JP2728352B2 - Centralized management system for handset - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a centralized management system for remote units, in which a plurality of remote units are remotely controlled by one master unit.

[0002]

2. Description of the Related Art For example, in a school, s heating units (child units) installed in each classroom and one central monitoring unit (master unit) installed in a staff room are connected by a communication line, and heating is performed. A centralized management system for slave units, which communicates between the control circuit on the machine side and the control circuit on the monitoring device side, and centrally starts and stops the operation of the heater (slave unit) with the central monitoring device (master unit) Are known. The central monitoring device is provided with t (for example, 30) operation switches and display lamps each assigned a registration number of 1 to t in the arrangement order, and by operating the operation switch, an arbitrary number can be set. An operation start instruction and an operation stop instruction are sent to the heater. When the start of the operation is instructed, the display lamp is turned on, and when the stop of the operation is instructed, the display lamp is turned off. In addition, the central monitoring device communicates with all the heaters when the power is turned on, and blinks the display lamp corresponding to the registration number in the case of a communication error.

However, generally, the number s of heaters to be controlled is s.
Is hardly equal to the maximum number t that can be controlled by the central monitoring device, and is often smaller than the maximum number t. Therefore, when the power of the central monitoring device is turned on, communication is performed with all registration numbers (1 to t). In the case of checking for a communication error, the display lamp blinks as a communication error in the same manner for both the registration number not used in the slave unit and the communication error, so that the two cannot be distinguished. Therefore, in the conventional central monitoring device, the registration number of the connected heater is registered at the time of the first use, and is stored in a storage device such as an E ² PROM. The registration data is read out, communication is performed only with the registered data, and a communication abnormality is checked.

[0004]

However, the conventional centralized management system for child units has the following drawbacks. The central monitoring device (master unit) uses the registration number set for the heater (slave unit)
When registering by, for example, it is necessary to switch the changeover switch provided on the back of the central monitoring device to the registration side, and to press all the operation switches of the central monitoring device corresponding to the set registration number one by one. However, it is troublesome and there is a possibility that the operation switch may be erroneously pressed. SUMMARY OF THE INVENTION It is an object of the present invention to make it possible to easily register a child device in a centralized management system of the child device in which a plurality of child devices are remotely controlled by one parent device.

[0005]

In order to solve the above-mentioned problems,
The present invention relates to a centralized management system for slave units, wherein a slave unit side control circuit and a master unit side control circuit are connected by a communication line, and n slave units are remotely controlled by one master unit. Registration numbers 1 to m are assigned in the order of arrangement, and there are m (where m ≧ n) operation switches for instructing start / stop of the slave unit and a memory for storing the registration number set in the slave unit. A base unit having a base unit side control circuit, number setting means for setting registration numbers from 1 to m different for each slave unit, and an answer when a number signal corresponding to the registration number is input from the base unit. And a slave unit having a slave unit control circuit for transmitting a signal to the communication line.
The number signal is sequentially transmitted to the communication line, and the registration number of the slave unit that has returned the answer signal is stored in the memory.After that, the registration number corresponding to each operation switch of the master unit is stored in the memory. A configuration is adopted that enables transmission only to the stored registration number of the slave unit.

[0006]

[Function] In the slave unit, 1 is set so that the registration number is different for each slave unit.
The setting of the registration numbers up to m is performed by the number setting means.
On the other hand, the base unit side control circuit of the base unit sequentially sends the number signals 1 to m to the communication line. When a number signal corresponding to the set registration number is sent via the communication line, the slave unit control circuit returns an answer signal to the master unit side control circuit via the communication line. The master-side control circuit automatically registers the slave unit by storing the registration number of the slave unit that has returned the answer signal in the memory. After that, when transmitting a signal from the master unit side control circuit to the slave unit side control circuit, it is necessary to transmit only the registration number stored in the memory among the registration numbers corresponding to each operation switch of the master unit. It is possible, and transmission to other registration numbers is prohibited.

[0007]

When a desired number of slave units having different registration numbers set for each slave unit are connected to a communication line and the system is started up for the first time, the changeover switch provided on the master unit is changed to the registration side as in the prior art. , And manually pressing the operation switches corresponding to the set registration number one by one manually eliminates the need to perform the registration work of the slave unit, making it easy to register the slave unit. Does not occur.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described with reference to FIGS. As shown in FIG.
, 129, 130, indicator lamps 201, 202, 229, 230, all ignition switch 301, all fire extinguishing switch 302, registration switch 30
3, a central monitoring device 1 having a master unit-side control circuit 12 having a memory 121 and a heating unit 2 having a registration number setting circuit 21, an actuator 22, and a slave unit-side control circuit 23. 2 and a coaxial cable 3 for electrically connecting the central monitoring device 1 and the heaters 2, 2,... Reference numeral 304 denotes a power switch, 305 denotes a buzzer stop switch, 306 denotes an abnormality notification lamp, 307 denotes a gas leak notification lamp, and 308 denotes a communication abnormality lamp.

