JPS63196197A - Carrier control system power line - Google Patents

Abstract

PURPOSE:To rapidly respond to the OFF operation of load at a load side, by performing the centralized control of the ON operation of the load by a switching means at a master machine, and performing the OFF control at the load side without acquiring the judgement of the master machine with respect to the OFF operation of the load by the switching means at the load side. CONSTITUTION:An operating switch 17 which performs the ON/OFF control of the load is provided on the master machine 3, and operating buttons 7 and 8 on the load 4 or the load 4 side of a slave machine 5, etc. The microcomputer 20 of the master machine 3, when the switches 17 and 7 being turned ON, judges whether the load 4 is possible to be turned ON or not. And a microcomputer 23 provided at the load 4 side, when a switch 8 being turned OFF, turns OFF the load 4 without acquiring the judgement of the microcomputer 20. By performing the OFF operation of the switch 8 at the load 4 side, the load 4 is turned OFF directly by the microcomputer 23 without performing the transmission/reception of a signal from the load 4 side to the master machine 3.

Description

[Detailed Description of the Invention] [Object of the Invention] (Industrial Application Field) The present invention provides a
The present invention relates to a power line transport control system that performs load control and centralized monitoring by transmitting information to slave units connected to Ill1.

(Prior Art) In general, as disclosed in Japanese Patent Application Laid-open No. 61-161032, the power line conveyance tlIIIll system uses indoor power lines to transport various electrical appliances such as lighting equipment, air conditioners, etc. You can send information to the slave unit that handles the load consisting of IIIll to perform the load $11 III, or send information indicating the operating status of the load from the slave unit to the master unit, and the master unit handles multiple loads. The purpose is to carry out intensive monitoring of Such a power line transport control system is used, for example, in hotels, schools, etc., to control the load in each room by It, IN10t,
It is used for monitoring multiple loads, and not only can the main unit turn on and off the loads, but also it can be installed in each room. The configuration is such that the load can be controlled on and off by the load side, that is, by the child unit or the load.

In this case, both the master unit and the slave unit are equipped with data processing units, but since it is more convenient to centrally control multiple slave units by a central control unit, the load side can turn on and off the data. Even if the handset is operated, the handset once transmits a signal based on this operation to the base unit, and the M unit receives this signal and judges whether it can operate on/off, and then sends the on/off tII11[l signal to the handset. and the handset will turn this on/off
It is configured to control the load on and off after receiving the II1wJ signal.

(Problems to be Solved by the Invention) In the above configuration, even if an abnormality occurs in the load and the load side immediately performs an off operation, the off signal is sent from the slave unit to the 12 units,
If the slave unit does not receive the off control signal from the base unit, the load will not be turned off, which may cause the base unit to malfunction or prevent signals from being sent and received between the base unit and other slave units. When a failure such as communication failure occurs, there is a problem in that the load cannot be stopped immediately even in an emergency situation.

The present invention has been made based on the above-mentioned problem, and the load is directly turned off by the slave unit. ! Another object of the present invention is to provide a power line transport control system that can quickly respond to a load-off operation on the load side.

[Structure of the Invention] (Means for Solving the Problems) In FIG. 1, a first switch means 17 for controlling the load 4 on and off is provided in the main unit 3, and the load 4 is also turned on and off.
Second switch means 7 and 8 for off-control are provided on the load 4 side such as the load 4 or the slave device 5, and the first control means 20 of the parent device 3 is connected to the first switch means 17 and the second switch. When the means 7 is turned on, it has a function of determining whether or not the load 4 can be turned on, and also has the function of determining whether the load 4 can be turned on or not. : The provided second switch means 23 has a function of turning off the load 4 without obtaining the judgment of the first Illm means 20 when the second switch means 8 is turned off. It is.

(Function) When the second switch means 8 is turned off with the load 4I, 15! from the load side 4! The load 4 is directly turned off by the second control means 23 without transmitting or receiving a signal to the machine 3.

(Example) Hereinafter, one embodiment of the present invention will be described in detail based on the drawings.

FIG. 2 is a configuration diagram of the system of the present invention, in which one control master unit 3 is connected to a power line 2 connected to a commercial AC power source 1, and an FF stove 8 is placed in each room. Eight loads 4 are connected to slave units 5, and the eight loads 4 are remotely controlled and centrally monitored by the master unit 3.

