JP2004088514A - Terminal device of remote monitoring control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a terminal device of a remote monitoring control system capable of confirmation the connection state and operation of a load even if in a state with no connection made to a signal line. <P>SOLUTION: In a normal operation, a contact of a relay Ry is inserted between a power supply terminal T2a for connecting a commercial power supply and a load terminal T3 for connecting a load, and the contact of the relay is opened and closed in accordance with the contents of a transmission signal inputted from a signal terminal T1. A power supply circuit 22 for supplying power source to an internal circuit makes the commercial power supply connected to the power supply terminal T2a to be an input power source and feeds power to a relay driving circuit 23. Then, if the commercial power supply is connected to the power supply terminal T2a, a power source for opening and closing the contact of the relay Ry is secured without receiving a transmission signal by an operation of a key input circuit 12. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a terminal of a remote monitoring and control system for monitoring and controlling a load from a distance.
[0002]
[Prior art]
Conventionally, as shown in FIG. 15, a plurality of terminals 42 and 43 are connected to a transmission unit 41 via a two-wire signal line Ls, and provided on a terminal (hereinafter referred to as an operation terminal) 42. A remote monitoring control system is provided in which a load L is controlled via a relay Ry provided in a terminal device (hereinafter referred to as a control terminal device) 43 in response to the operation of the switch SW. An address is set in each of the operation terminal 42 and the control terminal 43. When monitoring data by operating the switch SW is input to the operation terminal 42, the monitoring data is transmitted to the transmission unit 41, and the transmission data is transmitted to the transmission unit 41. Is received, the control data corresponding to the monitoring data is transmitted to the control terminal 43 whose correspondence with the operation terminal 42 is set by the address, and the load L is controlled via the control terminal 43. Each of the transmission unit 41, the operation terminal device 42, and the control terminal device 43 mainly has a microprocessor.
[0003]
The transmission unit 41 transmits a transmission signal Vs having a format as shown in FIGS. 16A and 16B to the signal line Ls. That is, the transmission signal Vs includes a start pulse signal SY indicating the start of signal transmission, a mode data signal MD indicating a signal mode, and an address data signal AD transmitting address data for individually calling the operation terminal 42 and the control terminal 43. A control data signal CD for transmitting control data for controlling a load, a checksum data signal CS for detecting a transmission error, and a time slot for receiving a return signal from the operation terminal 42 or the control terminal 43. This is a multipole (± 24 V) time division multiplexed signal including a signal return period WT, and data is transmitted by pulse width modulation.
[0004]
In each operation terminal device 42 and each control terminal device 43, when the address data of the transmission signal Vs received via the signal line Ls matches the address data set respectively, the control data is taken in from the transmission signal Vs, In synchronization with the signal return period WT of the transmission signal Vs, 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).
[0005]
In addition, the transmission unit 41 is provided with a constant polling unit that constantly changes the address data included in the transmission signal Vs cyclically and performs continuous polling for sequentially accessing the operation terminal 42 and the control terminal 43. During the constant polling, the operation terminal 42 or the control terminal 43 whose address data contained in the transmission signal Vs matches the control data contained in the transmission signal Vs. On the other hand, after the transmission unit 41 detects the operation terminal 42 that has generated the interrupt signal when receiving the interrupt signal Vi as shown in FIG. 16C generated from any of the operation terminals 42, Interrupt polling means for accessing the operation terminal 42 and returning the monitoring data is also provided.
[0006]
That is, in the transmission unit 41, the transmission signal Vs in which the address data is cyclically changed by the polling means is always transmitted to the signal line Ls, and the interrupt signal Vi generated from the operation terminal 42 is transmitted to the transmission signal Vs. Upon detection in synchronization with the start pulse signal SY, the transmission unit 41 sends out the transmission signal Vs in which the mode data signal MD is set to the interrupt polling mode by the interrupt polling means. When the upper bits of the address data of the transmission signal Vs in the interrupt polling mode match, the operation terminal 42 that has generated the interruption signal Vi synchronizes with the signal return period WT of the transmission signal Vs. The lower bits of the address data set in 42 are returned as return data. In this way, the transmission unit 41 obtains the address of the operation terminal 42 that has generated the interrupt signal Vi, and accesses the operation terminal 42 using the obtained address, whereby the switch connected to the operation terminal 42 is obtained. Operation data corresponding to the operation state of the SW is received as return data. If the lower address is not returned from the operation terminal 42 that generated the interrupt signal Vi, the interrupt polling means in the transmission unit 41 changes the upper address and retransmits the transmission signal Vs in the interrupt polling mode.
[0007]
Thus, when the transmission unit 41 obtains the address of the operation terminal 42 that has generated the interrupt signal Vi, the transmission unit 41 sends the transmission signal Vs requesting the operation terminal 42 to return the monitoring data. The operation terminal 42 returns the monitoring data corresponding to the operation of the switch SW to the transmission unit 41. The transmission unit 41 that has received the monitoring data generates control data for the control terminal 43 preliminarily associated with the operation terminal 42 according to the address correspondence, and transmits the transmission signal Vs including this control data to the signal line Ls. The load L is transmitted and controlled through the control terminal 43. Here, the addresses of the operation terminal device 42 and the control terminal device 43 are composed of a channel set for each terminal device and a load number for identifying the circuit of the switch SW and the load L. In the current product, the channel is 64 channels and load numbers can be set for each channel by four circuits. That is, a channel is set in each operation terminal 42 and each control terminal 43, and up to four switches SW can be connected to each operation terminal 42, and up to four switches SW can be connected to each control terminal 43. Load L can be connected. Therefore, the load L of a total of 256 circuits can be controlled. Here, the circuit of the switch SW and the load L means a set of the switch SW and the load L related by an address correspondence, and the load L controlled according to the operation of the switch SW is one. Constitute one circuit.
[0008]
The correspondence between the switch SW and the load L as described above is set in a relation data storage unit provided in the memory of the transmission unit 41. That is, at the time of construction, after the address setting for each operation terminal device 42 and each control terminal device 43 is completed, the correspondence between the switch SW and the load L is set in the relation data storage unit, so that the operation of the switch SW is performed. , A desired load L can be controlled. Here, the correspondence between the switch SW and the load L in the individual control is made to correspond to the same address, and if the address is set in the operation terminal 42 and the control terminal 43, the correspondence between the switch SW and the load L Is set automatically. However, the operation terminal 42 and the control terminal 43 are distinguished by the data of the terminal type.
[0009]
Incidentally, some control terminals 43 incorporate the above-described relay Ry (see FIG. 19). Such a control terminal 43 has, for example, the appearance shown in FIG. Some are designed to do so. The illustrated body 10 has four built-in relays Ry respectively corresponding to four load numbers, so that four circuits of the load L can be individually turned on and off. That is, as shown in the figure, the housing 10 is provided with a signal terminal T1 for connecting the signal line Ls, a power terminal T2a for connecting a commercial power supply, and a feed terminal T2b directly connected to the power terminal T2a. Four load terminals T3 are provided for connecting a load connection load line (using a VVF cable) Ld. Contacts of the respective relays Ry are inserted between the power terminal T2a and the feed terminal T2b and the respective load terminals T3. FIG. 18 shows an actual connection example. In FIG. 18, the signal line Ls is shown by a broken line to show a state where the signal line Ls is not connected to the signal terminal T1. A power supply line Lp for supplying commercial power AC is connected to the power supply terminal 2a, and an illumination load as a load L is connected to each load terminal 3 via a load line Ld.