The operation switches 101, 102... 129, 130 electrically connected to the base unit side control circuit 12 are normally open push button switches, and are numbered 1 to 3 in order from the left end.
A registration number of 0 is assigned, and a pressing operation instructs start / stop of the operation of the heaters 2, 2,...

The display lamps 201, 202,... 229, 230 (light emitting diodes) electrically connected to the base unit side control circuit 12 are operation switches 101, 102,.
It is arranged above the position 30.

The all-ignition switch 301 electrically connected to the base-unit-side control circuit 12 is a normally-open push-button switch, and all the heaters 2, 2,... It becomes an operation state.

The full fire extinguishing switch 302 electrically connected to the base unit side control circuit 12 is a normally open type push button switch, and all the heating units 2, 2,... The operation is stopped.

The registration switch 303 is a normally-open push-button switch. The function is enabled when the system is started up for the first time, and an instruction to start registration and an instruction to complete registration are given by a pressing operation.

As shown in FIG. 6, a master unit side control circuit 12 having a microcomputer, at the time of registration, number signals 401 to 401 corresponding to registration numbers 1 to 30,
402... 406, 407.
At the intervals, the signals are sequentially transmitted to the coaxial cable 3 and an answer signal (for example, 502, 5
03, 505, 506), the operation switches (for example, 102, 103, 105, 106) corresponding to the registration numbers of the heaters 2, 2,.
Display lamps (e.g., 202, 203,
205, 206) are turned on. Also, in this state,
When the registration switch 303 is pressed, the registration number (for example,
The registration numbers 2, 3, 5, and 6 are stored in the memory 121 (E ² PR
OM). Then, at the time of normal use (second and subsequent times), the base unit side control circuit 12 stores the stored registration number (for example,
It is possible to transmit only to the registration numbers 2, 3, 5, and 6).

The registration number setting circuit 21 connected to the slave unit side control circuit 23 sets different registration numbers 1 to 30 to the heaters 2, 2,...

The actuator 22 connected to the slave unit side control circuit 23 is a proportional valve, a solenoid valve, a sparker, a combustion fan, a convection fan, etc., which controls the heating operation of the heater 2.

When a number signal corresponding to a registration number is input at the time of system startup (at the time of initial operation), a slave-side control circuit 23 having a microcomputer receives answer signals (for example, answer signals 502, 503, and 505). , 50
6) is sent to the parent device side control circuit 12 via the coaxial cable 3.

The coaxial cable 3 has an impedance of 75Ω
5C-2V, and a two-way distributor 309 is provided on the way to provide two systems (for example, for the first floor and the second floor).

Next, the operation of the centralized management system A for the slave unit will be described with reference to the flowcharts of FIGS. 4 and 5 and the time chart of FIG. Steps s1 to s11 relate to the first system startup, and steps s12 to s19 relate to the second and subsequent system startups. First, a predetermined number of heaters 2, 2,... 2 are connected to the coaxial cable 3, and different registration numbers are respectively set by the rotary switch 211 to prepare for system startup. In step s1, the parent device side control circuit 12
It is determined from the content of 21 whether or not the operation is the first operation. If the operation is the first operation (YES), the process proceeds to step s2. If the operation is the second or subsequent operation (NO), the process proceeds to step s12. In step s2,
Master-side control circuit 12 determines whether registration switch 303 is pressed or not, and if pressed (YES), proceeds to step s3. In step s3, the master-side control circuit 12
Executes m = 1 and proceeds to step s4. Steps
In step 4, the master-side control circuit 12 determines whether or not m = 31. If m = 31 (YES), the process proceeds to step s9.
If m ≠ 31 (NO), the flow proceeds to step s5. In step s5, the master unit control circuit 12 sends out the number signal m (for example, the number signal 401) to the slave unit control circuit 23 via the coaxial cable 3, and proceeds to step s6.
In step s6, the base unit-side control circuit 12 determines whether or not an answer signal (for example, the answer signal 501) has been returned from the slave unit-side control circuit 23. If the answer signal has been returned (YES), the process proceeds to step s7. If not (NO), the flow proceeds to step s8. In step s7, the parent device side control circuit 12
The m-th display lamp (for example, the display lamp 201) is turned on, and the process proceeds to step s8. In step s8, the master-side control circuit 12 executes m ← m + 1 {increment m by 1}, and returns to step s4. In step s9, the parent device side control circuit 12 stops sending the number signal m, and proceeds to step s9.
Go to 10. In this step, display lamps (for example, the display lamps 202, 203, 205, and 206) corresponding to the registration number to be registered are turned on.
In step s10, base unit side control circuit 12 determines whether or not registration switch 303 has been pressed, and if pressed (YES), proceeds to step s11. Step s11
Then, the registration number (for example, registration numbers 2, 3, 5, and 6) of the heater 2 that has returned the answer signal is stored in the memory 121 (E ²
The display lamps (for example, the display lamps 202, 203, 205, and 206) stored and lit in the PROM are turned off, and the process proceeds to step s20.

