JP3565005B2 - Setting device for remote monitoring and control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To facilitate the recognition of a setting content and to easily detect erroneous settings by referring to relation data stored in a storage means and displaying an identifier using the designated address on a display part, when the address of the terminal unit of a load-side is designated by an operation part. SOLUTION: A central processing unit gives identifiers to respective groups in the corresponding relation of addresses between respective switches and loads and stores relation data. When an operation part 13 designates the address of the terminal unit on a load-side, all the identifiers using the designated address are discriminated from the identifiers which can be used and which are not used, and they are displayed on a display part 12. When a load which is not a control object operates at the time of collective control such as pattern control and group control, the address of the load is designated and the identifier (a pattern number and a group number) are obtained. Thus, erroneous setting can easily be detected and therefore site adjustment in pattern setting and group setting can easily be executed.

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
INDUSTRIAL APPLICABILITY The present invention is used in a remote monitoring control system that transmits a transmission signal to a signal line by a time-division multiplex transmission method and enables load control by operating a switch using the transmission signal. The present invention relates to a setting device for a remote monitoring and control system for setting a setting.
[0002]
[Prior art]
Conventionally, a remote monitoring control system having a configuration shown in FIG. 58 has been known. In this remote monitoring and control system, a plurality of operation terminals 31 and control terminals 32 are connected in a branch connection (multidrop connection) to a two-wire signal line Ls connected to the transmission control device 30. Although only one control terminal 32 is shown in the illustrated example, a plurality of control terminals 32 are actually used. In the illustrated example, an individual switch 31a and a pattern switch 31b are provided as the operation terminal device 31, and a later-described pattern setting device 33 is also connected to the signal line Ls. Individual addresses are set for each of the operation terminals 31 and the control terminals 32, and the transmission control device 30 individually recognizes the operation terminals 31 and the control terminals 32 using those addresses. The individual switch 31a and the pattern switch 31b include switches Sa and Sb, respectively, and a load L is connected to the control terminal 32. Further, the operation terminal 31 is provided with a confirmation light (not shown) made of a light emitting diode for confirming the operation state of the load L.
[0003]
The transmission control device 30 sends out a transmission signal Vs having a format shown in FIG. 59A to the signal line Ls. That is, a synchronization signal SY indicating the start of signal transmission, mode data MD indicating a mode of the transmission signal Vs, address data AD for individually calling the operation terminal 31 and the control terminal 32, control data CD for controlling the load L, In the case of bipolar (± 24V) consisting of a checksum data CS for detecting a transmission error and a signal return period WT which is a time slot for receiving a return signal (monitoring data) from the operation terminal 31 or the control terminal 32. This is a division multiplex signal, and data is transmitted by pulse width modulation (FIG. 59 (b)). In each of the operation terminal devices 31 and the control terminal devices 32, when the address data AD transmitted by the transmission signal Vs received via the signal line Ls matches the preset address, the control data CD is transmitted from the transmission signal Vs. At the same time, the monitoring data is returned as a current mode signal (a signal transmitted by short-circuiting the signal line Ls via an appropriate low impedance) during the signal return period WT of the transmission signal Vs.
[0004]
When data is transmitted from the transmission control device 30 to a desired operation terminal 31 or control terminal 32, the mode data MD is set to the control mode, and the address of the operation terminal 31 or control terminal 32 is set to the address data AD. When the transmission signal Vs is transmitted and the transmission signal Vs is transmitted to the signal line Ls, the operation terminal device 31 or the control terminal device 32 that matches the address data AD receives the control data CD, and transmits the monitoring data during the signal return period WT. I will send it back. The transmission control device 30 confirms that the control data CD has been transmitted to the desired operation terminal 31 or control terminal 32 based on the relationship between the transmitted control data CD and the monitoring data received during the signal return period WT. The control terminal 32 outputs a load control signal for controlling the load L in accordance with the received control data CD, and the operation terminal 31 outputs a monitoring signal for performing an operation confirmation display of the load L in accordance with the received control data CD. I do.
[0005]
On the other hand, the transmission control device 30 normally transmits the transmission signal Vs in which the mode data MD is in the dummy mode at regular time intervals (constant polling), and the operation terminal 31 transmits some information to the transmission control device 30. When attempting to do so, an interrupt signal as shown in FIG. 59 (c) is generated in synchronization with the synchronization signal SY of the transmission signal Vs in the dummy mode. At this time, the operation terminal 31 sets an interrupt flag to prepare for the subsequent information exchange with the transmission control device 30. When receiving the interrupt signal, the transmission control device 30 sets the mode data MD to the interrupt polling mode and sequentially increases the upper half of the address data AD (the upper 4 bits if the address data AD is 8 bits). In the operation terminal device 31 that has transmitted the transmission signal and generated the interrupt signal, the upper 4 bits of the address data AD of the transmission signal in the interrupt polling mode match the upper 4 bits of the address set in the operation terminal device 31. In this case, the lower half bits of the address are returned to the transmission control device 30 during the signal return period WT. As described above, since the transmission control device 30 collectively searches for 16 operation terminals 31 that have generated the interrupt signal, the operation terminal 31 can be found in a relatively short time.
[0006]
When the transmission control device 30 obtains the address of the operation terminal device 31 that has generated the interrupt signal, the mode data MD is set to the monitoring mode, and the transmission signal having the obtained address data AD is transmitted to the signal line Ls. In response to the transmission signal, the operation terminal device 31 returns the information to be transmitted in the signal return period WT. Finally, the transmission control device 30 sends a signal instructing an interrupt reset to the operation terminal device 31 that has generated the interrupt signal, and releases the interrupt flag of the operation terminal device 31. As described above, information transmission from the operation terminal device 31 to the transmission control device 30 is performed by four signal transmissions from the transmission control device 30 to the operation terminal device 31 (dummy mode, interrupt polling mode, monitoring mode, Reset). When the transmission control device 30 attempts to know the desired operation state of the control terminal 32, it is only necessary to transmit a transmission signal using the mode data MD as monitoring data.
[0007]
The above operation will be briefly summarized. First, when input data is generated by operating the switches Sa and Sb, monitor data corresponding to the input data is returned from the operation terminal device 31 to the transmission control device 30, and the transmission control device 30 transmits the control data CD to the control terminal device 32. Upon transmission, the control terminal 32 outputs a load control signal to control the load L. Here, the load monitoring input is given to the control terminal 32, the monitoring data corresponding to the load monitoring input is returned to the transmission control device 30, and the returned monitoring data is transmitted to the operation terminal 31. The operation terminal 31 outputs a monitoring signal according to the transmission signal. The monitoring output is usually used to turn on and off the confirmation lamp. The individual switch 31a has a maximum of four circuits of switches Sa, and the control terminal 32 can control a maximum of four circuits of load L. The individual switches 31a and the control terminal 32 are provided with the respective switches Sa and loads L. A 2-bit load number is added for individual recognition. Hereinafter, the address of the individual switch 31a to the control terminal 32 will be referred to as a channel, and the channel and the load number will be collectively referred to as an address. That is, each switch Sa, Sb and each load L are assigned an individual address. In addition, the individual switch 31a and the control terminal 32 corresponding to each other are set to the same channel so that the correspondence can be easily understood (actually, the distinction between the operation side and the control side is made according to the channel number). For example, the upper few bits of the address data represent the operation side or the control side, and the lower several bits are used as a channel).