[0010]
The control terminal 43 has a configuration shown in FIG. 19, and includes a transmission / reception circuit 21 that converts a transmission signal Vs of ± 24 V into a TTL level signal at a signal terminal T1 and inputs the signal to the control circuit 20. . The transmission / reception circuit 21 also has a function of converting the TTL level monitoring data output from the control circuit 20 in synchronization with the signal return period WT into a current mode signal to generate a return signal. The transmission signal Vs input to the transmission / reception circuit 21 is also passed to the power supply circuit 22, and the power supply circuit 22 generates an internal power supply by smoothing the transmission signal Ls. The transmission / reception circuit 21 includes a diode bridge for making the connection to the signal line Ls non-polar. The transmission signal Ls is full-wave rectified by the diode bridge and input to the power supply circuit 22. Therefore, a DC voltage of 24 V is input to the power supply circuit 22. The control circuit 20 includes a microcomputer (hereinafter, referred to as a “microcomputer”), and operates the relay Ry via the relay drive circuit 23 according to the content of the control data DT included in the transmission signal Vs when the transmission signal Vs is input. The monitoring data is output in synchronization with the signal return period WT of the transmission signal Vs. The control circuit 20 further includes an address setting unit 11 for setting an address, a key input circuit 12 including various switches described below, and a display circuit 13 including a display indicating an operation state of the relay Ry. You. Here, a light emitting diode is used as a display. Although not shown, four relays Ry are provided, and the contacts of each relay Ry are individually turned on and off. The address setting unit 11 is configured by using two rotary switches 11a and 11b (see FIG. 17), and each rotary switch is provided with an upper digit (10's digit) and a lower digit (1's digit) of a 2-digit channel. Corresponding. Regarding the load number, 1 to 4 are assigned to each relay Ry, and as a result, an address is individually associated with each relay Ry.
[0011]
The control terminal 43 shown in FIG. 17 includes an on-switch SWa and an off-switch SWb, each of which is a push button switch, and a load state confirmation switch SWc, which is a push button switch, for confirming the connection state or the operation of the load L at the time of construction. Is provided in the key input circuit 12. When the load state confirmation switch SWc is pressed, the mode shifts to a mode in which the connection state of the load L is confirmed. In this mode, when the on switch SWa is pressed, the four circuit relays Ry are turned on collectively. By pressing the off switch SWb, the relays Ry of the four circuits can be turned off collectively. That is, if the load L is turned on and off by operating the on switch SWa and the off switch SWb, it is possible to confirm whether the load L is abnormal. Further, the above-described display circuit 13 includes four confirmation lights PL1 to PL4 that are turned on when the relay Ry is operated by operating the on switch SWa, and an operation that is turned on when the on switch SWa and the off switch SWb are operated. Indicator lights PLa and PLb are provided.
[0012]
[Problems to be solved by the invention]
In the above-described configuration, since the power for operating the internal circuit of the control terminal 43 is supplied by the power supply circuit 22 for smoothing the transmission signal Vs, the signal line Ls is not provided at the time of construction because the signal line Ls is not attached. However, there is a problem that the relay Ry cannot be operated even if the on switches SWa and SWb are operated in order to confirm the connection state of the load L or the operation of the load in a state where the connection with the load L is not completed. In particular, in this type of remote monitoring and control system, the transmission unit 41 is often housed in a panel, and the panel is often not installed when the control terminal 43 is installed. The connection state and operation of the load L cannot be confirmed. In addition, when an abnormality such as disconnection of the load line Ld occurs while the transmission signal Vs is normally transmitted, and when an abnormality occurs such as the disconnection of the signal line Ls while the load L is normal. In either case, the load L does not operate when the on switch SWa or the off switch SWb is pressed, so it is necessary to identify which of the transmission system of the transmission signal Lv and the load L has an abnormality. Is something that cannot be done.
[0013]
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 capable of confirming the connection state and operation of a load even when not connected to a signal line. Terminal equipment is provided.
[0014]
[Means for Solving the Problems]
The invention according to claim 1, wherein a plurality of terminals each having an address are connected to a signal line, and a transmission signal is transmitted between the transmission unit connected to the signal line and each of the terminals by a time division multiplex transmission method. A terminal used in a remote monitoring control system for controlling a load by another terminal in response to the operation of a switch connected to one of the terminals using relation data in which a correspondence relation between addresses is set in a transmission unit. A load terminal for connecting a load, a power terminal for connecting a commercial power supply for supplying power to the load, a relay having a contact inserted between the load terminal and the power terminal to turn on and off the load, And a power supply circuit for supplying at least power necessary for driving the relay using a commercial power supply connected to the power supply terminal as an input power supply.
[0015]
According to the invention of claim 2, a plurality of terminals each having an address are connected to a signal line, and a transmission signal is transmitted between the transmission unit connected to the signal line and each of the terminals by a time division multiplex transmission system. A terminal used in a remote monitoring control system for controlling a load by another terminal in response to the operation of a switch connected to one of the terminals using relation data in which a correspondence relation between addresses is set in a transmission unit. A relay that turns the load on and off, a test power supply terminal that temporarily connects an external power supply for operation confirmation, and an external power supply connected to the test power supply terminal as an input power supply that is required to drive at least the relay. Power supply circuit that supplies an appropriate power supply, and a control circuit that turns on and off the relay in a specified procedure when it detects that an external power supply is connected to the inspection power supply terminal. It is characterized in.
[0016]
According to a third aspect of the present invention, a plurality of terminals each having an address are connected to a signal line, and a transmission signal is transmitted between the transmission unit connected to the signal line and each of the terminals by a time division multiplex transmission system. A terminal used in a remote monitoring control system for controlling a load by another terminal in response to the operation of a switch connected to one of the terminals using relation data in which a correspondence relation between addresses is set in a transmission unit. A relay for turning on and off a load, a signal terminal for connecting a signal line, a power supply circuit for making a voltage applied to the signal terminal constant, and an external power supply different from the transmission signal connected to the signal terminal. And a control circuit for turning on and off the relay in a prescribed procedure when detecting that the relay has been performed.
[0017]
According to a fourth aspect of the present invention, a plurality of terminals each having an address are connected to a signal line, and a transmission signal is transmitted between the transmission unit connected to the signal line and each of the terminals by a time division multiplex transmission system. A terminal used in a remote monitoring control system for controlling a load by another terminal in response to the operation of a switch connected to one of the terminals using relation data in which a correspondence relation between addresses is set in a transmission unit. A load terminal for connecting a load, a power terminal for connecting a commercial power supply for supplying power to the load, a relay having a contact inserted between the load terminal and the power terminal to turn on and off the load, And a manually operated inspection switch connected in parallel to the contact of the relay.
