JP2007096423A - Load control unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a load control unit which enables a user to execute ON/OFF operations of an individual load using an operating switch when an load communication control section is detached, and is connected to a network and enables a user to remotely control installed appliances or the individual load when the load communication control section is attached. <P>SOLUTION: The load control unit 1 is provided with the load communication control section 11 detachably/attachably connected to a load control unit body 22, and provided with a network connection terminal T4 to be connected to a network signal line L; an installed appliances load connecting terminal T3 for connecting a load of an appliance to be remotely controlled via the control section 11; a power feeding terminal T1 for feeding power source to the individual load; a switch connecting terminal T2 for connecting the operating switch; and the load control unit body 22 having a load power source feeding section incorporating a control relay to be controlled by the control section 11. The unit can control to turn ON/OFF the individual load using the operating switch in a state where the control section 11 is detached from the unit main body 22. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention is a load control unit that is connected to a network such as a LAN to remotely control home appliances and lighting fixtures, and is additionally connected with an operation switch so that individual loads such as lighting fixtures can be controlled on and off. It is about improvement.

  Recently, connected to a network such as a LAN, accessed from outside the dwelling unit by mobile phone, etc., not only remotely controlled air conditioners and lighting fixtures, but also operated switches for individual loads such as lighting fixtures. Load control units have been developed that can be additionally connected and turned on and off with an operation switch.

  This type of load control unit is disclosed in Patent Document 1 below, and FIG. 7 shows the internal configuration of such a load control unit. FIG. 8 shows an external configuration.

The load control unit 100 is configured by integrating a load communication control unit 111 and a load power supply unit 112, and the inside of the load power supply unit 112 is an individual such as a lighting fixture as shown in FIG. Load communication control having a power supply terminal T1 for supplying power to a load, connection terminals T2 and T2 for connecting an operation switch SW such as a wall switch, and a network connection terminal T4 for connecting to a network N by an internal connector 118 Connected to the unit 111.
In such a load control unit, an energization path is configured by the commercial power source AC, the lighting fixture S1 as an individual load, and the operation switch SW. Therefore, the power supply terminal T1 is connected to the commercial power source AC and is connected to the connection terminal. T2 and T2 are selectively connected to the switching terminals 114 and 115 through the contact points of the operation switches, respectively, and the common terminal 116 is connected to the lighting fixture S1.

  Further, the load power supply unit 112 is provided with a latch-type control relay 113, which is provided between the switching terminals 114 and 115 described above and the common connection point 117 connected to the power supply terminal T1. The first and second control contacts RY1 and RY2 are opened and closed by the communication control unit 111.

  According to such a load control unit 100, in the state shown in the figure, the first and second control contacts RY1 and RY2 of the control relay 113 are opened and closed, respectively, and the operation switch SW is connected to the contact point. Since the energization path is interrupted by the control contact RY1, the lighting fixture S1 is turned off. However, when the contact of the operation switch SW is set to the switching terminal 115 side, the control terminal RY2 passes through the control contact RY2. Since the energization path is formed, the lighting fixture S1 is lit. Then, when the operation switch SW is operated once again in the lighting state to bring the contact to the switching terminal 114 side, the lighting fixture S1 is turned off again.

On the other hand, when the load communication control unit 111 receives the lighting control signal from the network N in the state of FIG. 7, the control contacts RY1 and RY2 are controlled to be closed and opened by the communication control unit 111, respectively. Since the energization path via the contact point RY1 is formed, the lighting fixture S1 is turned on. On the other hand, when the control signal for turning off is received, the control contacts RY1 and RY2 return to the opened and closed states, respectively, so that the lighting fixture S1 is turned off again.
Therefore, in such a load control unit 100, the luminaire S1 can be controlled by either the operation switch SW or a control signal from the network N.

Japanese Patent Laid-Open No. 2003-309662

  However, since the load communication control unit 111 and the load power supply unit 112 are integrally formed in the conventional load control unit 100 described above, the cost is high for users who do not need remote control by the network N. There was a problem of becoming.

  The present invention is proposed in view of such circumstances, and can be used with the load communication control unit removed in accordance with the purpose of use. With the load communication control unit removed, the individual load can be operated. The purpose is to propose a load control unit with a new configuration that can be connected to a network and remotely control equipment and individual loads when the load communication control unit is attached.

  That is, in order to achieve the above object, the load control unit proposed as claim 1 is such that the load communication control unit is detachably connected to the load control unit main body via a connector, and the control relay is When the load communication control unit is detached from the load control unit, the first and second control contacts are held in a state in which the respective opening and closing are contradictory to each other.

  According to claim 1 of the present invention, when the load communication control unit is removed from the load control unit main body and the relay power supply is cut off, the first and second control contacts of the control relay are contradictory to open and closed, respectively. Therefore, the toggle operation by the operation switch is possible, and the individual load can be controlled on and off. In addition, if a load communication control unit is installed, it is convenient because both the equipment and the individual load can be remotely controlled through the network signal line.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is an exploded perspective view showing an external configuration of a load control unit according to an embodiment of the present invention.