[0008]
By the way, in this type of remote monitoring and control system, the correspondence between the address of the pattern operation Sb and the load L is managed by the transmission control device 30. By associating the addresses of the loads L as related data, the loads L of a plurality of circuits can be controlled collectively by the switch Sb of one circuit. Such collective control includes group control and pattern control. In the group control, a plurality of loads are controlled to the same control state, and in the pattern control, the plurality of loads are controlled to a control state individually set in advance. In the illustrated example, the pattern switch 31b including the switch Sb is shown, but the group switch which is a terminal device for group control is not shown. However, the pattern control and the group control are the same as other operation terminals except that an operation address defined for collective control is used.
[0009]
As described above, in order to perform the pattern control, it is necessary to register the address of the load L of the plurality of circuits in the transmission control device 30 in association with the address of the switch Sb provided in the pattern switch 31b. The setting operation is called pattern setting. Since the same applies to the case of group control, the setting operation for performing group control is hereinafter referred to as group setting.
[0010]
The remote monitoring control system has two operation modes, a control mode for controlling the load L and a setting mode for performing pattern setting and group setting. That is, when the remote monitoring control system is operated, the transmission control device 30 first enters a normal control mode, and sends a transmission signal in the dummy mode to the signal line Ls. If there is no interrupt signal, constant polling is performed by repeating the transmission signal in the dummy mode. On the other hand, if there is an interrupt signal, the operation terminal 31 is specified and a request from the operation terminal 31 is fetched. Here, if the change of the operation mode is not requested, the current operation mode is determined, the load L is controlled in the control mode, and the pattern setting or the group setting is performed in the setting mode. When the change of the operation mode is requested, the operation mode is changed according to the request.
[0011]
To perform pattern setting in the setting mode, the switch Sb of the desired pattern switch 31b is operated, and then the switch Sa associated with the load L to be controlled by the switch Sb is operated. Here, it is assumed that the relationship between each switch Sa and the load L is set first. According to such a procedure, the state of the load L according to the operation of the switch Sa is taken into the transmission control device 30 as related data, and the state of a plurality of loads L is associated with one switch Sb. The group setting is almost the same as the pattern setting.
[0012]
On the other hand, in this type of remote monitoring and control system, a pattern setting device 33 which is a kind of the operation terminal device 31 may be used. The pattern setting device 33 corresponds to a device in which a plurality of operation terminals 31 are provided, and includes a large number of switches S (the illustrated example includes switches S for 64 circuits. The configuration is such that the switch S is used to select each of the four circuits so that the operation can be performed for each of the four circuits, so that 256 circuits can be operated.) Each switch S can be used as any switch by assigning an address.
[0013]
When using the pattern setting device 33, after selecting the switch S allocated as a pattern switch, the control state of each load L is set by operating the switch S allocated as an individual switch, and related data is created. The data is transferred to the transmission control device 30. That is, since the related data can be created at the place where the pattern setting device 33 is installed, the operation is simplified as compared with the case where the pattern setting is performed using the individual switch 31a and the pattern switch 31b.
[0014]
[Problems to be solved by the invention]
By the way, when pattern setting is performed using the individual switch 31a and the pattern switch 31b, it is not possible to know which load L is assigned to which pattern switch 31b without operating each pattern switch 31b and confirming it. Things. Even if the pattern setting device 33 is used, it is necessary to check all addresses in order to search for a free address for pattern setting or group setting, so that it takes time to search for a free address. Further, in order to check whether an address not assigned to the control terminal 32 is used in pattern setting or group setting, it is necessary to individually examine the contents of each pattern setting or each group setting. It takes time. In short, finding an incorrect setting is very time-consuming.
[0015]
SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a remote monitoring control system in which setting contents can be easily confirmed and erroneous settings can be easily found.
[0016]
[Means for Solving the Problems]
According to the first aspect of the present invention, a storage unit for assigning an identifier to each set of the correspondence relationship between each switch and a load and storing related data, a display unit capable of displaying various information, and instructing processing contents. An operation unit, and a central processing unit that, when the address of the terminal device on the load side is specified by the operation unit, inquires related data stored in the storage unit and displays an identifier using the specified address on the display unit. It is provided.
[0017]
According to a second aspect of the present invention, there is provided a storage unit for assigning an identifier to each set of the correspondence relationship between each switch and a load and storing related data, a display unit capable of displaying various information, and instructing processing contents. An operation unit; and a central processing unit for inquiring related data stored in the storage unit in response to an instruction from the operation unit and displaying a usable and unused identifier on a display unit.
[0020]
Claim 3 The invention of The identifier is a sequence number, and the central processing unit When an identifier is specified by the operation unit when setting the related data, the display is started from the smallest address among the addresses of the loads associated with the closest identifier smaller than the specified identifier. Rumo It is.
[0021]
Claim 4 The invention of The central processing unit When confirming the related data, the load address corresponding to the identifier specified by the operation unit is displayed on the display unit from the smallest address. Rumo It is.
[0022]
Claim 5 The invention of The central processing unit In accordance with an instruction from the operation unit, the relation data in which an identifier is added to a set of the correspondence relation between the switch and the load is selectively transferred to the transmission control device. Rumo It is.
[0023]
Claim 6 The invention of Equipped with a battery as a power supply, the central processing unit, Check the battery capacity at the start of work according to the instruction from the operation unit.When there is no battery capacity until the end of work, display that fact on the display. Rumo It is.
[0024]
Claim 7 The invention of The central processing unit The related data set in the transmission control device is compared with the related data stored in the storage means in accordance with an instruction from the operation unit, and the difference is displayed on the display unit. Rumo It is.
[0025]
Note that the pattern setting device 33 of the conventional configuration is provided with the switches S for 64 circuits, so it is large and expensive, and since it is used fixed to a control panel or the like, it is small. Although it is not suitable for use in a small- to medium-scale remote monitoring and control system (that is, a system in which the number of operation terminals 31 and control terminals 32 is relatively small), the following embodiment will This figure shows a setting device using a possible case, which can be used in a small-to-medium-sized remote monitoring control system with few restrictions on the place of use. In particular, the portability makes it possible to use a plurality of remote monitoring control systems. Further, the pattern setting device 33 only shows the setting contents by turning on / off the indicator light composed of the light emitting diode. Therefore, it is determined whether or not the contents of the pattern setting and the group setting fall within a desired address range. Although it is difficult to understand, the setting unit 34 described below is configured so that the setting contents can be easily understood by displaying characters.