[0018]
The invention according to claim 5, wherein a plurality of terminals each having an address are connected to a signal line, and a transmission signal is transmitted between the transmission unit connected to the signal line and each of the terminals by a time division multiplex transmission system. A terminal used in a remote monitoring control system for controlling a load by another terminal in response to the operation of a switch connected to one of the terminals using relation data in which a correspondence relation between addresses is set in a transmission unit. A load terminal for connecting a load, a power terminal for connecting a commercial power supply for supplying power to the load, a relay having a contact inserted between the load terminal and the power terminal to turn on and off the load, A semiconductor switch connected in parallel to the relay contacts, and a semiconductor switch turned on at least during a specified start period from when the load is turned on and an end period from before the load is turned off until it is turned off Between the start period and the end period is characterized by having a control circuit for turning on the contacts of the relay.
[0019]
The invention according to claim 6 is the invention according to claim 5, wherein the load terminal and the power supply terminal each include two terminals for one circuit, and the relay is provided between corresponding terminals of the load terminal and the power supply terminal. The semiconductor switch is provided with two contacts inserted respectively, and the semiconductor switch is connected in parallel to at least one of the contacts.
[0020]
The invention according to claim 7, wherein a plurality of terminals each having an address are connected to a signal line, and a transmission signal is transmitted between the transmission unit connected to the signal line and each of the terminals by a time division multiplex transmission method. A terminal used in a remote monitoring control system for controlling a load by another terminal in response to the operation of a switch connected to one of the terminals using relation data in which a correspondence relation between addresses is set in a transmission unit. An address setting unit using a mechanical switch and capable of manually setting an address, and a setting indicator for displaying an address set by the address setting unit and capable of emitting light by itself. Features.
[0021]
The invention according to claim 8, wherein a plurality of terminals each having an address are connected to a signal line, and a transmission signal is transmitted between the transmission unit connected to the signal line and each of the terminals by a time division multiplex transmission system. A terminal used in a remote monitoring control system for controlling a load by another terminal in response to the operation of a switch connected to one of the terminals using relation data in which a correspondence relation between addresses is set in a transmission unit. A load terminal for connecting a load, a power terminal for connecting a commercial power supply for supplying power to the load, a relay having a contact inserted between the load terminal and the power terminal to turn on and off the load, A load capacitance sensor for detecting a current passing through an electric circuit between the load terminal and the power supply terminal, and a capacitor for notifying when a current detected by the load capacitance sensor exceeds a specified threshold value Characterized in that it comprises an alarm device.
[0022]
BEST MODE FOR CARRYING OUT THE INVENTION
(Embodiment 1)
The appearance of the control terminal according to the present embodiment is the same as the conventional configuration shown in FIG. 17 and includes a body having a shape suitable for being arranged in the internal space of the ceiling. The structure arranged in the interior space of the ceiling will be described later in a second embodiment. In this embodiment, the power supply circuit 22 is not connected to the transmission / reception circuit 21 shown in FIG. 19, but is connected to the power supply terminal T2a as shown in FIG. Since a commercial power supply is connected to the power supply terminal T2a, the power supply circuit 22 is configured to generate an internal power supply from the commercial power supply, and the step-down ratio becomes larger as compared with the conventional configuration. Therefore, a power transformer for stepping down or a switching power supply is used for the power supply circuit 22.
[0023]
Since the power is supplied from the commercial power supply to the internal circuit by adopting the above configuration, the transmission signal is transmitted to the control terminal 43 due to disconnection of the signal line Ls, disconnection of the signal line Ls, failure of the transmission unit 41, and the like. Even when Vs is not input, if a commercial power supply is connected, the load L is controlled by operating the on switch SWa, the off switch SWb, and the load state confirmation switch SWc (see FIG. 17) provided in the key input circuit 12. Can be turned on and off, and the connection state between the control terminal 43 and the load L and the operation of the load L can be confirmed. Other configurations and operations are the same as those of the conventional configuration. In the present embodiment, the power supply to the load L is a commercial power supply. However, the same configuration can be adopted when power is supplied to the load L from another power supply.
[0024]
(Embodiment 2)
In this embodiment, as shown in FIG. 2, not only the transmission signal Vs input through the transmission / reception circuit 21 but also an external power supply can be used as the input power supply of the power supply circuit 22 having the conventional configuration shown in FIG. is there. For example, a 9 V battery B is used as an external power supply, and the control terminal 43 of this embodiment is provided with an inspection power supply terminal T4 for connecting the battery B. If a 9 V stacked dry battery is used as the battery B, the two electrodes are provided on the same surface, so that connection to the inspection power supply terminal T4 arranged side by side on one surface of the housing 10 as described later becomes easy.
[0025]
By the way, the power supply circuit 22 applies a voltage of 5 V to the control circuit 20 when the transmission signal Vs is used as an input power supply, and applies a voltage of 24 V to the relay drive circuit 23 to drive the relay Ry. ing. Now, it is assumed that a relay Ry that operates in a voltage range of 12 to 24 V applied to the relay drive circuit 23 is used. Here, since the voltage of the battery B used for the external power supply is 9 V, if the external power supply is used as it is, the voltage for operating the relay Ry cannot be secured even if the voltage applied to the control circuit 20 can be secured. Therefore, a DC-DC converter 24 for increasing the voltage of the external power supply connected to the inspection power supply terminal T4 is added. In the present embodiment, the output voltage of the DC-DC converter 24 is set to 16V, and the input voltage of the power supply circuit 22 when an external power supply is connected is set to 16V.
[0026]
Diodes D1 and D2 are inserted between the transmission / reception circuit 21 and the DC-DC converter 24 and the power supply circuit 22, respectively. The cathodes of the diodes D1 and D2 are connected to the input terminals of the power supply circuit 22. Therefore, while the transmission signal Vs is input to the signal terminal T1 and the DC voltage of 24 V is applied to the power supply circuit 22 from the transmission / reception circuit 21, the diode D2 conducts even when the battery B is connected to the inspection power supply terminal T4. Instead, a voltage of 24 V is applied to the power supply circuit 22. When the transmission signal Vs is not input to the signal terminal T1, the diode D1 is not conducting. When the battery B is connected to the test power supply terminal T4, the diode D2 conducts and a voltage of 16 V is applied to the power supply circuit 22. Will be.
[0027]
In the present embodiment, when the battery B is connected to the inspection power supply terminal T4, a function is also provided for automatically turning on and off the relay Ry in a prescribed procedure unless the transmission signal Vs is input to the signal terminal T1. . That is, the control circuit 20 has a function of determining a condition that the battery B is connected to the inspection power supply terminal T4 and a condition that the transmission signal Vs is not input to the signal terminal T1. Then, the relay drive circuit 23 is controlled so that the relays Ry are turned on and off in a predetermined order. Whether or not the battery B is connected to the inspection power supply terminal T4 is determined by the connection detection circuit 25 connected to the output terminal of the DC-DC converter 24.
