JPS6069932A - Controlling method of transmission - Google Patents

Abstract

PURPOSE:To obtain a transmission control method with fast control speed and simple operation and equipment by transmitting simultaneously a single control signal from a control instrument to other control instrument and allowing a control instrument receiving said signal to the control instrument according to a preset procedure. CONSTITUTION:Instruments 14-18 such as household electric appliances are connected to a lighting line 13 via control modules 19-22 respectively, and a control terminal 24 being a control is also connected to the lighting line 13. When the simultaneous command switch 25 of the terminal 24 is depressed, an instrument number common to all modules and a simultaneous instruction command are transmitted to all the modules. When the control modules 19-23 receive the simultaneous instruction, they check own control/non-control switches 26-30, and when they are selected to a non-control position, the simultaneous instruction is disregarded. When the switches are selected to a control position, the own ON/OFF changeover switches 31-35 are checked, and when the switches are selected to an ON position, the instruments 14-18 are controlled to an ON state and when to an OFF position, the instruments 14-18 are controlled to an OFF state respectively.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to communication control between decentralized devices.

Conventional configuration and its problems In order to centrally control multiple devices or to control them according to a set procedure based on mutual relationships, each device is connected through an electrical communication network and sends control signals to each other. Various transmission control methods for mutual transmission have been reported. - For example, there is a method of using a commercial 100V electric light line as a communication network to control home appliances in a general household. This is the potential line 501
1z or 6011z AC voltage is superimposed with a communication signal voltage of a sufficiently higher frequency to communicate between each device, and since special wiring for control is not required, the effort and cost associated with installation is reduced. It has the characteristic of being small.

The transmission control method using potential lines will be explained in detail below using the drawings.

FIG. 1 shows a transmission control method using a potential line, and -1 is a commercial 100V potential line, which is located inside a typical household. Devices 2 to clj, such as home appliances, are connected to the potential line 1 via modules T to 11, which are control devices, respectively. Control module - Lua ~ 11 is a sensor function that detects whether the currently connected device is in an energized state (hereinafter referred to as an ON state) or a non-energized state (hereinafter referred to as an OFF state).1 A control function that turns the device 0N10FF. - and has a communication function for exchanging the control signals with other devices. The potential line 1 also has a control terminal 12 which is a control device.
is connected. The control terminal 12 has a communication function to exchange control signals with the control modules 7 to 11, a control signal generation function to generate ON10FF signals to be transmitted to each control module, and a control signal generation function to generate ON10FF signals to be transmitted to the individual control modules.
It has a monitor display function that displays whether it is in the OFF state or in the OFF state. The control signal used for communication consists of a device number indicating the object to be controlled and an instruction command indicating the content of the control. The device number and command are encoded by intermittent alternating current voltage with a frequency sufficiently higher than the electric light line voltage, and are injected into the potential line. The device number is set so that each control module can be assigned an individual job.

Imaichi control terminal 12f: Device 2 in OFF state
change to ON state. First, when the control terminal 12 receives a command from the user, the control terminal 12 transmits the device number of the device 2 and a command to turn it on to the potential line 1. Although the signal transmitted from the control terminal 12 reaches all control modules, only the control module 7 corresponding to the transmitted equipment number reacts to the command. When the control module receives a command from the control terminal 12, it turns one device 2 on, and when it confirms that one device 2 is turned on, it tells the control terminal 12 that the device 2 is changed to the ON state. Send information to let you know. If the control terminal 12 receives information from the control module 7, the device 2
The N state is displayed on the monitor, and the user sees this and confirms the ON state of the device 2, completing the series of controls.

In the conventional transmission control method described above, a request to control a plurality of devices at once arises in some cases. For example, when going to bed, all devices are turned off and security devices such as gate lights are turned on.

In addition, the lighting equipment at hand can be manually set to 0N without being affected by transmission control.
A request arises to simultaneously control each of the 10 FFs.

One means of satisfying this requirement using conventional transmission control methods is a method in which one user controls each device one by one while checking the monitor display on the control terminal 12. This method has disadvantages in that it takes a long time to complete the control and requires a large number of operations, making it easy for the user to make input errors. Another method is to store a series of control processes as a program in the control terminal 12, and when one communication request occurs, control commands are sent and turned ON to the control modules connected to each device one by one.
10 FF There is a method of repeating a series of controls such as receiving information and displaying it on the monitor. This method also has the disadvantage that it takes a long time to complete the control. Another drawback is that when the number of devices increases, the scale of the program within the control terminal becomes extremely large. Furthermore, when changing the control contents for equipment, for example when adding or changing equipment, the control program must be re-edited, and there is a drawback that it is not responsive to changes in general equipment.

OBJECTS OF THE INVENTION The present invention solves the above conventional problems and provides a transmission control method that has high control speed, simple single-operation general setup, and good adaptability to changes in general setup regarding multiple simultaneous control. purpose.

Structure of the Invention The transmission control method of the present invention consists of a plurality of control devices that can communicate with each other and a communication transmission path connecting them. When a control signal is transmitted and the other device receives the control signal, it controls the device according to a procedure set for each device as necessary.

Description of examples Embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 2 is a block diagram of the transmission control method of the present invention.