[0026]
BEST MODE FOR CARRYING OUT THE INVENTION
The setting device 34 of the present invention has the external shape shown in FIG. The setting device 34 includes a flat case 11 formed to a size that can be held by one hand, and a display unit 12 formed of a liquid crystal display is provided on an upper front surface of the case 11. An operation unit 13 for performing various operations is provided at a lower part. A window 14 for transmitting an infrared wireless signal to be described later is formed on an upper surface of the case 11, and a connection terminal 15 for a signal line Ls is provided on an upper side of the case 11. Specific configurations and functions of the display unit 12 and the operation unit 13 will be described later.
[0027]
By the way, as shown in FIG. 4, the case 11 of the setting device 34 houses a central processing unit 20 having a microcomputer (hereinafter, abbreviated as a microcomputer) as a main component, and the central processing unit 20 is stored in the ROM 21. In addition to the operation by the system program, the RAM 22 (a non-volatile memory such as an EEPROM) as a storage means can be used as a work area to perform various works described later. The central processing unit 20 is connected to the connection terminal 15 via a signal transmission / reception circuit 23, and the signal transmission / reception circuit 23 connects the setting unit 34 and the transmission control device 30 via the signal line Ls of the remote monitoring control system. It allows data to be sent and received between them. When connecting the setting device 34 to the signal line Ls as shown in FIG. 2, as shown in FIG. 3, a connection line 17 having a connector 16 at one end detachably coupled to a jack-type connection terminal 15 is provided. And the other end of the connection line 17 may be electrically connected to the signal line Ls. As a connection portion to the signal line Ls, an alligator clip 18a as shown in FIG. 3A, a pin plug 18b as shown in FIG. 3B, a Y-type terminal 18c as shown in FIG. Can be. These connection lines 17 are appropriately selected in accordance with where the signal line Ls is connected.
[0028]
Further, a liquid crystal display 25 as the display unit 12 is connected to the central processing unit 20 via a liquid crystal driver 24, and a backlight 26 using a light emitting diode as a light source is disposed on the back side of the liquid crystal display 25. Is done. The operation unit 13 is configured by using a plurality of so-called rubber switches using elasticity of rubber as a return force of the pressing operation. Further, a wireless signal transmitting / receiving circuit 27 for transmitting and receiving infrared wireless signals is also connected to the central processing unit 20. A battery is basically used as a power source for the setting unit 34. However, when connected to the signal line Ls, a power source can be obtained by rectifying and stabilizing a transmission signal transmitted on the signal line Ls. It is possible. The power supply function is realized by the power supply circuit 28. It should be noted that a peripheral device connection driver 29a for connecting a peripheral device such as an external storage device (for example, an IC card) or a printer, and a data latch 29b for temporarily holding data exchanged with the peripheral device are provided. Is provided.
[0029]
On the other hand, in the operation terminal device 31 and the control terminal device 32 used in the present embodiment, transmission and reception of data to and from the transmission control device 30 are performed by a terminal processing section mainly including a microcomputer, and the address and the type of the terminal device are It is configured to be stored in a data storage unit composed of an EEPROM. It also has a wireless signal transmitting and receiving unit for transmitting and receiving infrared wireless signals, and uses infrared wireless signals for setting, correcting and confirming information stored in the data storage unit. In addition to the individual switches 31a and the pattern switches 31b, a group switch used for group control, a dimming switch 31c (see FIG. 2) for instructing dimming of a lighting load, and sensors and switches are connected to the operation terminal device 31 as monitoring inputs. As shown in FIG. 2, the control terminal 32 includes a relay terminal 32a for controlling a relay inserted between the load and the power supply, and a supply terminal for the lighting load. There are types such as a dimming terminal 32c that controls the power to perform dimming lighting.
[0030]
These various terminals have a common configuration of a terminal processing unit, a data storage unit, and a wireless signal transmission / reception unit, and the type of each terminal is stored in the data storage unit, so that the terminal processing unit can be configured to the type of the terminal. Perform the corresponding operation. That is, the data storage unit functions as a kind of memory switch or parameter memory, and the operation of the terminal processing unit is defined according to the setting contents. In other words, the terminal processing unit includes a plurality of types of program modules, and which program module is used is determined according to the settings in the data storage unit. The information that can be set in the data storage unit includes, in addition to the type of the terminal, the temporary ON operation for turning on the load for a fixed time after the operation for turning on the load, and the load OFF after a certain time from the operation for turning off the load. It is also possible to set a fade function for gradually increasing or decreasing the light output of the lighting load from the operation of turning off the lighting load or turning on or off the lighting load, and these functions can also set the time.
[0031]
By the way, as shown in FIG. 1, the screen of the liquid crystal display 25 is arranged in the center of the display unit 12 described above, and the “pattern type”, “address No”, and “ON” are arranged along the upper side of the screen of the liquid crystal display 25. / OFF, "Timer" and "Dimming" are written in order from the left, and "Mode", "Address setting", "Pattern setting", "Initial", "Special" and "Confirmation" are written in order from the left along the left side. The characters "switch", "input T / U", "relay T / U", "dimming", "error", and "out of battery" are written in order from the left along the lower side. Markers M (see FIG. 5) are provided at portions corresponding to each character except for “mode” and “confirmation” among the characters written along the left side and the bottom side on the liquid crystal display 25, By highlighting the marker M (meaning that the display color is different from that of the other portions), it is possible to indicate which content is selected. The liquid crystal display 25 is a dot matrix type display that can display arbitrary characters or figures.
[0032]
Meanwhile, the operation unit 13 is provided with a number of keys K11 to K18, K21 to K24, K31 to K34, K41, and K42 that are pressed. These keys are basically arranged in four types. The key K41 is for selecting ON / OFF of the power supply, and the key K42 is for selecting ON / OFF of the backlight 26. The operation mode of the setting unit 34 includes four modes of an address setting mode, a pattern / group setting mode, an initial setting mode, and a special mode, and these modes are selected by pressing the keys K21 to K24. The key K21 corresponds to the address setting mode, the key K22 corresponds to the pattern / group setting mode, the key K23 corresponds to the initial setting mode, and the key K24 corresponds to the special mode. That is, the keys K21 to K24 are selectively pressed.
[0033]
When the address setting mode is selected by operating the key K21, an address and function data can be set in the data storage unit of each terminal by an infrared wireless signal. When the address setting mode is selected, as shown in FIG. 5, the marker M corresponding to the character of "address setting" is highlighted. Further, since one terminal has four load numbers as described in the prior art, one screen of the liquid crystal display 25 displays setting fields for four addresses in four rows at the top and bottom. You. The setting column has five columns on the left and right, and has cells in four rows and five columns. To change the contents of each cell, the desired cell may be displayed in a highlighted state, and the cursor key K14 is used to reverse the cell.
[0034]
The cursor key K14 has four arrow keys of up, down, left, and right. When the arrow keys are pressed, the position of the inverted display moves in the direction of the arrow keys. When the address type (cell in the first column) is individual, the address No. (cell in the second column) is displayed by combining the channel number and the load number with a hyphen. Each is highlighted. That is, when the position of the reverse display is moved by the cursor key K14, the channel number and the load number are displayed separately in the reverse display.