On the other hand, as the start-up of the second and subsequent systems, the master-side control circuit 12 reads the registration number stored in the memory 121 at step s12, and
Proceed to 13. In step s13, the master-side control circuit 12
Executes m = 1, and proceeds to step s14. In step s14, base unit side control circuit 12 determines whether or not registration number m is a number stored in memory 121, and if it is a stored number (YES), step s15.
If it is not the stored number (NO), the flow proceeds to step s18. In step s15, the master unit control circuit 12 sends the number signal m to the slave unit control circuit 23 via the coaxial cable 3, and proceeds to step s16. In step s16, the parent device side control circuit 12
It is determined whether or not an answer signal has been returned from the server. If the answer signal has been returned (YES), the process proceeds to step s17. If not (NO), the process proceeds to step s19. In step s17,
m ← m + 1 {increment m by 1} is executed, and step s14 is executed.
Return to In step s18, the parent device side control circuit 12
= 31 or not, and if m = 31 (Y
ES) proceeds to step s20, and if m ≠ 31 (N
O) proceeds to step s17. In step s19, the master-side control circuit 12 considers that a communication error has occurred,
The second display lamp flashes, and the process proceeds to step s17.

After the start-up of the system for the first time or for the second time or later is completed, the mode shifts to the normal mode after step s20. In step s20, the master-side control circuit 12 determines whether or not all the ignition switches 301 have been pressed, and if pressed (YES), proceeds to step s21; if not (NO), proceeds to step s23. . Step s2
In step 1, the master-side control circuit 12 transmits the ignition signal for igniting the heaters 2 of all the registration numbers (for example, 2, 3, 5, and 6) stored in the memory 121 to the coaxial cable 3. The data is transmitted to the slave-side control circuit 23 via the sub-unit, and the process proceeds to step s22. In step s22, when the ignition signal is transmitted, the master-side control circuit 12 displays the display lamp (for example, the display lamps 202 and 20) corresponding to the registration number stored in the memory 121.
3, 205, 206) are turned on, and step s20
Return to If there is a heater 2 that does not go into the ignition state, the corresponding display lamp blinks, and the abnormality notification lamp 3
06 is turned on, and a buzzer (not shown) sounds. In step s23, master unit side control circuit 12 determines whether or not all fire extinguishing switch 302 has been pressed. If pressed (YES), the flow proceeds to step s24; if not (NO), the flow proceeds to step s26. . Step s24
The master-side control circuit 12 sends, via the coaxial cable 3, a fire extinguishing signal for extinguishing the heaters 2 of all registration numbers (for example, Nos. 2, 3, 5, and 6) stored in the memory 121. And sends it to the slave unit-side control circuit 23, and proceeds to step s25. In step s25, when the fire extinguishing signal is transmitted, the base unit side control circuit 12 displays the display lamp (for example, the display lamps 202 and 20) associated with the registration number stored in the memory 121.
3, 205, 206) are turned off, and step s20
Return to If there is a heater 2 that does not enter the fire extinguishing state, the corresponding display lamp blinks and the abnormality notification lamp 3
06 is turned on, and a buzzer (not shown) sounds. In step s26, the master-side control circuit 12 determines whether any of the operation switches 101, 102,... 129, and 130 has been pressed. If not (NO)
Returns to step s20. In step s27, the base unit-side control circuit 12 determines whether or not the heater 2 corresponding to the pressed operation switch is burning, and if it is burning (YES), proceeds to step s28 and burns If not (NO), the process proceeds to step s30. In step s28,
The base unit side control circuit 12 sends a fire extinguishing signal for stopping the combustion of the heater 2 corresponding to the pressed operation switch to the coaxial cable 3.
Is sent to the slave unit-side control circuit 23 via
Proceed to. In step s29, the master-side control circuit 12 turns off the display lamp corresponding to the pressed operation switch, and returns to step s20. If the fire is not extinguished, the indicator lamp flashes and the abnormality notification lamp 30 is turned off.
6 is turned on, and the buzzer sounds. Step s3
At 0, the master-side control circuit 12 sends out an ignition signal for causing the heater 2 corresponding to the pressed operation switch to be in the operating state to the slave-side control circuit 23 via the coaxial cable 3, and proceeds to step s31. In step s31, the master-side control circuit 1
2 turns on the display lamp corresponding to the pressed operation switch, and returns to step s20. If the ignition state is not established, the display lamp is turned on and off, the abnormality notification lamp 306 is turned on, and the buzzer is sounded.