[0028]
The connection detection circuit 25 includes two series-connected resistors R1 and R2 for dividing the output voltage of the DC-DC converter 24, and the base and the emitter of the transistor Q are connected between both ends of the resistor R2. The collector of the transistor Q is connected to a power supply terminal to which power is supplied from the power supply circuit 22 in the control circuit 20 via a resistor R3. Therefore, when the battery B is connected to the inspection power supply terminal T4, the transistor Q is turned on by the output voltage from the DC-DC converter 24, and the collector of the transistor Q goes to L level. When the battery B is not connected to the inspection power supply terminal T4, the collector of the transistor Q is at the H level. The control circuit 20 is connected to the collector of the transistor Q, whereby the control circuit 20 determines whether the battery B is connected to the inspection power supply terminal T4.
[0029]
Further, since the transmission signal Vs is input to the control circuit 20 from the transmission / reception circuit 21 at the TTL level, the presence / absence of the transmission signal Vs can also be determined by the control circuit 20. Therefore, when the collector of the transistor Q becomes L level, the control circuit 20 determines whether or not the output of the transmission / reception circuit 21 has a constant value for a period of one second from that point. When this condition is satisfied, the battery B is connected. It is determined that the transmission signal Vs is not input and the relay Ry is turned on and off in the order shown in FIG. That is, all the four relays Ry are turned on, then the relays Ry are selectively turned on one by one, and after all the relays Ry are turned on one by one, all the relays Ry are turned on again. Is repeated in a short cycle. Note that the control circuit 20 sets the time for judging whether the output of the transmission / reception circuit 21 is a constant value to be 1 second in the current product because the generation cycle of the transmission signal Vs is about 15 ms and the output of the transmission / reception circuit 21 For one second is considered sufficient to determine the presence or absence of the transmission signal Vs.
[0030]
With the above-described configuration, as in the first embodiment, even when the signal line Ls is not connected, if a commercial power supply is connected to the power supply terminal T2a, the load L can be obtained simply by connecting the battery B to the test power supply terminal T4. It is possible to check the connection state and operation of the device. Further, the operation of the relay Ry can be checked even when the commercial power supply is not connected. Here, since the battery B is not used while the battery B is used as the power source of the relay Ry at the time of operation confirmation, there is no liquid leakage due to the battery B being left as it is. In addition, since the state where the battery B is connected to the inspection power supply terminal T4 and not connected to the signal line Ls is automatically determined and the relay Ry is turned on / off, the operation for checking the connection state and operation of the load L is started. No operation is required.
[0031]
By the way, the body 10 of the control terminal device shown in this embodiment has a rectangular parallelepiped shape as shown in FIG. 4, and a ceiling material is connected to a ceiling structural material in the ceiling to be arranged in the interior space of the ceiling. And a pair of upper and lower mounting pieces 14 connected to the hanging bolts. The ceiling structural material generally means a concrete ceiling, and the ceiling material means a so-called system ceiling having a structure in which a ceiling panel is mounted on a framed ceiling edge. This type of system ceiling adopts a configuration in which a ceiling edge is hung at a lower end of a suspension bolt having an upper end fixed to a ceiling structural material. Therefore, the body 10 can be fixed to the interior space of the ceiling (the space between the ceiling structural material and the ceiling material) by connecting the body 10 to the hanging bolts. In fixing the body 10 to the suspension bolts, a clamping plate (not shown) that clamps the suspension bolt with the mounting piece 14 is used, and a screw (not illustrated) that is screwed into the clamping plate through the mounting piece 14. Is tightened.
[0032]
The inspection power supply terminal T4 is exposed at the lower part of the front surface of the container 10, and the above-described operation is performed only by pressing the battery B against the inspection power supply terminal T4. In addition, the front surface of the housing 10 covers the rotary switches 11a and 11b, the on switch SWa, the off switch SWb, the load state confirmation switch SWc, the operation indicator lights PLa and PLb, the confirmation lights PL1 to PL4, and the signal terminal T1. Door plate 15 is provided. One side edge of the door plate 15 is pivotally attached to the container 10. Here, the signal terminal T1 includes one set of threaded terminals and two sets of quick connection terminals. As is well known, the quick connection terminal electrically and mechanically holds an electric wire introduced from an electric wire insertion opening opened on the side surface of the body 10 by a lock spring formed by a leaf spring.
[0033]
In this embodiment, the battery B is used as the external power supply connected to the inspection power supply terminal T4. However, any battery that outputs the same DC voltage as the battery B can be used as the external power supply. As can be seen from a comparison between FIG. 19 and FIG. 4, the external configuration of this embodiment is the same as that of the first embodiment except that an inspection power supply terminal T4 is provided on the body 10. The configuration and function of the internal circuit are the same as those of the first embodiment except for the points described above.
[0034]
(Embodiment 3)
In the second embodiment, an inspection power supply terminal T4 for connecting a battery B as an external power supply is separately provided, whereas in the present embodiment, the load L is reduced by connecting an external power supply to the signal terminal T1. It is possible to confirm the connection state or the operation of. Therefore, as shown in FIG. 5, in the present embodiment, there is no inspection power supply terminal T4, and neither the DC-DC converter 24 nor the connection detection circuit 25 is provided.
[0035]
However, as described in the second embodiment, the terminal voltage of the battery as the external power supply is lower than the voltage obtained by full-wave rectifying the transmission signal Vs, and generally the voltage is insufficient to drive the relay Ry. However, simply connecting a battery to the signal terminal T1 cannot secure a voltage for driving the relay Ry. Therefore, in the present embodiment, the power supply circuit 22 is configured to be capable of boosting and stepping down, so that the output voltage is kept constant regardless of the input voltage. Specifically, when the transmission signal Vs is being input to the signal terminal T1, the voltage drops in the power supply circuit 22, and when the battery is connected to the signal terminal T1, the voltage increases in the power supply circuit 22. Further, in the present embodiment, similarly to the second embodiment, the control circuit 20 determines whether the transmission signal Vs is input to the signal terminal T1 or a battery is connected, and when the battery is connected, four relays are used. By automatically turning on and off Ry in order, the connection state or operation of the load L can be inspected.
[0036]
This will be described more specifically. The voltage applied to the signal terminal T1 and full-wave rectified by the transmission / reception circuit 21 is input to the power supply circuit 22 as in the above-described embodiments. The power supply to the control circuit 20 in the power supply circuit 22 may be ensured by the step-down by the series regulator as in the above-described embodiments. However, the circuit configuration for obtaining the power supply to the relay drive circuit 23 requires at least a voltage lower than the input voltage. , The output voltage of which is variable within a range from the input voltage to the input voltage. Various types of circuit configurations of this type have been proposed. For example, the input voltage is boosted by a polarity inversion type chopper circuit, a flyback type converter circuit, or a boost chopper circuit, and then the output voltage of the boost chopper circuit is reduced by a buck chopper circuit. A step-up / step-down chopper circuit can be used. In the power supply circuit 22 of the present embodiment, 5 V is supplied to the control circuit 20 and 16 V is supplied to the relay drive circuit 23 regardless of the input voltage. Here, by appropriately designing the power supply circuit 22, even an external power supply (battery) having a terminal voltage of 3V can be used as an external power supply (battery) connected to the signal terminal T1.