[0035]
The address type can be selected from the group switch, the pattern switch, the individual switch, and the dimming switch by pressing the keys K21 to K24 in a state where the cell in the first column is highlighted. it can. When the first column is highlighted, the terminal type can be changed by operating the page key K15. Two page keys K15 are provided, and when the upper and lower keys are operated, the terminal device type is sequentially displayed.
[0036]
In a state where the inside of the second column is highlighted, the numerical value displayed in the second column can be changed by pressing the page key K15. For example, when the channel number is highlighted, the channel number can be increased or decreased by the up / down page keys K15, and when the load number is highlighted, the load number can be increased or decreased. When the pattern type is the pattern (P) or the group (G), the pattern number or the group number which is the identifier of the related data can be changed by the page key K15 in a state where the address No is highlighted. Further, if the address clear key K12 is pressed while the cell of the address No is highlighted, the address can be erased.
[0037]
In the state where the grid in the third column is highlighted, whether to turn the load on or off is selected with the page key K15, but such an operation is effective only when the pattern setting or the group setting is performed. become. When the cell in the fourth column is highlighted, it is possible to specify the temporary ON and the delay OFF with the page key K15, and the time is also selected. In other words, 30 seconds, 1 minute, 5 minutes, 60 minutes, and 120 minutes can be selected when temporarily turned on, and 30 seconds, 1 minute, and 5 minutes can be selected when delayed off. Specifically, the combination of the type of operation and the time, such as temporary ON for 30 seconds and temporary ON for one minute, are sequentially selected by the page key K15. When the grid in the fifth column is highlighted, the dimming level is selected by the page key K15. This cell is effective when the pattern type is dimming. When the operation unit of the operation terminal device 31 in which this setting is made is operated to turn on the illumination load associated with the operation unit. For example, the lighting load can be turned on at a specified dimming level. The setting contents of one cell can be determined by using the execution key K16, and the setting contents of one cell can be deleted by using the cancel key K17.
[0038]
After the address setting for one screen is completed by the above-described operation, the setting device 34 is set so that the infrared wireless signal can be transmitted / received only to / from the terminal device to which the address and function data are set. If the key K13 is pressed close to the device and the key K13 is pressed, a wireless signal is transmitted to the terminal device and the settings on the screen can be stored in the data storage section of the terminal device. When setting the contents of another terminal, the above operation can be repeated. However, if the forward key K18 is pressed, only the address (channel number) is forwarded (incremented by one). D) The same setting content can be displayed on the screen of the liquid crystal display 25.
[0039]
By the way, in the address setting mode, if the confirmation key K11 is pressed while the setting device 34 is close to the terminal device, the setting contents of the data storage section in the terminal device are read out and displayed on the screen of the liquid crystal display 25. Is done. Therefore, in the case of the existing remote monitoring control system, the address and function data may be set after confirming the contents of the data storage unit with the confirmation key K11. By such an operation, it is also possible to use the already set contents.
[0040]
The operation terminal 31 having a switch can be used for any of an individual switch, a pattern switch, a group switch, and a dimming switch. However, the operation terminal 31 is connected to an external switch or a sensor. Those must be distinguished from the operation terminal 31 provided with a switch. Also, of course, the relay 32a and the dimming control terminal 32c must be distinguished. In the address setting mode, the type of the device for which the address is set can be changed. When the device type is changed, a window W1 as shown in FIG. 6 is displayed, but this process is not described in detail. . The device type for which an address is to be set is indicated by the position of the marker M that moves along the lower side of the liquid crystal display 25.
[0041]
After the address and function data are set in each terminal as described above, pattern setting and group setting can be performed. That is, when the pattern setting mode is selected by the key K22, a screen as shown in FIG. 7 is displayed. At this time, the marker M corresponding to the character of "pattern setting" is displayed in reverse video. In this state, it is possible to select between group setting and pattern setting by pressing the key K31 or the key K32. Alternatively, even if the page key K15 is operated in a state where the cells in one row and one column are highlighted, it is possible to select between group setting and pattern setting. Further, if the page key K15 is operated after the group key or the pattern key is determined by the execution key K16, the group number or the pattern number can be designated. The illustrated example shows a state where the pattern number is 1, and “P1” is displayed in one row and one column. The contents of the pattern settings are stored in the RAM 22. When an external storage device is connected, the contents registered in the external storage device can be read and stored in the RAM 22.
[0042]
The group setting is a setting for collectively controlling the state of each load so as to be equal, and can be said to be a special case in which the state of each load is individually set like the pattern setting. Therefore, only the pattern setting will be described below. In the pattern setting mode, as shown in FIG. 7, the first column displays a pattern number, whether or not there is a fade, and whether or not there is a designation to turn on or off a load connected to one terminal at a time. Is done. These contents can be specified by operating the page key K15 in a state where the corresponding cells are highlighted. For the fade, no fade, 3 seconds for the fade, 5 seconds for the fade, and 1 minute for the fade can be specified. For the batch on / off of the load, no batch, batch on, and batch off can be specified. The address is displayed in the second column, but only the channel number can be specified with the page key K15. Further, the same setting as the address setting can be performed for the third to fifth columns.
[0043]
As described above, in the pattern setting mode, the content for each terminal can be set. In the illustrated example, an example in which the same pattern number is assigned to a plurality of load numbers by one terminal is shown. However, even if a procedure of assigning the same pattern number to a plurality of terminals is adopted, the terminal belongs to the pattern number. The load can be controlled collectively. When pattern setting is performed for each terminal device, the setting contents are stored in the RAM 22. Therefore, by referring to the contents of the RAM 22, it is possible to know whether or not a pattern has been set for each terminal. Therefore, when the pattern setting is completed for one terminal and the forward key K18 is operated to select the terminal of the next channel, if a pattern has already been set for the terminal, a warning sound is issued. (Not shown in FIG. 2, a buzzer for generating a warning sound is provided in the setting device 34), and it is confirmed whether the screen of the liquid crystal display 25 can be overwritten as shown in FIG. 8. Window W2 is displayed. Here, if the forward key K18 or the execution key K16 is operated, the data is overwritten, and if the cancel key K17 is operated, the change of the contents of this channel is stopped. To end the pattern setting, the setting key K13 is operated.
In the pattern setting mode, when a pattern number is specified, the minimum value of the address set to the closest and smaller pattern number than the specified pattern number is displayed on the liquid crystal display 25. That is, in pattern setting, it is empirically known that many terminals belonging to successive pattern numbers have close addresses, so that the address of a terminal belonging to a close pattern number is displayed to enable pattern setting. Setting work becomes easy. Since the setting device 34 used in the present embodiment is relatively small and the screen of the liquid crystal display 25 is small, the number of addresses that can be displayed at a time is relatively small, and screen selection is required when selecting an address. By adopting such a display mode, the possibility of reducing the number of screen feeds increases.
