor 14, and a microcomputer 15 (hereinafter simply referred to as "microcomputer"). In addition, the signal transmitted from the transmission I / F 11 described above may be a dimming signal for directly adjusting the brightness of the lighting fixture 20 in addition to a signal for controlling the lighting fixture 20 to be controlled.

  The microcomputer 15 of the control device 10 controls the plurality of lighting fixtures 20 on the transmission line 40 based on the control schedule set by the remote controller 30 (all light lighting, dimming lighting, extinguishing, etc.). Although not shown, the control is started when the time described on the control schedule matches the time of the time counting unit 13. When the day of the week and the time excluding the second unit are received through the transmission / reception unit 12, the day of the week is set in the time counting unit 13, the reception time is set in the time counting unit 13 as the current time, and time measurement is started from zero seconds. When the time including the second unit is received, the reception time is set in the time counting unit 13 as the current time, and the time measurement is continued. When correction data to be described later is received, the time of the time counting unit 13 is corrected based on the correction data. When the time is read, the current time (including seconds) measured by the time counting unit 13 is transmitted from the transmitting / receiving unit 12.

  The remote controller 30 includes an operation unit 31 in which various operation buttons are arranged, a liquid crystal display unit 32, a modem (for example, an infrared transmitter / receiver) that modulates / demodulates a radio signal (for example, an electromagnetic wave such as radio waves and infrared rays), a signal amplifier, and the like. The transmission / reception unit 33 includes a time counting unit 35 including a crystal oscillator, and a microcomputer 35 (hereinafter simply referred to as “microcomputer”). Note that the remote controller 30 shown in the figure shows a state in which the door is opened. The microcomputer 35 of the remote controller 30 displays the time setting screen on the liquid crystal display unit 32 when the time setting button 31a of the operation unit 31 is pressed and held, and then displays the day of the week on the time setting screen according to the operation of the button 31a. To do. Further, based on the operation of the light / dark button 31b for dimming setting, the “hour / minute” time (excluding the second unit) is displayed on the time setting screen and the time is held, and then the transmission button 31c is pressed. The stored day of the week and time are transmitted to the control device 10 to be transmitted via the transmission / reception unit 33, and time measurement is started from zero seconds with the stored time as the current time.

  When the reception button 31d is pressed, a time readout signal is transmitted to the transmission target control device 10 via the transmission / reception unit 33, and when the time being measured is received by the readout signal, it is displayed on the time setting screen. To do. At this time, timing is continued with the reception time as the current time. When the transmission button 31c is pressed in this state, the time being measured (including the second unit) is transmitted to the transmission target control device 10 via the transmission / reception unit 33, and the current time is counted. For example, when the code “86” is selected by operating the item button 31e, correction data that is advanced by 2 seconds every month is transmitted to the transmission target control device 10 via the transmission / reception unit 33, and “87” is transmitted. When the code is selected, correction data for delaying by 2 seconds every month is transmitted to the control apparatus 10 to be transmitted. This time adjustment is determined according to the accuracy of the crystal oscillator built in the time counting unit 13. Note that the above-described control device 10 to be transmitted is the control device 10 that faces the front end portion of the remote control (portion where the transmission / reception unit 33 is provided) directed by the operator.

Next, the operation of the present embodiment will be described with reference to FIGS. 2 is a diagram showing an example of a time setting screen at the time setting time, FIG. 3 is a diagram showing an example of a time setting screen at the time reception, and FIG. 4 is a diagram showing an example of a time setting screen at the time correction.
When the time setting button 31a of the remote controller 30 is pressed and held, the microcomputer 35 displays a time setting screen on the liquid crystal display unit 32 as shown in FIG. After that, when the time setting button 31a is pressed to select the day of the week and the time (except for the second unit) is set with the light / dark button 31b for dimming setting, the microcomputer 35 displays the day of the week and the time on the time setting screen. And hold. For example, when the day of the week is Monday and the time is 10:00, the display is as shown in FIG. The day of the week is displayed while sequentially shifting to the right from “day” every time the time setting button 31a is pressed, and the time is set by a combination operation of the two light / dark buttons 31b. When the transmission button 31c is pressed after setting the day of the week and the time, the microcomputer 35 transmits the stored day of the week and time (excluding the second unit) as data to the control device 10 via the transmission / reception unit 33, and the stored time is displayed. Start timing from zero seconds as the current time. As described above, the transmission target control device 10 is the control device 10 facing the transmission / reception unit 33 of the remote controller 30.

  On the other hand, when the transmitting / receiving unit 12 of the control device 10 receives the day of the week and the time excluding the second unit, the microcomputer 15 sets the day of the week in the time counting unit 13 and sets the reception time as the current time in the time counting unit 13. And start timing from zero seconds. Further, the time setting button 31a of the remote controller 30 is pressed and held to display the time setting screen again on the liquid crystal display unit 32 (see FIG. 3A), and the remote control 30 is directed to the previous control device 10 and the reception button 31d is pressed. When pressed, the microcomputer 35 transmits a time readout signal based on the operation. When the time reading signal is received by the control device 10, the microcomputer 15 transmits the time (including seconds) counted by the time counting unit 13 from the transmission / reception unit 12 and causes the remote controller 30 to receive the time. At this time, the microcomputer 35 of the remote controller 30 displays the time sent from the control device 10 on the liquid crystal display unit 32 (see FIG. 3B), and sets the reception time as the current time in the time counting unit 13. , Keep counting the time. In this state, when the remote controller 30 is pointed at the other control device 10 and the transmission button 31c is pressed again, the microcomputer 35 reads the time (including the second unit) during the time measurement from the time counting unit 13, and It transmits to the other control apparatus 10 which opposes, and time-measures as a present time. Thereby, since the time of the control apparatus 10 which set time first and the 2nd control apparatus 10 correspond, the same control schedule set to each control apparatus 10 will be performed simultaneously.