[0037]
In the control circuit 20, whether or not the transmission signal Vs is input to the signal terminal T1 can be recognized by monitoring the TTL level signal from the transmission / reception circuit 21, as in the second embodiment. On the other hand, whether or not a battery is connected to the signal terminal T1 is monitored by the output voltage of the power supply circuit 22. That is, in FIG. 5, one of two lines connecting the power supply circuit 22 and the control circuit 20 indicates a line for supplying power to the control circuit 20, and the other one of the two lines connects the power supply circuit 22 and the control circuit 20. The line for the control circuit 20 to monitor whether the input voltage to the relay drive circuit 23 is more than required voltage is shown. That is, the power supply circuit 22 outputs a determination signal that becomes H level when the input voltage to the relay drive circuit 23 is 10 V or more (L level when the input voltage is less than 10 V), and inputs this determination signal to the control circuit 20. I have. Such a determination signal can be easily generated by comparing the voltages with a comparator. Here, the threshold for generating the determination signal is set to 10 V because the input voltage to the power supply circuit 22 when the transmission signal Vs is input to the signal terminal T1 is 24 V, and the battery is connected to the signal terminal T1. Is assumed to be an input voltage lower than 10 V (for example, 3 V, 9 V, etc.) when the power supply is connected. If the voltage of the battery as the external power supply is different, the threshold value is appropriately adjusted. I do.
[0038]
However, in the control circuit 20, when the transmission signal Vs is input to the signal terminal T1, the output voltage of the transmission / reception circuit 21 changes over time and the determination signal from the power supply circuit 22 becomes H level. A normal operation based on the content of the signal Vs is performed. On the other hand, if the input voltage to the power supply circuit 22 is less than 10 V, the determination signal goes to the L level. Therefore, the control circuit 20 determines that the voltage input from the transmission / reception circuit 21 is not 0 V and is constant for one second. If it does not change, it is determined that a battery is connected to the signal terminal T1, and the four relays Ry are sequentially turned on and off via the relay drive circuit 23 as in the second embodiment. That is, when a battery is connected to the signal terminal T1, the relays Ry are automatically turned on and off automatically in order, and the connection state or operation of the load L can be checked.
[0039]
The other configuration of the present embodiment is the same as that of the first or second embodiment. Even if the signal line Ls is not connected, if a commercial power supply is connected to the power supply terminal T2a, a battery is connected to the signal terminal T1. The connection state and operation of the load L can be checked simply by connecting. Further, the operation of the relay Ry can be checked even when the commercial power supply is not connected. In addition, since a battery is used as a power source of the relay Ry at the time of operation confirmation and the battery is not built in, the liquid does not leak when the battery is left with the built-in battery left. In addition, since the state where the battery is connected to the signal terminal T1 is automatically determined and the relay Ry is turned on / off, an operation for starting the operation for checking the connection state and operation of the load L is not required. Moreover, unlike the second embodiment, there is no need to separately provide the inspection power supply terminal T4.
[0040]
(Embodiment 4)
In the present embodiment, as shown in FIG. 6, the inspection switches SW1 to SW4 that are manually operated are connected to the respective contacts r1 to r4 of the four relays Ry provided between the power supply terminal T2a and the respective load terminals T3. Are connected in parallel. That is, a parallel circuit of the contacts r1 to r4 and the inspection switches SW1 to SW4 is inserted between the power supply terminal T2a and each load terminal T3. In the illustrated example, each of the power supply terminal T2a, the feed terminal T2b, and the load terminal T3 is composed of three terminals. The upper two terminals in the figure are for power supply, and the lower one is for grounding. The operation units of the inspection switches SW1 to SW4 are arranged near the load terminals T3 on the front surface of the housing 10, as shown in FIG. That is, when the connection state or operation of the load L connected to each load terminal T3 is to be checked, the inspection switches SW1 to SW4 may be manually operated with the commercial power supply connected to the power supply terminal T2. It is possible to check the connection state of the load L to the load terminal T3 or the operation of the load L without operating Ry. That is, the connection state and operation of the load L can be checked without connecting to the signal line Ls. Further, even when the commercial power supply is not connected to the power supply terminal T2a, the continuity test is possible, so that the connection state can be confirmed. In addition, a push button switch or a slide switch can be used as the inspection switches SW1 to SW4.
[0041]
In the configuration of the present embodiment, it is possible to check the connection state of the load L to the load terminal T3 regardless of the operation of the internal circuit. In the test of the connection state, for example, a continuity tester may be connected to the power supply terminal T2a, and the inspection switches SW1 to SW4 may be appropriately turned on and off. Other configurations and functions are the same as the conventional configuration.
[0042]
(Embodiment 5)
As described in each of the above embodiments, the control terminal 43 disposed in the interior space of the ceiling uses the relay Ry to control the on / off of the load L. Since the current product uses an electromagnetic relay having a mechanical contact having a rated current of 6 A as the relay Ry, an arc is generated when the contact of the relay Ry is turned off. That is, if a mechanical contact is used, the occurrence of an arc causes the contact to be worn. Therefore, the number of times that the contact can be operated normally is relatively small. As a result, the life of the control terminal 43 is determined by the life of the relay Ry. ing. In addition, when using a relay Ry having mechanical contacts, when a load L that generates an inrush current that greatly exceeds the rated current of the contacts is connected, problems such as welding of the contacts occur. In the case where the loads L are turned on and off collectively, even if the total rated current of the plurality of loads L is lower than the rated current of the contacts, the number of loads L should be controlled by one contact. Cannot be done. An inverter-type lighting fixture or the like is known as a load L in which such an inrush current is generated. There is a problem in that the number of lamps of the lighting fixture per circuit must be limited, and the connection-related design is troublesome.
[0043]
In order to solve this kind of problem, in the present embodiment, as shown in FIG. 8, a triac Q3 as a semiconductor switch is connected in parallel to a contact r of the relay Ry, and a connection between the contact r of the relay Ry and the triac Q3 is made. A configuration in which the ON / OFF timing is controlled by the control circuit 20 is employed. That is, the control circuit 20 controls on / off of the triac Q3 via the triac drive circuit 26 in addition to controlling on / off of the relay Ry via the relay drive circuit 23. The relay drive circuit 23 applies the output voltage of the power supply circuit 22 to a series circuit in which a transistor Q1 (collector-emitter thereof) as a switching element is connected in series to the coil Rc of the relay Ry, and the transistor Q1 is instructed by the control circuit 20. Is turned on and off to turn on and off the contact r.