Figure 4 shows the operation panel section 6 of the load 4, where 7 is an operation button that turns on the load 4, and 8 is an off button that turns off the load 4. When both are pressed as shown in Figure 7, It uses a button-type switch that closes the contact and then automatically returns to output a pulse-like signal. 9 is an operating lamp that displays the operating status, 10 is "low", "medium",
This is a room temperature control knob that adjusts the room temperature up to "high."

FIG. 3 shows the base unit 3, 11 is a power lamp that displays the connection status of this base unit 3 to the power line 2, and 12 is a carrier signal that is transmitted and received between the base unit 3 and the slave unit 5. A communication lamp 13 indicates the communication status, and is a model name display label in which the name of the room in which the load 4 is installed is written, and a cover 14 is provided to prevent it from getting dirty or coming off. 1
5 is an operation lamp that displays the operating status of the load 4; 16 is a warning lamp that lights up when an abnormality occurs in the load 4 and a safety device such as an overheating prevention device or a vibration sensor is activated and the operation is stopped; 11 is an operation switch that controls on/off the load 4 in this master unit 3, and uses a button type switch whose contact closes when suppressed and then automatically returns to output a pulsed signal. If a pressing operation is performed while the load 4 is in operation, the load 4 is turned off, and if a pressing operation is performed while the load 4 is stopped, the load 4 is turned on. Reference numeral 18 denotes a see-saw type forced switch that strongly υj regulates the load 4 to the OFF state with priority over the operation button 7 of the load 4 and the operation switch 17 of the main unit Q, and when this forced switch 18 is set to the "off" side, If the push button 7 and run switch 17 are pushed down, the push operation of the run button 7 and run switch 17 will be disabled and the load 4 will remain in the OFF state. The pressing operation becomes effective and the load 4 can be turned on and off. As shown in Figure 7,
This forced switch 18 does not have an automatic return function, and always outputs an on signal "1" while it is on the "on" side.
It is also possible to use a lock type switch, a tumbler set switch, etc. that always outputs an off signal "0" while the label is on the "off" side.
An operation lamp 15, a warning lamp 16, an operation switch 17, and a forced switch 18 are provided corresponding to each load 4.

FIG. 1 shows a block diagram of the present invention, and in order to simplify the explanation, only one load 4 and one slave device 5 are shown.

The power line 2 is connected to the commercial AC power source 1 via a block filter 19 to block noise from the outside and prevent leakage of generated noise. The master unit 3 includes a microcomputer 20, a transmitting/receiving circuit 21, and a power supply circuit 22. The master unit 3 is controlled by the microcomputer 20, and when the operation switch 17 is operated, the transmitting/receiving circuit 21 transmits control signals such as on/off commands to the power line 2. Child through! fi5
At the same time, it receives confirmation signals, inquiry signals, etc. transmitted from the handset 5.

The handset 5 includes a microcomputer 23, a transmitting/receiving circuit 24,
The microcomputer 2 is equipped with a power supply circuit 25, a relay 26 that directly controls on/off the load 4, and a phototransistor 27 that detects that the operating lamp 9 consisting of a light emitting diode goes out when the safety device of the load 4 is activated.
3, the load 4 is turned on and off based on a control signal that is an on/off command transmitted from the base unit 3 vI
'ta b, transmits the confirmation signal, and when the operation button 7 is operated, sends an inquiry signal to the parent unit 13 to inquire whether or not consecutive battles are possible, receives an ON control signal from the parent unit 3, and turns on the load 4. When the off button 8 is operated while turning on &lJ, the parent! ! ! 3 directly demagnetizes the relay 26 and turns off the load 4. The load 4 includes a microcomputer 28, an FF stove II11 control section 29, and a power supply circuit 30, and is controlled by the microcomputer 28, and its operation button 7
and the off button 8 is the microcomputer 23 of the slave unit 5.
It is connected to the.

The operation of the present invention configured as described above will be explained with reference to the flowcharts of FIGS. 5 and 6. In the system of the present invention, the operation υ control of the load 4 can be performed by both the master unit 3 and the load 4, and when the load 4 is turned on, the master unit 3 concentrates i+1jllll, and the load 4 on the load 4 side Regarding the off operation, the slave device 5 directly controls the load 4 to turn off. First, the load 4 is removed remotely by the master hoe 3.
When the operation switch 17 of the parent vA3 is pressed, the switching signal is sent to the microcomputer 20.
Output to.