[0044]
Further, when confirming the contents of the pattern setting, when the confirmation key K11 is operated by designating the pattern number, the pattern is displayed on the screen of the liquid crystal display 25 from the smallest address belonging to the designated pattern number. For example, if the minimum value of the address belonging to the pattern of pattern number 1 is 10 channels and the maximum value is 16 channels, the address is displayed on the screen from 10 channels. This also prevents unnecessary channel numbers from being displayed on the screen, and reduces the number of screen feeds.
[0045]
In the above-described procedure, pattern setting is performed for each terminal. However, there is a relatively large amount of work of setting the load to the same state in a plurality of terminals having consecutive addresses. Therefore, by operating the special key K24 in the pattern setting mode, an edit window W3 for batch registration as shown in FIG. 9 can be displayed. In the editing window W3, if the start and end of the continuous address are designated by the page key K15 and whether the load state is turned on or off, the load corresponding to the address in the designated range is obtained. The same state is controlled collectively. Here, a field is designated by the cursor key K14 to set the head, end, or load state of the address, and the contents of the field are designated by the page key K15. Such an operation is the same in the following. When the pattern is set in the edit window W3, the control contents of a plurality of terminals can be specified collectively, so that the labor of the operation is greatly reduced. In order to end the editing screen P2, the user operates the cancel key K17.
[0046]
When the key K23 is operated, an initial setting mode for setting various functions of the setting device 34 is set, and the marker M is highlighted at a position corresponding to the character of "initial". When the initial setting mode is selected, as shown in FIG. 10, whether or not the buzzer sounds in response to the operation of the operation unit 13 (sound tone), the contrast of the screen of the liquid crystal display 25, the transmission control device (FIG. In the example shown, “transmission unit” is displayed), and the setting of the type and initial special setting of 30 is possible. The presence or absence of the buzzer is selected by the page key K15, and the contrast is displayed in a bar graph, and the stage is set by the page key K15. The type of the transmission control device 30 can be selected because there are various products in the transmission control device 30 and a procedure for transferring related data defining the contents of pattern setting and group setting to the transmission control device 30. This is because the form of the transmission signal is different. Specifically, the model number of the transmission control device 30 is selected by the page key K15. The cursor key K14 is used to move between the setting fields.
[0047]
However, when the transmission control device 30 is changed, a confirmation window W4 is displayed as shown in FIG. 11, and when the execution key K16 is operated in this state, the change of the transmission control device 30 becomes effective. is there. By operating the cancel key K17 in the display state of the window W4, the change of the transmission control device 30 can be stopped. Here, when the transmission control device 30 is changed in a state where some related data remains in the RAM 22 of the setting unit 34, there is a possibility that the related data does not belong to the target remote monitoring control system. For this purpose, a window W5 shown in FIG. 12 is displayed. Here, whether to convert the current related data so as to correspond to the selected transmission control device 30 (select YES with the cursor key K14 and operate the execution key K16) Select whether to leave as it is (select NO with the cursor key K14 and operate the execution key K16) or to delete the current related data (select erase with the cursor key K14 and operate the execution key K16). I do. When deletion is selected, a confirmation screen as to whether or not to delete is displayed (not shown). When the deletion is confirmed on the screen, the setting contents in the RAM 22 are deleted.
[0048]
By the way, in the initial special setting, it is possible to select three contents of an erroneous registration prevention mode, a power-off time, and a change in the number of connected terminals. For example, windows W6 to W8 shown in FIGS. 13 to 15 corresponding to the respective contents are displayed. When the execution key K16 is pressed in the window W6 of the erroneous registration prevention mode shown in FIG. 13, only the address where the terminal exists is displayed, and when the cancel key K17 is operated, all the addresses are displayed. Will be able to In other words, when the erroneous registration prevention mode is selected, it is possible to prevent addresses that are not used in the system from being included in the pattern setting or the group setting when setting the pattern or the group. That is, by referring to the setting contents of the RAM 22, it is possible to prevent an address that does not exist in the remote monitoring control system from being included in the pattern setting or the group setting.
[0049]
When the battery disconnection time is selected, a window W7 shown in FIG. 14 is displayed, and a selection is made as to whether or not to turn off the power after a fixed time after the keys are no longer operated (using the execution key K16 and the cancel key K17). Can be set, and when shutting down, the time can be set (using the page key K15).
[0050]
When the change monitoring of the number of connected terminals is selected, a window W8 shown in FIG. 15 is displayed, and it is selected whether or not to monitor a change in the number of terminals connected to the signal line Ls (the execution key K16 and the cancel key). Key K17). In this function, the state of the terminal is read into the RAM 22, and when the number of terminals changes based on the data in the RAM 22, the address of the added or deleted terminal is displayed on the liquid crystal display 25. That is, if this function is used, it is easy to find a portion where the connection between the terminal device and the signal line Ls is unstable.
[0051]
When the special mode is selected by operating the key K24, the marker M is highlighted at the position of the character "special". In the special mode, the screen shown in FIG. 16 is displayed, and the four modes of data transfer, check, edit, and setting are selected by operating the page key K15, and then each mode is selected by operating the execution key K16. .
[0052]
The data transfer is a mode for selecting whether to transfer the related data to the transmission control device 30 or to an IC card as a printer or an external storage device. After the selection by the page key K15, the operation key K16 is operated. Then, the transfer partner can be determined (the transmission control device 30 is selected in FIG. 16). Here, when reading, writing, or content collation is selected with the page key K15, a screen as shown in FIG. 17 is displayed (however, FIG. 17 shows writing (output)). If any of the keys K31 and K32 is operated on this screen, the screens of FIGS. 18 and 19 are sequentially selected. By pressing the execution key K16 on the screen of FIG. 18, all the related data is transferred. On the screen of FIG. 18, by specifying the range of the pattern number and pressing the execution key K16, the relation of the specified range is obtained. Only data is transferred. Here, the related data to be transferred is only the data having the set contents, and the data is not transferred for the unused pattern numbers and group numbers. As a result, it is possible to prevent the signal line Ls from being used for transferring unnecessary data and suppress an increase in traffic on the signal line Ls. The page key K15 is used to specify the pattern number. In short, the field is selected with the cursor key K14 and the input value is specified with the page key K15, as in the case of other designations. If the user wants to stop the transfer during the transfer of the related data, he operates the cancel key K17. When the transmission control device 30 is a transfer partner, it goes without saying that the transmission control device 30 is connected to the signal line Ls using the connection line 17.
[0053]
Checks include a system status display that indicates the operating status of the remote monitoring and control system, an operation check whether the remote monitoring and control system actually operates using the set related data, and an indication of an unused address in the remote monitoring and control system. In addition, the remote monitoring control system has a function of determining whether or not the address of each terminal device is used for pattern setting or group setting (referred to as terminal registration display). Therefore, to perform the check, it is necessary to be connected to the signal line Ls via the connection line 17.