[0044]
On the other hand, the triac drive circuit 26 applies the output voltage of the power supply circuit 22 to a series circuit in which a light emitting element (light emitting diode) PE of the photocoupler PC and a transistor Q2 (collector-emitter thereof) as a switching element are connected in series. The light emitting element PE is turned on and off by turning on and off the transistor Q2 in accordance with an instruction from the circuit 20, and a voltage is applied to the gate of the triac Q3 through a light receiving element (phototriac) PR optically coupled to the light emitting element PE. ing. That is, the light receiving element PR forms a series circuit with the resistors R4 and R5 in a form inserted between the two resistors R4 and R5, and this series circuit is inserted between the power supply terminal T2a and the load terminal T3. is there. The gate of the triac Q3 is connected to a connection point between the light receiving element PR and the resistor R5. When the light receiving element PR is turned on, a voltage is applied to the gate of the triac Q3 to turn on the triac Q3. Therefore, when the transistor Q2 is turned on according to an instruction from the control circuit 20, the light emitting element PE is turned on and the trigger voltage is applied to the gate of the triac Q3, so that the triac Q3 is turned on.
[0045]
As described above, the control circuit 20 controls both the on / off of the contact r of the relay Ry and the triac Q3, and controls the contact r of the relay Ry and the triac Q3 in the procedure shown in FIG. That is, when turning on the load L as shown in FIG. 9A, first, as shown in FIG. 9C, the triac Q3 is turned on only for a prescribed start period t1. As shown in FIG. 9B, the contact r of the relay Ry turns on the contact r of the relay Ry immediately before the end of the start period t1, and turns off the contact r of the relay Ry before turning off the load L. I do. Further, as shown in FIG. 9C, the triac Q3 is turned on during an end period t2 before the contact r of the relay Ry is turned off and before the load L is turned off. Therefore, for example, when the transmission signal Vs turns on, the contact r of the relay Ry is turned on while the triac Q3 is turned on for only the start period t1, and when the transmission signal Vs turns off, the triac Q3 is turned on. Is turned on again only for the end period t2, and the contact r of the relay Ry is turned off during the end period t2. In this operation, there is a delay of the end period t2 from the OFF instruction by the transmission signal Vs to the turning off of the load L. However, the end period t2 only needs to be long enough to prevent the arc of the contact r from being generated. This is a very short time and does not cause any discomfort due to this delay. Further, the triac Q3 is turned on only for a short time between the start period t1 and the end period t2, and the triac Q3 is not normally energized. Therefore, the amount of heat generated is small and power loss can be suppressed.
[0046]
By the above-described operation, even if the load L that generates an inrush current immediately after the power is turned on is connected to the load terminal T3, the inrush current flows through the triac Q3, so that the contact r of the relay Ry is welded by the inrush current. Does not occur. As a result, the rated current of the load L connected to the load terminal T3 can be matched with the rated current of the contact r, and the connection design becomes easier. Here, since the triac Q3 has an on-resistance, an effect of reducing the inrush current when the load L is on can be expected. Further, since the load L is turned off by turning off the triac Q3 after turning off the contact r, no arc is generated at the contact r and the contact life is extended.
[0047]
By the way, in the above-described configuration, the power supply terminal T2a and the load terminal T3 have a so-called one-sided cutout in which only one contact r is inserted. However, when the commercial power supply connected to the power supply terminal T2a is 200 V, for example, In this case, as shown in FIG. 10, a so-called double-sided cut-off method is used in which contacts ra and rb are inserted between the power supply terminal T2a and the load terminal T3 between the power supply terminal T2a and the load terminal T3. desirable. In this case, two relays Rya and Ryb are provided per circuit, and the contacts ra and rb of each relay Rya and Ryb are individually turned on and off. In the present embodiment, a configuration is adopted in which the triac Q3 is connected in parallel to one contact rb, but the triac Q3 is not connected to the other contact ra. Transistors Q1a and Q1b are connected in series to coils Rca and Rcb of relays Rya and Ryb, respectively, and control circuit 20 turns on and off contacts ra and rb individually by turning on and off transistors Q1a and Q1b individually.
[0048]
In the configuration shown in FIG. 10, the triac Q3 is turned on with the contact ra not connected in parallel with the triac Q3 turned on, and then the contact rb is turned on. In this operation, no rush current flows through the contact rb, as in the case of the above-described one-side cut. A current flows through the contact ra through the triac Q3, but the inrush current is reduced by the on-resistance of the triac Q3. On the other hand, when the load L is turned off, if the contact rb is turned off while the triac Q3 is turned on, and then the contact ra is turned off, no arc is generated at both the contacts ra and rb. Other configurations and operations are the same as those shown in FIG.
[0049]
Other configurations and operations are the same as those of the conventional configuration. Note that the configuration of the present embodiment can be used together with the configurations of the first to fourth embodiments.
[0050]
(Embodiment 6)
In each of the embodiments described above, two rotary switches 11a and 11b for setting channels are used as the address setting unit 11 of the control terminal 43. On the other hand, since the control terminal 43 is installed in a relatively dark interior space of the ceiling, it is difficult to read the set values by the rotary switches 11a and 11b, and the possibility of erroneous setting increases. When the rotary switches 11a and 11b are used, the knob may stop between two adjacent values among the values associated with the rotary switches 11a and 11b. ) May be incorrectly set. If the address is incorrectly set, the device cannot be operated normally. Therefore, the address must be reset after construction, and in consideration of the fact that the control terminal 43 is installed in the internal space of the ceiling, the work of resetting is performed. Would be very time-consuming.
[0051]
Therefore, in the present embodiment, as shown in FIGS. 11 and 12, a setting display 16 for displaying the address set by the address setting unit 11 is provided. The setting display 16 shown includes a segment type liquid crystal display, a backlight, and a driving circuit of the liquid crystal display. The setting display 16 is provided at the lower portion of the front of the body 10 so that the channel can be displayed by a two-digit numerical value. Further, since the setting display 16 is provided with a backlight so as to be able to emit light by itself, the display contents can be easily recognized even in darkness. That is, even when the surroundings are dark at the time of construction, the channel set by the rotary switches 11a and 11b can be easily recognized, so that the possibility of erroneous setting is reduced. The use of the setting display 16 enables various error displays. For example, in the current product, channels 0 to 63 can be designated as channels, but if the 2-digit rotary switches 11a and 11b are used, it is possible to set channels 64 to 69 or 64 to 99. Since such a channel cannot be used, an error display may be displayed on the setting display 16 when an unusable channel is designated by the rotary switches 11a and 11b.
[0052]
In addition, as long as the setting display 16 can emit light by itself, a display other than a combination of a liquid crystal display and a backlight, such as a light emitting diode display and an organic EL display, can be adopted. Other configurations and operations are the same as those of the other embodiments, and the configuration of the present embodiment can be used in any of the configurations of the first to fifth embodiments.
[0053]
(Embodiment 7)
As described above, the control terminal 43 has the built-in relay Ry, and if the current flowing through the load L is larger than the current allowed to the contact of the relay Ry, the relay Ry may be broken. Generally, the commercial power supply connected to the power supply terminal T2a is supplied via a branch breaker in the distribution board, but the rated current of the contact of the relay Ry is usually smaller than the current value cut off by the branch breaker. Therefore, the above-mentioned problem cannot be solved by the branch breaker.