When the microcomputer 20 determines in step S1 that this switching signal has been input, it proceeds to step S2.
Determine whether load 4 is currently in operation, and if it is in operation,
In step S3, the switching signal indicates an off command, and an off signal is sent to the slave unit 5 to stop the operation of the load 4. If the load 4 is stopped, the forced switch 18 is turned on and off in step S4. Determine the condition. If the forced switch 18 is off, the forced switch 18 has priority over the operation switch 17, so even if an on signal is input from the operation switch 11, the microcomputer 20 invalidates this and the load 4 is not operated.

On the other hand, if iti+switch 18 is on, step S
At step 5, a signal is transmitted from the base unit 3 to the slave unit 5. Then, in step S6 and step S7, the corresponding child Ia5
receives this ON signal, energizes the relay 26, opens the relay contact 26A, and supplies power to the load 4.
turns on. When it is determined in step S8 that the load 4 is turned on, the I! ! A confirmation signal indicating that the MPIA 3 has been turned on is transmitted, and the base unit 3 receives this confirmation signal (step 510), and the operation lamp 15 of the MPIA 3 lights up (step 511). Also,
If the load 4 does not turn on even though the power is turned on to the load 4 in step S8, the microcomputer 23 of the slave device 5 determines that an abnormality has occurred in the load 4 and sends an abnormality signal to the master device 3 (step 512). ), the base unit 3 receives this signal (step 513), and the warning lamp 16 lights up (step 514).

Next, when the load 4 is directly controlled by the load 411, when the operation button 7 of the load 4 is pressed, the switching signal is output to the microcomputer 23 of the child 115 (step 515). This microcomputer 23
When the switching signal is input, it is determined in step 816 whether or not the load 4 is currently in operation. If it is, the process moves to step 317 and the load 4 is caused to continue operating. If the load 4 is stopped, the process moves to step 318, and the microcomputer 23 of the slave unit 5 sends an inquiry signal to the base unit 3 to check whether the forced switch 18 is on, that is, whether it can be operated. do. Master unit 3
receives the inquiry signal in step 319, determines whether the emphasis switch 18 is on or not in step 320, and if the forced switch 18 is on, transmits the on signal to the handset 5 (step S5), as described above. Steps S6 to 31
Processing No. 4 is performed. However, if the forced switch 18 is in the OFF state, the master device 3 outputs a command signal to the child 85 to continue turning it off (step 521). The slave device 5 receives this signal (step 522) and does not energize the relay 26 even though the operation button 7 is pressed (step 323), so the load 4 remains stopped.

On the other hand, as shown in FIG. 6, when the cut-off button 8 of the load 4 is pressed, the switching signal is output to the microcomputer 23 of the slave unit 5 (step 524). When the switching signal is input, the microcomputer 23 determines whether the load 4 is currently in operation in step 325, and if the load 4 is stopped, the process moves to step 826 and continues to be stopped.

If the load 4 is in operation, the process moves to step 327, where the microcomputer 23 demagnetizes the relay 26 and stops the load 4. Thereafter, when the microcomputer 23 detects the off state of the load 4, it sends a confirmation signal indicating that the load 4 is off to the base unit 3 (step 828), and the base unit 3 receives this signal (step 329). The operation lamp 15 corresponding to the corresponding slave device 5 is turned off (step 530).