[0054]
In the system status display, the screen of FIG. 20 is displayed, and the on / off state of the load of each load number is displayed for each channel. Unused channels are indicated by "-". For this display, data on the on / off of the load managed by the transmission control device 30 may be read into the RAM 22 and the contents of the RAM 22 may be monitored. By using this function, it is possible to reduce a trouble that the same address is duplicatedly set in a plurality of terminals at the time of site adjustment.
[0055]
The operation check is a mode for checking whether the address is appropriately set in the control terminal by using the setting device 34 in place of the operation terminal device. After selecting the operation check mode, the cursor key K14 is used. By using the page key K15, screens as shown in FIGS. 21 to 23 can be displayed. That is, when the screen shown in FIG. 21 is displayed, pattern control becomes possible, and on the screen shown in FIG. 22, dimming control becomes possible. By operating the execution key K16 while these screens are displayed, the pattern numbers (group numbers) or addresses displayed on the screens are compared with the relevant data of the transmission control device 30. The pattern number and the address can also be selected by operating the cursor key K14 and the page key K15.
[0056]
Now, in the case of the pattern control shown in FIG. 21, the address corresponding to the pattern number specified by operating the execution key K16 is collated, and a screen as shown in FIG. 23 is displayed. As a result of the collation, if the terminal of the address exists, the character of "collation" disappears after the completion of the collation, and the screen shifts to the screen of FIG. 24. If the collated address does not exist, as shown in FIG. The window W9 displays that control is impossible. In addition, addresses that do not correspond are displayed. Further, when a plurality of uncorresponding addresses exist, a downward triangle mark N is displayed, and when this mark N is displayed, another address can be sequentially displayed by operating the page key K15. In short, the relation data between the setting device 34 and the transmission control device 30 can be collated. By using this function, it is possible to confirm that the relevant data transferred from the setting device 34 to the transmission control device 30 is definitely set in the transmission control device 30.
[0057]
When the user selects to display an unused address, a screen as shown in FIG. 26 is displayed. On this screen, channels having unused addresses and load numbers are displayed. Channels having unused addresses are displayed side by side, and whether or not a load number is used for each channel is displayed vertically. The ON / OFF of the load is displayed at the address in use. The difference between this screen and the system status display of FIG. 20 is that the system status display shows information of all channels used in the remote monitoring control system, while the screen of FIG. Is that only the information is displayed.
[0058]
When the terminal registration display is selected, a screen for inputting an address of a desired load is displayed as shown in FIG. 27. After selecting an address with a page key in a state where a field is selected with a cursor key K14, an execution key is displayed. By operating K16, it is possible to search whether the load of the selected address is used in pattern setting or group setting. The search result is displayed on a screen as shown in FIG. 28, and a list of pattern numbers and group numbers using the addresses is displayed. Here, it can be seen that the load having the address “12-3” is used for the pattern setting of the pattern numbers 1, 2, and 3 and the group setting of the group numbers 10 and 126. By using this function, when an unnecessary load is operating during pattern control or group control, it is easy to know which pattern or group the load belongs to, so that the contents of the pattern setting or group setting can be easily understood. Is easier to correct.
[0059]
In the special mode, when editing is selected, inversion, copy, deletion, and range designation input can be selected. These selections can be performed by operating the execution key K16 in a state where a desired item is selected by the page key K15 as in the above-described example. When the inversion is selected, a screen shown in FIG. 29 is displayed, and it is possible to invert the on / off state of the load set in the pattern setting or the group setting. On this screen, a desired pattern number or group number is selected by a page key K15 while a field in which a pattern number or a group number is displayed is selected by a cursor key K14, and a pattern setting or a group is operated by operating an execution key K16. The setting state of the load on / off in the setting can be reversed.
[0060]
When the copy is selected, the screen shown in FIG. 30 is displayed, and the setting contents of a specific pattern number or group number can be copied as the setting contents of another pattern number or group number. That is, when the pattern key or group number of the copy source and the pattern number or group number of the copy destination are designated and the execution key K16 is operated, the same contents are copied from the copy source to the copy destination. Here, the page key K15 is used for selecting a pattern number or a group number.
[0061]
When the deletion is selected, the screen shown in FIG. 31 is displayed, and the deletion of the related data stored in the RAM 22 becomes possible. The range of erasure is any of all data, all patterns, and all groups. If any one is selected using the page key K15 and the execution key K16 is operated, the related data in the selected range is erased. .
[0062]
In the range designation input, it is possible to select whether only addresses in a desired range are to be set for pattern setting or group setting, or addresses in the range are not to be set for pattern setting or group setting. That is, when the range designation input is selected, a state is entered in which a pattern number or a group number is selected, and when a pattern number or a group number is selected, a range of an address is entered. Here, when a range of addresses is given, it becomes possible to select whether the load in that range is turned on, turned off, or excluded from control. Further, when the dimming control of the load is possible, the input of the dimming level becomes possible.
[0063]
In the setting state mode in the special mode, it is possible to select whether the remote monitoring control system is in a normal state in which load control is performed or a setting state in which related data is set in the transmission control device 30. That is, a window W10 as shown in FIG. 32 is displayed, the current state (whether the normal state or the setting state) is shown, and it is confirmed whether or not to change to another state. Here, by selecting whether or not to change with the page key K15 and operating the execution key K16, it is possible to instruct the remote monitoring control system whether or not the operation state has changed. The change of the operation state is realized by giving an instruction to the transmission control device 30 using a normal transmission signal.
[0064]
In the setting mode, numbers used in pattern setting and group setting can be displayed in a list. That is, as shown in FIG. 33, eight pattern numbers or group numbers are displayed on the screen of the liquid crystal display 25, and when each number is used, a circle is displayed. To change the displayed pattern number or group number, the page key K15 is operated. With this function, it is possible to reduce the erroneous operation of changing the contents of the pattern number or group number for which the related data is set. This function can be realized by referring to the contents of the RAM 22.
[0065]
Further, in the setting state mode, the setting state of the address used for each pattern number or group number can also be displayed. That is, as shown in FIG. 34, the setting content of each address is displayed on the screen of the liquid crystal display 25 for each pattern number or group number. In the illustrated example, the setting contents of each load from channel 0 to channel 3 are shown for the switch whose pattern number is 1. If the page key K15 is operated in this state, the setting state of the load of another channel is also displayed. Note that "-" indicates that the address is not used in the remote monitoring control system.
[0066]
Incidentally, in addition to the above-described functions, the setting unit 34 in the present embodiment also has the following functions. For example, when connected to the signal line Ls when the power is turned on, there is a function of confirming the model number of the transmission control device 30 when the power is turned on. That is, a window W11 as shown in FIG. 35 is displayed, a signal for requesting a model number is transmitted to the transmission control device 30 using the transmission signal, and transmission control is performed in response to a response from the transmission control device 30 to this request. The model number or type of the device 30 is confirmed. This processing is performed when a normal transmission signal used for load control is used as a transmission procedure of related data between the setting unit 34 and the transmission control device 30, or a special signal having a format different from the transmission signal is used. This is because the transmission procedure differs depending on the transmission control device 30. When the type of the transmission control device 30 is confirmed, if the type is different from the current type in the setting device 34, a window W12 as shown in FIG. It is confirmed whether to change the type. Here, by using the page key K15 to select whether or not to change the type and operating the execution key K16, it is possible to determine whether or not to change the type of the transmission control device 30.