  The load control unit 1 shown in the figure has a structure in which the load communication control unit 11 can be attached to and detached from the load control unit main body 22.

The load communication control unit 11 is configured to connect a network signal line L such as a LAN through a network connection terminal T4, and is provided with an external connection connector T5 for connecting an external device such as a notebook PC for maintenance. Yes.
An attachment recess 21 is provided in the load control unit main body 22, and the load communication control unit 11 is inserted into the attachment recess 21. Therefore, the connector 18 provided on the bottom surface of the load communication control unit 11 can be connected to and attached to the connector 18 provided corresponding to the mounting recess 21 of the load control unit main body 22, and is attached to the unit main body 22. When this happens, the connector 18 is not visible, and the appearance is smart.

  The load control unit main body 22 corresponds to an individual load such as the lighting fixture S1, and supplies a power supply terminal T1 for supplying power, connection terminals T2 and T2 for connecting operation switches such as a wall switch, and a control load connection terminal T3. It has.

  FIG. 2 is a perspective view showing a state in which the load communication control unit 11 is inserted into the load control unit main body 22 in the load control unit 1 having such a structure.

In such a state, the load communication control unit 11 is in a state where the two side surfaces 11a and 11a of the control communication unit 11 are exposed from the attachment recess 21 so as to be gripped.
In addition, 11b is a reset switch (corresponding to step 103 in FIG. 6 described later) for returning the combination of the open / closed states of the first and second control contacts RY1, RY2 of the control relay 13 to the initial position, 11c, 11d Indicates a reset switch for resetting the CPU block B.

  FIG. 3 is a block diagram showing a schematic configuration of the load control unit according to the embodiment of the present invention.

The load control unit 1 includes an Ethernet (registered trademark) block A having a network connection terminal T4 corresponding to the Ethernet (registered trademark) standard, a CPU block B that controls each unit as a control means, and a notebook PC during maintenance. RS232C block C for connecting through a connector for external connection (serial connector) T5, power supply block D having AC / DC converter I for converting AC commercial power into internal DC power, and individual loads such as lighting fixture S1 A load communication control unit 11 including a lighting interface block E that controls the JEM-A interface block F that controls equipment (home appliances) such as an air conditioner S2 that complies with the JEM-A standard, and an individual load. , Power supply terminal T1, and connection terminals T2, T2, A terminal block G with a built-in over, and a load power supply unit 12 consisting of a terminal block H having a control load connection terminals (HA terminal) T3 for connecting equipment.
Here, both terminal blocks G and F have one system, but a plurality of systems may be used.

In addition, the load control unit 1 configures an energization path including the commercial power supply AC, the lighting fixture S1 that is an individual load, and the operation switch SW. Therefore, the commercial power AC is connected to the power supply terminal T1 of the terminal block G, An operation switch SW is connected to the connection terminals T2 and T2.
In addition, an air conditioner S2 is connected to the control load connection terminal T3 of the terminal block H via the interface unit 2, and these connected individual loads and equipment loads can be remotely connected via the network signal line L. It has a communication function that can be remotely monitored and controlled.

  In such a communication function, the CPU block B provides a web-based device control screen to a communication terminal such as a mobile phone or a personal computer using the Ethernet (registered trademark) block A using the HTTPS protocol or the like. The status is displayed on the monitoring screen, and the control signal specifying the device is received from the control screen. At that time, if the designated individual load is the lighting fixture S1, the lighting interface block D connects and shuts off the energization path including the lighting fixture S1, and controls the lighting and extinguishing, while the designated equipment is In the case of the air conditioner S2, a JEM-A standard control signal corresponding to the received control signal is generated by the JEM-A interface block F and transmitted to the air conditioner.

  When a maintenance control command is received from an external device PC such as a notebook PC through the RS232C block C with the load communication control unit 11 removed from the load power supply unit 12 during construction or maintenance work, the load control unit 1 performs various types of fault diagnosis and various setting changes, and returns the results to the notebook PC. Communication settings such as an address to be processed by the Ethernet (registered trademark) block A may be set by a control command by the notebook PC.

  Since such a maintenance process is performed by removing the load communication control unit 11 from the load power supply unit 12, the load communication control unit 11 is connected to an AC commercial power source and converted by the AC / DC converter I of the power block D. It operates with the generated DC power supply.

  The external connection connector T5 may be a USB connector instead of a serial connector. In that case, power can be supplied from the USB connector.

  FIG. 4 is a diagram for explaining in detail the internal configuration of the load power supply unit 12 in the load control unit 1. Each block A to F in FIG. 1 constitutes the load communication control unit 11, and the terminal block G and the terminal block H constitute the load power supply unit 12.

  As shown in FIG. 4, the operation switch SW is a wall switch or the like, and the first and second switching terminals 15a with respect to one common terminal 16 connected to an individual load such as the lighting fixture S1. , 15b are configured to have contacts 14 for selectively switching connection, and the control relays 13, 13 are respectively connected between the switching terminals 15a, 15b and the common connection point 17 connected to the power feeding terminal T1. The load communication control unit 11 includes control contacts RY1 and RY2 that are opened and closed independently.