This embodiment has the following advantages. (A) Up to 30 heaters 2, 2 ... 2 are coaxial cable 3
The registration work is started by pressing the registration switch 303 when the system is started up for the first time by setting different registration numbers by the rotary switch 211, respectively. 2, 2
Registration can be completed. For this reason, as before,
The changeover switch provided in the central monitoring device is switched to the registration side, and the operation switch of the central monitoring device corresponding to the registration number set in the heater is registered one by one. No work is required,
It is possible to easily register the heaters 2, 2, ..., 2, and it is not necessary to start up the system for the first time.
There is no registration error caused by the wrong operation switch pressing.

(I) When the system is started up for the first time, the registration switch 303 is depressed, and the transmission of the number signals 401, 402,..., 406, 407 (430) is completed. The configuration is such that the display lamps corresponding to the registration numbers of the heaters 2 to be registered are turned on. For this reason, at the time of normal use, it becomes apparent at a glance in step s9 which operation switch function is valid. Step s9
In this state, if a card describing the location of the heater is inserted into the holder 310, the relationship between the operation switch and the location of the heater 2 can be clarified.

(C) In the centralized management system A for the slave units, only the flowcharts need to be changed without changing the hardware of the conventional system, so that no significant increase in manufacturing cost is caused.

The present invention includes the following embodiments in addition to the above embodiment. a. In the above embodiment, the registration numbers from 1 to 30 are assigned from the left end, but the registration numbers from 1 to 30 from the right end may be assigned. b. The value of the variable m (the number of registration numbers and the number of operation switches) may be any number, and the number of slave units n may be any number as long as it is equal to or less than the variable m. c. In the above-described embodiment, the first operation is determined based on the contents of the memory 121 (step s1). However, when the registration switch 303 is pressed, an interruption occurs to shift from the normal operation mode to the registration mode. It may be configured.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram of a centralized management system for a child device according to an embodiment of the present invention.

FIG. 2 is a perspective view of a central monitoring device in the system.

FIG. 3 is a block diagram of the system.

FIG. 4 is a flowchart showing the operation of the system.

FIG. 5 is a flowchart showing the operation of the system.

FIG. 6 is a waveform chart showing the operation of the system.

[Explanation of symbols]

 A Central management system for slave units 1 Central monitoring device (master unit) 2 Heater (slave unit) 3 Coaxial cable (communication line) 12 Master unit control circuit 21 Registration number setting circuit (number setting means) 23 Slave unit control Circuits 101 to 130 Operation switch 121 Memory 401 to 407 Number signal 502, 503, 505, 506 Answer signal

Claims (1)

(57) [Claims] 1. A centralized management system for slave units, wherein a slave unit side control circuit and a master unit side control circuit are connected by a communication line, and n slave units are remotely controlled by one master unit. Registration numbers 1 to m are assigned in the order of arrangement, and m (where m ≧ n) operation switches for instructing start / stop of the slave unit and a memory for storing the registration number set in the slave unit are provided. A master unit having a master-side control circuit, number setting means for setting registration numbers from 1 to m different for each slave unit, and when a number signal corresponding to the registration number is input from the master unit A slave unit having a slave unit-side control circuit that sends an answer signal to the communication line.The master unit-side control circuit sequentially sends number signals 1 to m to the communication line at the time of slave unit registration. The registration number of the slave unit that has returned the answer signal is stored in the memory, and thereafter, A centralized management system for a handset that enables transmission only to the registration number of the handset stored in the memory among the registration numbers corresponding to the operation switches of the base unit.