[0067]
The portion corresponding to the lower side of the liquid crystal display 25 in the setting device 34 has a notation of "battery depleted", and the liquid crystal display 25 displays a graphic indicating a battery at a portion corresponding to this notation. Indicates the remaining amount of the battery (three rectangles are arranged in a horizontal line, and the remaining amount is displayed such that the number of the inverted rectangles increases as the battery capacity increases). Here, if the capacity of the battery is reduced to such an extent that a specific process cannot be performed, a window W13 screen prompting for battery replacement is displayed on the liquid crystal display 25 as shown in FIG. You. For example, it may take 30 to 40 minutes to transfer the relevant data to the transmission control device 30, and if the battery runs out during this operation, the operation is wasted. Waste of work can be prevented. If the capacity of the battery is further reduced, a window W14 prompting for battery replacement is displayed as shown in FIG. 38 regardless of whether or not some processing is performed.
[0068]
By the way, when an error occurs during execution of various functions, the occurrence of the error is displayed on the screen of the liquid crystal display 25. FIG. 39 shows a state in which a transmission signal (in the illustrated example, the transmission signal is called a “full two-wire signal”) is not detected when a function to be performed in a state connected to the signal line Ls of the remote monitoring and control system is to be executed. When the operator wants to know the contents of the error, he operates the execution key K16. To cancel the execution of the function without confirming the contents, the user operates the cancel key K17. When the execution key K16 is operated, the screen shown in FIG. 40 is displayed, indicating that either the connection is not made to the signal line Ls or the transmission control device 30 is not operating. On this screen, if the user wants to know further measures, he operates the execution key K16 to display the screen shown in FIG. By operating the cancel key K17 on the screens of FIGS. 40 and 41, it is possible to return to the previous screen.
[0069]
FIG. 42 shows a state in which control cannot be performed. If the execution key K16 is operated on this screen, the screen shown in FIG. 43 is displayed to explain the cause of the error. Here, it is displayed that the remote monitoring control system is set. By further operating the execution key K16, as shown in FIG. 44, a method of dealing with this cause is shown. At this point, whether or not to perform the treatment can be selected by using the execution key K16 or the cancel key K17. If the execution of the treatment is selected by the execution key K16, the setting state is released as shown in FIG. 45, and if the cancel key K17 is operated, the display can return to the previous screen.
[0070]
The same applies to other errors. For example, in FIG. 46, data cannot be input / output to / from the transmission control device 30, in FIG. 49, control cannot be performed, and in FIG. Each state cannot be shown. Further, by operating the execution key K16 when each error is displayed, detailed information of each error can be displayed as shown in FIGS. 47, 50 and 53, and the detailed information is displayed. By operating the execution key K16 at times, the treatment can be displayed as shown in FIGS. In short, when an error is detected, the fact that an error has occurred is displayed, and details and actions are displayed as necessary. If the error is relatively simple, the error can be dealt with by instructions on the screen.
[0071]
The setting unit 34 has various functions for site adjustment, and has a function of confirming the control operation of the remote monitoring control system and storing a control history. For example, as shown in FIG. 55, "operation check" or "other" is selected, and when the "operation check display item" screen as shown in FIG. 56 is displayed, the control data of the transmission signal is displayed. "Control command" to be displayed, "operation address" to display the address of the transmission signal, and "retry count" to select the number of times the relay operation of the relay terminal 32a is tried are selected. As the operation history, a list of control histories is displayed as shown in FIG. 57, and the display can be scrolled by using the page key K15.
[0072]
【The invention's effect】
According to the first aspect of the present invention, a storage unit for assigning an identifier to each set of the correspondence relationship between each switch and a load and storing related data, a display unit capable of displaying various information, and instructing processing contents. An operation unit, and a central processing unit that, when the address of the terminal device on the load side is specified by the operation unit, inquires related data stored in the storage unit and displays an identifier using the specified address on the display unit. For example, when a load that is not to be controlled is operated during batch control such as pattern control or group control, the address of the load is specified and an identifier (pattern number or group number) is specified. , An erroneous setting in the pattern setting or the group setting can be easily found. In other words, field adjustment in pattern setting and group setting becomes easy.
[0073]
According to a second aspect of the present invention, there is provided a storage unit for assigning an identifier to each set of the correspondence relationship between each switch and a load and storing related data, a display unit capable of displaying various information, and instructing processing contents. An operation unit, and a central processing unit for inquiring related data stored in the storage means in accordance with an instruction from the operation unit and displaying an available and unused identifier on a display unit. By displaying, the settable identifier can be easily known, and it is possible to prevent the setting contents of the already set identifier from being changed.
[0076]
Claim 3 The invention of The identifier is a sequence number, and the central processing unit When an identifier is specified by the operation unit when setting the related data, the display is started from the smallest address among the addresses of the loads associated with the closest identifier smaller than the specified identifier. Rumo Therefore, when trying to set related data similar to continuous identifiers, the time required to specify a terminal can be reduced, and the related data can be set efficiently even when a relatively small screen display is used. can do.
[0077]
Claim 4 The invention of The central processing unit A central processing unit for displaying the load address associated with the identifier specified by the operation unit at the time of confirming the relation data from the smallest address on the display unit, and confirming the set relation data At this time, since the display is started from the smallest address associated with the identifier, unregistered terminals are not displayed, and the time required for confirming the terminals can be reduced. If no terminal is registered for the specified identifier, the lowest address is channel 0. As a result, an unused identifier can be easily known, and the possibility of erroneously setting related data to a preset identifier can be reduced.
[0078]
Claim 5 The invention of The central processing unit In accordance with an instruction from the operation unit, the relation data in which an identifier is added to a set of the correspondence relation between the switch and the load is selectively transferred to the transmission control device. Rumo Since unnecessary data is not transferred, related data can be transferred in a short time.
[0079]
Claim 6 The invention of Equipped with a battery as a power supply, the central processing unit, Check the battery capacity at the start of work according to the instruction from the operation unit.When there is no battery capacity until the end of work, display that fact on the display. Rumo In addition, if there is a possibility that the battery runs out during the work, the battery is notified by the display, so that it is possible to prevent the battery from running out during the work.
[0080]
Claim 7 The invention of The central processing unit The related data set in the transmission control device is compared with the related data stored in the storage means in accordance with an instruction from the operation unit, and the difference is displayed on the display unit. Rumo By comparing the related data set in the setting device with the related data set in the transmission control device, whether the same related data has already been set in the transmission control device or transferred from the setting device. It is possible to easily confirm whether or not the related data has been surely set in the transmission control device.