[0054]
The present embodiment is provided with a function of notifying when a load L exceeding an allowable current capacity is connected. As shown in FIG. 13, a function between the power supply terminal T2a and the load terminal T3 is provided. A load capacitance sensor 27 for detecting a current passing through the electric circuit is provided. It is assumed that the load capacity sensor 27 uses a current transformer. The current value detected by the load capacitance sensor 27 is input to the control circuit 20. The control circuit 20 determines a current value (threshold) predetermined according to the rated current of the contact point of the relay Ry and a current value detected by the load capacitance sensor 27. Are compared, and when the current value detected by the load capacity sensor 27 exceeds the threshold, the capacity notifying device 28 notifies that the load L is excessive. Here, the capacity notification device 28 is assumed to use a light emitting diode. Further, a load capacitance sensor 27 is provided for each load terminal T3, and as shown in FIG. 14, a capacitance notification device 28 composed of a light emitting diode is arranged near each load terminal T3. It should be noted that a notification by a buzzer sound may be added as the capacity notification device 28.
[0055]
By adopting the configuration of the present embodiment, when the current flowing through the load L is larger than the allowable current capacity, a notification is made by the capacity notifying device 28 so that the load L is used in a connected state. Is prevented, and a failure of the relay Ry can be prevented. In the present embodiment, the current cannot be detected by the load capacity sensor 27 unless the contact of the relay Ry is turned on. However, when the connection of the load L exceeding the allowable current capacity is detected, the capacity notification device 28 In addition to notifying the relay, the contact of the relay Ry is immediately turned off, so that an excessive current can be prevented from continuously flowing through the contact of the relay Ry. Other configurations and operations are the same as those of the other embodiments described above, and the configuration of the present embodiment can be used together with the configurations of the other embodiments.
[0056]
【The invention's effect】
According to the first aspect of the present invention, a power supply required to drive a relay for turning on and off the load is supplied from a power supply circuit having a commercial power supply connected to a power supply terminal connected to a power supply terminal connected to the power supply to the load. If a commercial power supply for supplying power is connected, there is an advantage that the construction state can be inspected by turning on / off the load without receiving a transmission signal from the signal line.
[0057]
According to a second aspect of the present invention, there is provided a relay for turning on and off a load from a power supply circuit having an external power supply connected to the test power supply terminal and having an input power supply, the test power supply terminal for temporarily connecting an external power supply for operation confirmation. In addition to supplying the power required for driving, the control circuit turns on and off the relay in a specified procedure when it detects that an external power supply has been connected to the inspection power supply terminal, so the load can be applied without receiving a transmission signal from the signal line. There is an advantage that the construction state can be inspected by turning it on and off. In driving the relay, an external power supply only needs to be connected, and it is not necessary to connect the power supply to the load. Therefore, if the power supply is connected to the load, it is possible to inspect the connection state of the load. Thus, it is possible to check the connection state of the load regardless of the voltage supplied to the load. Furthermore, even if a battery is used as an external power supply, it is only necessary to temporarily connect to the power supply terminal for inspection and there is no need to incorporate a battery. There is also the advantage that there is no possibility. In addition, since the connection state of the load can be inspected by simply connecting the external power supply to the inspection power supply terminal without performing any other operation, there is an advantage that it is not necessary to provide another component such as an inspection switch. .
[0058]
According to a third aspect of the present invention, there is provided a power supply circuit for converting a voltage applied to a signal terminal into a constant voltage, and a control circuit for controlling a relay for turning on and off a load when an external power supply different from the transmission signal is connected to the signal terminal. Since the power supply is turned on / off in a prescribed procedure, there is an advantage that the load can be turned on / off without receiving a transmission signal from the signal line and the construction state can be inspected. In driving the relay, an external power supply only needs to be connected, and it is not necessary to connect the power supply to the load. Therefore, if the power supply is connected to the load, it is possible to inspect the connection state of the load. Thus, it is possible to check the connection state of the load regardless of the voltage supplied to the load. Furthermore, even when a battery is used as an external power supply, it is only necessary to connect the battery to the signal terminal and there is no need to incorporate the battery. There is also the advantage that there is no. In addition, by simply connecting the external power supply to the signal terminal, the connection state of the load can be inspected without any other operation, so that there is no need to provide a separate component such as an inspection switch. In addition, there is no need to provide a dedicated terminal for connecting an external power supply.
[0059]
According to the fourth aspect of the present invention, since a manually operated inspection switch is connected in parallel to the contact of the relay for turning the load on and off, the electric circuit with the load can be opened and closed without securing a power supply for driving the relay. Can be. That is, there is an advantage that the connection state of the load can be inspected even when the transmission signal is not received from the signal line and the power supply to the load is not connected. Also, when inspecting the connection state of the load, it is only necessary to turn on and off the inspection switch, and it is not necessary to connect the power supply to the load. It is possible, and it is possible to check the connection state of the load regardless of the voltage supplied to the load.
[0060]
According to a fifth aspect of the present invention, a semiconductor switch is connected in parallel to a contact of a relay for turning on and off the load, and the semiconductor switch is turned on during a specified start period from turning on of the load and an end period from before turning off to off, and at least a start period and an end period are set. During the period, the relay contacts are turned on, so even when using a load in which inrush current flows immediately after energization, the inrush current is reduced by the semiconductor switch, and in the steady state, current flows through the relay contacts This can prevent a temperature rise due to heat generation of the semiconductor switch. As a result, even when using a load that generates an inrush current such as an inverter-type lighting fixture, the total of the rated currents of the loads connected to the load terminals is matched with the rated current of the contact without considering the inrush current. And connection design becomes easier. In addition, when the relay contact is turned off, the semiconductor switch is on, and no arc is generated at the relay contact and the wear of the contact is small. Can be expected to improve.
[0061]
According to a sixth aspect of the present invention, in the fifth aspect of the present invention, the relay includes two contacts inserted between corresponding terminals of the load terminal and the power supply terminal, and a semiconductor switch is connected in parallel to at least one of the contacts. Therefore, in addition to the effect of the invention of claim 5, since the contact of the relay is double-ended, it is possible to cope with a case where the voltage supplied to the load is a high voltage (for example, 200 V).
[0062]
According to a seventh aspect of the present invention, there is provided an address setting unit using a mechanical switch and capable of manually setting an address, and a setting indicator for displaying the address set by the address setting unit and capable of emitting light by itself. Therefore, the address set by the address setting unit can be confirmed even when the surroundings are dark, and the operation of the address setting unit is incomplete and the mechanical switch stops at a position other than the specified position However, it can be easily confirmed by the setting display.
[0063]
The invention according to claim 8 is a load capacity sensor for detecting a current passing through an electric circuit between a load terminal and a power supply terminal, and a capacity notification for notifying when a current detected by the load capacity sensor exceeds a prescribed threshold value. When the capacity of the load connected to the load terminal exceeds the capacity of the contact of the relay, the device is notified by the capacity notifying device, so that use exceeding the capacity of the contact can be prevented.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a first embodiment of the present invention.