In this way, the present invention provides the forced switch 18 in the i-machine 3, and also provides 1!81 for the on-operation of the load 4.
3 is centrally controlled, it is possible to forcefully keep the load 4 in the OFF state with priority over the ON operations of the operation switch 17 and the operation button 7. Centralized monitoring of the system by preventing it from turning on 4? It can improve II ability. In addition, since this force switch 18 is provided corresponding to each load 4, it is possible to select the load 4 to be forcibly turned off, and it can be done individually and centrally! 'J all is also possible. Regarding the off operation of the load 4 on the load 4 side, when the off button 8 is operated while the load 4 is operating, the microcomputer 23 of the slave unit 5 does not send a signal to the master unit 3 and the master unit 8
By demagnetizing the relay 26 and immediately stopping the load 4 without obtaining the judgment of 13, the load 4
When an abnormality occurs in the load 4 and the load 4 needs to be turned off urgently, the load 4 can be turned off immediately regardless of failure of the 113 or communication failure due to the use of the communication line. Furthermore, FIG. 7 shows the operation switch 17 and operation button 7 when the forced switch 18 is turned on.
It shows the on/off state of the load 4 in response to the operation of the operation switch 17.
As the run button 7 and the off button 8, button-type switches are used that output a pulse-like signal only when pressed. Therefore, in the case of the force switch 18, the switch position can be maintained at all times, so even if power is temporarily cut off to the base unit 3 due to a power outage or the base unit 3 being unplugged, the switch position can be maintained at all times. Logic circuit backs up the state? There is no need to memorize it using a ti source or a non-volatile memory, and when power is supplied again, the switch position is applied as is, and the subsequent operation switch 11. It is possible to respond to the suppression operation of the run button 7 and the off button 8, and there is no need to reset the forced switch 18 again. On the other hand, operation switch 17゜operation button 7
And in the case of the off button 8, since it generates a pulse-like signal, the signal is temporarily generated only when the suppression operation is performed, and the signal does not remain. Therefore, the operation switch 17 and the operation button 7 ( Alternatively, the on/off control of the load 4 can be easily performed bidirectionally using the off button 8). Incidentally, while the load 4 is operating, the microcomputer 23 of the slave device 5 switches the phototransistor 21 constituting the photocoupler.
The operation lamp 9 of load 4 is monitored by [113
If a safety device such as an abnormal overheating prevention device of the load 4 is activated and the load 4 stops operating even though an off signal is not input from the load 4, an abnormality signal is sent to the parent unit 613 and the parent unit Since the warning lamp 1G of No. 3 lights up, the load 4 can be centrally monitored by the parent device 3.

Although one embodiment of the present invention has been described above in detail, it can be modified as appropriate within the scope of the gist of the present invention. For example, although the slave l15 is provided separately from the load 4, it may be built into the load 4 and integrated into the load 4, or the operation panel section 6 of the load 4 may be provided in the slave unit 5, and the slave 15 can be used to load the load 411. 4 on/off control may be performed. Furthermore, the first switch means in the base unit 3 and the slave I! The number of second switch means in 15 or the number of configurations of base unit 3 and slave unit 815 are not limited to those in the above embodiment.

[Effects of the Invention] As described in detail above, according to the present invention, the main unit centrally controls the on-operation of the load by the switch means, and the lubricant controls the off-operation of the load by the switch means on the load side. ! By performing direct off control on the load side without making any arbitrary decisions, it is possible to provide a power am transmission system that can quickly respond to a load off operation on the load side.

[Brief explanation of the drawing]

Fig. 1 is a block diagram showing an embodiment of the present invention, Fig. 2 is a block diagram of the entire system, Fig. 3 is a perspective view of the main unit, and Fig. 4 is a block diagram showing an embodiment of the present invention.
5 is a front view of the operation panel section, FIGS. 5 and 6 are flowcharts showing the operation of the system, and FIG. 7 is a timing chart of switch operation. 1...Commercial AC power supply 2...Power line 3...Main unit 4...Load 5...Slave unit 7...Run button (second switch means) 17...
Operation switch (first switch means) 18...Forced switch (forced switch means) 20...Microcomputer (first control means) 23...Microcomputer (second tIIJII11 means) Patent application
Person: Toshiba Heat Appliances Co., Ltd. Patent Attorney Mamoru Ushiki Figure 7 Figure 3 Q Figure 4 ■Colony] D Figure Figure 6

Claims (1)

[Scope of Claims] A base unit and a slave unit having a transmitting/receiving circuit are connected to a power line of a commercial AC power source, and a high frequency signal is transmitted and received on the power line between the base unit and the slave unit, and the slave unit is connected to the base unit. In a power line carrier control system that performs remote control and centralized monitoring of a load, the power line carrier control system includes a first switch provided on the master device to control on/off the load, and a first switch provided on the load side such as the child device or the load. The second one controls the load on and off.
a first control means for determining whether or not the load can be turned on when the first switch means and the second switch means provided in the base unit are turned on; a second control means that is provided on the side and turns off the load without obtaining a judgment from the first control means when the second switch means is turned off; control system.