[Brief description of the drawings]
1 shows an embodiment of the present invention, wherein (a) is a front view, (b) is a side view, and (c) is a plan view.
FIG. 2 is a schematic configuration diagram showing a usage example of the above.
FIG. 3 is a diagram showing an example of a connection line used in the embodiment.
FIG. 4 is a block diagram of the same.
FIG. 5 is an operation explanatory view of the above.
FIG. 6 is an operation explanatory view of the above.
FIG. 7 is an operation explanatory view of the above.
FIG. 8 is an operation explanatory view of the above.
FIG. 9 is an operation explanatory view of the above.
FIG. 10 is an operation explanatory view of the above.
FIG. 11 is an operation explanatory view of the above.
FIG. 12 is an operation explanatory view of the above.
FIG. 13 is an operation explanatory diagram of the above.
FIG. 14 is an explanatory diagram of the operation of the above.
FIG. 15 is an operation explanatory view of the above.
FIG. 16 is an operation explanatory view of the above.
FIG. 17 is an operation explanatory view of the above.
FIG. 18 is an explanatory diagram of the above operation.
FIG. 19 is an explanatory diagram of the operation of the above.
FIG. 20 is an explanatory diagram of the operation of the above.
FIG. 21 is an explanatory diagram of the operation of the above.
FIG. 22 is an explanatory diagram of the operation of the above.
FIG. 23 is an explanatory diagram of the operation of the above.
FIG. 24 is an explanatory diagram of the above operation.
FIG. 25 is an explanatory diagram of the operation of the above.
FIG. 26 is an explanatory diagram of the operation of the above.
FIG. 27 is an explanatory diagram of the above operation.
FIG. 28 is an explanatory diagram of the operation of the above.
FIG. 29 is an explanatory diagram of the operation of the above.
FIG. 30 is an explanatory diagram of the operation of the above.
FIG. 31 is an explanatory diagram of the above operation.
FIG. 32 is an explanatory diagram of the above operation.
FIG. 33 is an explanatory diagram of the operation of the above.
FIG. 34 is an explanatory diagram of the above operation.
FIG. 35 is an explanatory diagram of the above operation.
FIG. 36 is an explanatory diagram of the above operation.
FIG. 37 is an explanatory diagram of the operation of the above.
FIG. 38 is an explanatory diagram of the above operation.
FIG. 39 is a diagram illustrating the operation of the above.
FIG. 40 is an explanatory diagram of the above operation.
FIG. 41 is an explanatory diagram of the operation of the above.
FIG. 42 is an explanatory diagram of the operation of the above.
FIG. 43 is an explanatory diagram of the above operation.
FIG. 44 is an explanatory diagram of the operation of the above.
FIG. 45 is an explanatory diagram of the operation of the above.
FIG. 46 is an explanatory diagram illustrating the operation of the above.
FIG. 47 is an explanatory diagram of the operation of the above.
FIG. 48 is an explanatory diagram of the above operation.
FIG. 49 is an explanatory diagram of the operation of the above.
FIG. 50 is an explanatory diagram of the operation of the above.
FIG. 51 is an explanatory diagram of the above operation.
FIG. 52 is an explanatory diagram illustrating the operation of the above.
FIG. 53 is an explanatory diagram illustrating the operation of the above.
FIG. 54 is an explanatory diagram of the operation of the above.
FIG. 55 is an explanatory diagram of the operation of the above.
FIG. 56 is an explanatory diagram of the operation of the above.
FIG. 57 is an explanatory diagram of the operation of the above.
FIG. 58 is a diagram showing a configuration example of a conventional remote monitoring control system.
FIG. 59 is an explanatory diagram of the above operation.
[Explanation of symbols]
L load
Ls signal line
S operation unit
Sa operation unit
Sb operation unit
12 Display
13 Operation section
20 Central processing unit
22 RAM
25 LCD display
30 Transmission control device
31 Operation terminal
31a Individual switch
31b pattern switch
31c dimming switch
32a relay terminal
32c dimming terminal
34 Setting device

Claims (7)

A plurality of terminals each having an address are branched and connected to a signal line, and a transmission control device connected to the signal line transmits and receives a transmission signal by a time-division multiplexing transmission method between each terminal and the transmission control device. Data is transmitted and received between terminals using an address correspondence defined by relation data set in the device, and a load connected to another terminal is controlled according to an operation of a switch provided in the terminal. A setting device that is used in a remote monitoring and control system, creates related data for controlling a plurality of loads by operating one switch, and sets the related data to a transmission control device via a signal line. Storage means for assigning an identifier to each set of address correspondences and storing related data, a display unit capable of displaying various information, an operation unit for instructing processing contents, and an operation unit A central processing unit which, when the address of the terminal on the load side is designated, inquires the relational data stored in the storage means to display an identifier using the designated address on the display unit. Setting device for remote monitoring and control system. A plurality of terminals each having an address are branched and connected to a signal line, and a transmission control device connected to the signal line transmits and receives a transmission signal by a time-division multiplexing transmission method between each terminal and the transmission control device. Data is transmitted and received between terminals using an address correspondence defined by relation data set in the device, and a load connected to another terminal is controlled according to an operation of a switch provided in the terminal. A setting device that is used in a remote monitoring and control system, creates related data for controlling a plurality of loads by operating one switch, and sets the related data to a transmission control device via a signal line. Storage means for assigning an identifier to each set of address correspondences and storing related data, a display unit capable of displaying various information, an operation unit for instructing processing contents, and an operation unit Setter for remote monitoring and control system, comprising a central processing unit for displaying on the display unit the identifier of the available and unused queries the relationship data stored in the storage means according to an instruction al. The identifier is a sequence number, and when the central processing unit specifies the identifier by the operation unit when setting the relation data, the central processing unit specifies the smallest one of the addresses of the loads associated with the closest identifier smaller than the specified identifier. setter for remote monitoring and control system according to claim 1 or claim 2, wherein the address and wherein the to be displayed on the display unit. The central processing unit, according to claim 1 or claim, characterized in that to be displayed on the display unit from the smallest address among the addresses associated with the specified identifier load by the operation unit when checking the relationship data 3. A setting device for the remote monitoring and control system according to 2 . The central processing unit, according to claim, characterized in that to transfer selectively to the transmission control device the relationship data assigned with the the set of correspondence between the address of the switch and the load identifier in accordance with an instruction from the operating unit A setting device for a remote monitoring and control system according to claim 1 or 2 . A battery as a power source is provided, and the central processing unit checks the battery capacity at the start of work according to an instruction from the operation unit, and displays the fact on the display when there is no battery capacity until the end of the work. A setting device for a remote monitoring and control system according to claim 1 or 2 . The central processing unit compares the relational data set in the transmission control device with the relational data stored in the storage unit according to an instruction from the operation unit, and causes the display unit to display the difference. A setting device for a remote monitoring and control system according to claim 1 or 2 .

Images