FIG. 2 is a block diagram showing a second embodiment of the present invention.
FIG. 3 is an operation explanatory diagram of the above.
FIG. 4 is a front view showing the appearance of the above.
FIG. 5 is a block diagram showing a third embodiment of the present invention.
FIG. 6 is a main part circuit diagram showing a fourth embodiment of the present invention.
FIG. 7 is a front view showing the appearance of the above.
FIG. 8 is a block diagram showing a fifth embodiment of the present invention.
FIG. 9 is an operation explanatory view of the above.
FIG. 10 is a block diagram of another configuration example of the embodiment.
FIG. 11 is a block diagram showing a sixth embodiment of the present invention.
FIG. 12 is a front view showing the appearance of the above.
FIG. 13 is a block diagram showing Embodiment 7 of the present invention.
FIG. 14 is a front view showing the appearance of the above.
FIG. 15 is a schematic configuration diagram showing a remote monitoring control system.
FIG. 16 is an operation explanatory view of the above.
FIG. 17 is a front view showing the appearance of a conventional example.
FIG. 18 is a diagram showing an example of use of the above.
FIG. 19 is a block diagram of the above.
[Explanation of symbols]
11 Address setting section
11a, 11b Rotary switch
16 Display for setting
20 control circuit
22 Power supply circuit
27 Load capacity sensor
28 Capacity notification device
41 Transmission unit
42 Operation terminal
43 Control terminal
AC commercial power supply
B Battery (external power supply)
L load
Ld load line
Lp power line
Ls signal line
Q3 Triac (Semiconductor switch)
r contact
ra, rb contact
Ry relay
S switch
SW1-SW4 Inspection switch
T1 signal terminal
T2a power supply terminal
T3 Load terminal
T4 Inspection power supply terminal

Claims (8)

A plurality of terminals each having an address are connected to the signal line, and transmission signals are transmitted and received by a time division multiplex transmission method between the transmission unit connected to the signal line and each of the terminals, and in the transmission unit A terminal for use in a remote monitoring and control system in which a load is controlled by another terminal in accordance with an operation of a switch connected to one of the terminals using the relation data in which an address correspondence is set, and A load terminal to be connected; a power terminal to connect a commercial power supply for supplying power to the load; a relay having a contact inserted between the load terminal and the power terminal to turn on and off the load; and a commercial terminal to be connected to the power terminal. And a power supply circuit for supplying at least power necessary for driving the relay using the power supply as an input power supply. A plurality of terminals each having an address are connected to the signal line, and transmission signals are transmitted and received by a time division multiplex transmission method between the transmission unit connected to the signal line and each of the terminals, and in the transmission unit A terminal for use in a remote monitoring and control system in which a load is controlled by another terminal in accordance with an operation of a switch connected to one of the terminals using the relation data in which an address correspondence is set, and A relay that turns on and off, a test power supply terminal that temporarily connects an external power supply for operation confirmation, and a power supply circuit that supplies at least the power required to drive the relay with the external power supply connected to the test power supply terminal as the input power supply And a control circuit that turns on and off a relay in a prescribed procedure when detecting that an external power supply is connected to the inspection power supply terminal.隔監 viewed terminal unit of the control system. A plurality of terminals each having an address are connected to the signal line, and transmission signals are transmitted and received by a time division multiplex transmission method between the transmission unit connected to the signal line and each of the terminals, and in the transmission unit A terminal for use in a remote monitoring and control system in which a load is controlled by another terminal in accordance with an operation of a switch connected to one of the terminals using the relation data in which an address correspondence is set, and A relay that turns on and off, a signal terminal that connects a signal line, a power supply circuit that makes a voltage applied to the signal terminal constant, and a method that detects that an external power supply different from the transmission signal is connected to the signal terminal. And a control circuit for turning on and off the relay in accordance with the above procedure. A plurality of terminals each having an address are connected to the signal line, and transmission signals are transmitted and received by a time division multiplex transmission method between the transmission unit connected to the signal line and each of the terminals, and in the transmission unit A terminal for use in a remote monitoring and control system in which a load is controlled by another terminal in accordance with an operation of a switch connected to one of the terminals using the relation data in which an address correspondence is set, and A load terminal to be connected, a power supply terminal to connect a commercial power supply that supplies power to the load, a relay that has a contact inserted between the load terminal and the power supply terminal to turn the load on and off, and is connected in parallel to the relay contact. A terminal for a remote monitoring and control system, comprising: a manually operated inspection switch. A plurality of terminals each having an address are connected to the signal line, and transmission signals are transmitted and received by a time division multiplex transmission method between the transmission unit connected to the signal line and each of the terminals, and in the transmission unit A terminal for use in a remote monitoring and control system in which a load is controlled by another terminal in accordance with an operation of a switch connected to one of the terminals using the relation data in which an address correspondence is set, and A load terminal to be connected, a power supply terminal to connect a commercial power supply that supplies power to the load, a relay that has a contact inserted between the load terminal and the power supply terminal to turn the load on and off, and is connected in parallel to the relay contact. A semiconductor switch to turn on the semiconductor switch during a specified start period from when the load is turned on and an end period from before the load is turned off to at least a start period and an end period. Terminal unit of the remote monitoring control system while the characterized in that it comprises a control circuit for turning on the contact of the relay with. The load terminal and the power supply terminal each include two terminals for one circuit, and the relay includes two contacts that are respectively inserted between corresponding terminals of the load terminal and the power supply terminal. The terminal of claim 5, wherein the semiconductor switch is connected in parallel to a contact. A plurality of terminals each having an address are connected to the signal line, and transmission signals are transmitted and received by a time division multiplex transmission method between the transmission unit connected to the signal line and each of the terminals, and in the transmission unit A terminal for use in a remote monitoring and control system for controlling a load by another terminal in accordance with the operation of a switch connected to one of the terminals using the relation data in which an address correspondence is set, the terminal being a mechanical type A remote monitoring control system comprising: an address setting unit using a switch and capable of manually setting an address; and a setting display for displaying an address set by the address setting unit and capable of emitting light by itself. Terminal equipment. A plurality of terminals each having an address are connected to the signal line, and transmission signals are transmitted and received by a time division multiplex transmission method between the transmission unit connected to the signal line and each of the terminals, and in the transmission unit A terminal for use in a remote monitoring and control system in which a load is controlled by another terminal in accordance with an operation of a switch connected to one of the terminals using the relation data in which an address correspondence is set, and A load terminal to be connected, a power terminal to connect a commercial power supply for supplying power to the load, a relay having a contact inserted between the load terminal and the power terminal to turn on and off the load, and a load terminal and a power terminal. A load capacity sensor for detecting a current passing through an electric circuit between the load capacity sensor and a capacity notification device for notifying when a current detected by the load capacity sensor exceeds a prescribed threshold value Terminal unit of the remote monitoring control system, characterized in that.

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