  Further, after setting the time to each control device 10 by the remote controller 30, for example, the item button 31e is operated to display the code “86” on the liquid crystal display unit 32 (see FIG. 4A), and the transmission button 31c is set. When the button is pressed, the microcomputer 35 transmits correction data that is advanced by 2 seconds every month to the control device 10 to be transmitted, and displays the code “87” on the liquid crystal display unit 32 by the item button 31e (FIG. 4). When the transmission button 31c is pressed, correction data that is delayed by 2 seconds every month is transmitted to the control apparatus 10 to be transmitted. On the other hand, the control device 10 set with the code “86” advances the time by 2 seconds every time one month passes, and the control device 10 set with the code “86” sets the time every time one month passes. Delay 2 seconds.

  As described above, according to the present embodiment, when the time set by the remote controller 30 (excluding the second unit) is transmitted to the first control device 10, the control device 10 and the remote control 30 each have the same time as the current time. The time measurement is started, and when the time measured by the first control device 10 is received by the remote controller 30, the time measurement is continued as the current time, and this time is transmitted to the other control devices 10 to be timed as the current time. Therefore, the same time can be easily set for the plurality of control devices 10.

  Moreover, since the time measured by the control device 10 can be displayed on the liquid crystal display unit 32 of the remote controller 30, it is possible to check whether the time of the control device 10 is advanced or delayed. Is corrected so that it is delayed by 2 seconds every month, and when the time is delayed, it can be corrected so that it is advanced by 2 seconds every month. Even if a crystal oscillator with relatively low accuracy is used, the time error during that period can be suppressed as much as possible.

  In the above embodiment, when the time set by the remote controller 30 (excluding the second unit) is transmitted to the first control device 10 to time the time and the time is set to the other control device 10, The time of the control device 10 set first is read by the remote controller 30 and is set to the other control device 10 as the current time. However, the time set by the remote controller 30 (except for the second unit) is the first control. The time at which the time measurement is started when transmitted to the device 10 may be set in another control device 10, and the same time can be set in many control devices 10 in a relatively short time.

  In addition, the time can be advanced or delayed by 2 seconds every month, but is not limited to this time, and can be arbitrarily set according to the time counting state of the time counting unit 13 on the control device 10 side. You may enable it to correct | amend time.

  Further, although the same time is set for each of the plurality of control devices 10 by the remote controller 30, the transmission I / F provided in each control device 10 is connected by the transmission line 40, and the first control device is set. 10 receives the time excluding the second unit from the remote controller 30 and starts counting from zero seconds with the received time as the current time, and transmits the current time to another adjacent control device 10 via the transmission line 40. When a time including a second unit is received, the time is continued as the current time, and the current time is transmitted to another adjacent control device 10 via the transmission line 40. You may make it transmit. When configured in this way, the time setting by the operator is simplified, and the same time can be set in many control devices 10 on the system in a short time.

It is a schematic block diagram of the equipment control system which shows embodiment of this invention. It is a figure which shows an example of the time setting screen at the time of time setting. It is a figure which shows an example of the time setting screen at the time of time reception. It is a figure which shows an example of the time setting screen at the time of time correction.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Control apparatus, 11 Transmission I / F, 12 Transmission / reception part, 13 Time counting part, 14 Illuminance sensor, 15 Microcomputer, 20 Lighting fixture, 30 Remote control, 31 Operation part, 32 Liquid crystal display part, 33 Transmission / reception part, 34 Time counting part 35 Microcomputer.

Claims (5)

A plurality of equipment devices are connected to each other, a plurality of control devices that respectively control each equipment device based on a preset control schedule, and the control schedule is created based on the operation of the operation unit, and set in each control device It consists of a setting device,
The setting device holds the time when a time excluding the second unit is set by operating the operation unit, and when the transmission operation is confirmed, transmits the time to the control device and sets the time as the current time. When time measurement is started from zero seconds, and the transmission operation is confirmed during time measurement, the time including the second unit is transmitted to the control device,
When the time excluding the second unit is received, the control device starts counting from zero seconds with the received time as the current time, and when receiving time including the second unit, the time is measured with the received time as the current time. An equipment control system that continues and uses the current time as discrimination information for control schedule execution.   The setter has a display unit, receives a time measured on the control device side when confirming a reception operation, displays the time on the display unit and continues the time measurement as the current time, After that, when the transmission operation is confirmed, a time including a second unit is transmitted to the control device. The setter has correction data for shifting the time by a predetermined time every predetermined period, and transmits the correction data to the control device when confirming the time correction operation,
3. The equipment control system according to claim 1, wherein when the correction data is received, the control device corrects the time by shifting the time by a predetermined time every predetermined period.   When the time excluding the second unit is received, the control device starts timing from zero seconds with the reception time as the current time, and transmits the current time to another adjacent control device. The equipment control system according to any one of claims 1 to 3. 2. The control device according to claim 1, wherein when the time including the second unit is received, the control device continues counting the time using the reception time as the current time, and transmits the current time to another adjacent control device. The equipment control system in any one of 4 thru | or 4.

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