The potential line 13 is a line inside a general household that supplies 100V commercial power. The devices 14 to 1B, such as home appliances, are controlled by a control module 19, 20°21.22.
23 respectively to the potential line 13. The devices 14 to 18 and the control modules 19 to 23 may be integrated or separate. A control terminal 24, which is a control device, is also connected to the potential line 13.

The control modules 19 to 23 have a sensor function 1 that senses whether the connected device is currently in the ON or OFF state.
It has a control function for 0N10FF of devices, and a communication function for communicating the control signal with other devices. The control terminal 24 has a communication function, a control signal generation function for generating 0N10FF signals to be transmitted to each control module, and a monitor display function for displaying whether each device 14 to 18 is currently in an ON state or an OFF state. The control terminal 24 also has a simultaneous command switch 26 and a simultaneous command generating function for outputting a specific simultaneous command (for example, 0N10FF command to each device at bedtime) to all the control modules 19 to 23. The control modules 19 to 23&'i also have control/non-control changeover switches 2e5 to 30 that determine whether or not to be controlled by a specific simultaneous command transmitted from the control terminal 24, and if this switch is on the control side, the The control module is controlled by a simultaneous command, and conversely, if it is on the non-control side, it has the function of being able to be switched so that it is not controlled. The control modules 19 to 23 also turn on the connected devices when the control/non-control changeover switches 26 to 30 are on the control side and are controlled by the simultaneous command V from the control terminal 24. 0N10FF9J switch 3 to set whether to turn on or off
1 to 36, - If this switch is on the ON side, the connected devices will be turned on by a simultaneous command from the control terminal.
It has a switchable function such that if it is in the N state, it will be in the OFF state, and if it is on the OFF side, it will be in the OFF state. However, when the control/non-control selector switch is on the non-control side.

Since the control module does not accept all commands from the fltlJ control terminal, the 0N10FF changeover switch has no meaning at all.

With the above configuration, the procedure for controlling each device one by one from one control terminal 24 is exactly the same as the conventional example explained using FIG. 1.

Next, if the simultaneous command generation function of the control terminal 24 is pressed and a communication request for a simultaneous command is generated, the control terminal 24
transmits a device number common to all modules and a simultaneous command generation function that enables control to be applied to all control modules. When the control modules 19 to 23 receive a general command, they first check their own control/non-control changeover switch, and if this is on the non-control side, they ignore the general command. If it is on the control side, then check your own 0N10FF selector switch.If it is on the ON side, turn the connected device ON and vice versa.
If it is on the F side, each connected device is controlled to be in an OFF state. The manner in which devices are controlled by this simultaneous command will be explained using a table.

FIG. 3 is a state change table showing how equipment is controlled by simultaneous commands. - Devices 14 to 18 before the simultaneous command is output
The state of ``ON'' is as shown in Figure 3.

OFF, OFF, ON, OFF, one control/non-control changeover switch is control, second control, control, non-control, control, and some N10FF changeover switches are OFF,
ON, OFF, OFF, OFF.

It is assumed that a command is input to all devices at once in this state. Since the control/non-control changeover switch of the equipment 17 is on the non-control side, it remains in the same ON state as the beginning even after the simultaneous command. Equipment 14. For i6, 15゜17, the control/non-control switch is on the control side, so fiON can be turned on by simultaneous command.
It is controlled as indicated by the 10FF changeover switch.

In this way, in the transmission control method of the present invention, even though multiple devices are controlled simultaneously, the control terminal that issues the command only outputs the control signal of the simultaneous command common to all the devices, and the control When a control module connected to a device receives a control signal of a simultaneous command, each control module can perform control according to a procedure set for each control module as necessary. In this transmission control method, the configuration of the control module on the controlled side needs to be somewhat complicated. but.

The control procedure program for the control terminal on the control side is preferably small-scale. Since the control signal only needs to be transmitted once, the time required to complete the control is short, and the user only needs to perform the operation once, so the probability of input errors is extremely small. In addition, when adding or changing controlled equipment, there is no need to change the control program at all, just change the connection to the transmission line, and the system is very responsive to equipment changes. Control contents can be freely set for each individual device, and changes can be made very easily without requiring any changes to the control program.This system has many advantages.

Effects of the Invention The transmission control method of the present invention solves the conventional problems, allows the control program to be downsized, shortens the control time, reduces input errors by the user, and has excellent adaptability to general equipment changes. The control contents can be freely set for each individual device and can be easily changed.

It has many practical effects.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of a conventional transmission control method, and FIG. 2 is a block diagram of a transmission control method showing an embodiment of the present invention. FIG. 3 is a state change diagram showing how equipment is controlled by simultaneous commands. 14-18...Equipment-19-23.24...
...Control equipment (control module, control terminal) -
25...-Q command switch, 26-30...
・-Control/non-control changeover switch, 31 to 35...O
N10 FF selector switch.

Claims (1)

[Claims] It has multiple control devices that can communicate with each other and a communication transmission path that connects them, and when a communication request occurs within the control device, it simultaneously transmits a single control signal to other control devices, and A transmission control method in which, upon receiving the control signal, the other control device controls the device according to a procedure set for each control device as necessary.