Each of the control contacts RY1 and RY2 is configured such that the control contact RY1 is a normally open type (normally open type) and the control contact RY2 is a normally closed type (normally closed type).
Since the first and second control contacts RY1 and RY2 have such a configuration, the first and second control contacts RY1 and RY2 are also removed when the load communication control unit 11 is detached from the load control unit main body 22 and the relay power supply is cut off. Since the control contacts RY1 and RY2 are kept in an open and closed state, the operation switch S can perform a so-called toggle operation that performs on / off control of the lighting fixture S1 each time it is operated.

  The first and second control contacts RY1 and RY2 need only be positioned in the opposite directions to the open and closed states, so that the first control contact RY1 is normally closed and the second control contact RY2 is normally closed. You may be comprised by the open type contact.

  In addition, the first and second control contacts RY1 and RY2 may be configured by latch relays that close and open the contacts by setting and resetting. If it carries out like this, power consumption can be suppressed when the load communication control part 11 is mounted | worn.

Each of the control contacts RY1 and RY2 is provided with a control contact state discriminating means 20 comprising monitoring contacts RY3 and RY4 that perform the same or opposite interlocking operation.
This control contact state determination means 20 outputs an L level voltage connected to GND or an H level voltage pulled up to Vcc by resistors R1 and R2 by the interlocking operation of the monitor contacts RY3 and RY4. . However, the control contact state determination unit 20 may be configured as a software unit that stores the number of times the control contacts RY1 and RY2 are driven from a predetermined reference time and determines the state based on the number of drive times. The monitoring contacts RY3 and RY4 have a plurality of control contacts in the case where a mechanical contact relay is employed as a control relay in order to control a large capacity current of the lighting fixture S1 and the like. If it is a thing, the unused thing should just be used.

  The load communication control unit 11 is further provided with individual load on / off determining means 19 for determining whether or not power is supplied to the switching terminals T2 and T2.

  FIG. 5 is a circuit diagram showing an example of the individual load on / off discriminating means 19. This circuit includes resistors R1 and R2, a capacitor C, and a photocoupler including photodiodes PD1 and PD2 and a phototransistor PTr. Here, when the lighting fixture S1 is in the on state, either one of the switching terminals T2 and T2 is in a high impedance state, so the photodiodes PD1 and PD2 do not blink, and if the lighting fixture S1 is in the off state, Since an alternating voltage is applied between the switching terminals T2 and T2, the photodiodes PD1 and PD2 blink, indicating that the lighting fixture S1 is in an extinguished state, but the alternating current flowing at this time is limited by the resistors R1 and R2. Therefore, the lighting fixture S1 does not light up. The phototransistor PTr converts the blinking of the photodiodes PD1 and PD2 into a voltage level and outputs the voltage level.

  Since the load control unit 1 is configured as described above, the voltage level output from the control contact state determination unit 20 is captured at a predetermined timing, and the control contacts RY1 and RY2 of the control relay 13 are opened or closed. When they are in the state, they are forcibly switched to open, closed or closed, open, and at that time, the individual load on / off discriminating means 19 takes in the voltage levels of the switching terminals 14 and 15 and turns on or off the lighting fixture S1. If the state is also determined, the control contacts RY1 and RY2 can be switched so that the lighting device S1 is turned off. Note that the predetermined timing includes when the load control unit 1 is turned on. Alternatively, the control may be performed when a specific control signal is received from the network N at regular intervals.

  In addition, when the load control unit 1 receives a control signal for turning on / off from the network N, the individual load on / off discriminating means 19 discriminates the on / off state of the luminaire S1 and turns it off (on state). ), The control contacts RY1 and RY2 of the control relay 13 may be switched and controlled reciprocally.

  The load control unit 1 operates as follows when the load communication control unit 11 is removed. That is, the control contacts RY1 and RY2 are opened and closed, respectively, and the on / off control of the lighting fixture S1 can be performed only by operating the operation switch SW.

  When the operation switch SW is operated and the contact 14 is set to the switching terminal 15a side, since the energization path to the luminaire S1 is interrupted by opening the control contact RY1, the luminaire S1 is turned off, while the contact of the operation switch SW When 14 is the switching terminal 15b, the energization path to the lighting fixture S1 is formed as the control contact RY2, the power supply terminal T1, and the individual load S1, and the lighting fixture S1 is turned on.

  FIG. 6 is a flowchart for specifically explaining processing in a state where the load communication control unit 11 is attached to the load control unit main body 22. When the power is turned on, the load communication control unit 11 determines whether the control contacts RY1 and RY2 of the control relay 13 are open or closed. If both control contacts RY1 and RY2 are open and closed, one is open. The switching control is forcibly performed so that the other is closed (steps 101 to 103).

  Thereafter, the operation proceeds to a standby state. In this standby state, the lighting fixture S1 can be controlled to be turned on and off by the operation switch SW (steps 104 and 105).

  When the control signal of the lighting fixture S1 is input through the network N in the standby state, the individual load on / off discriminating means 19 discriminates the on / off state of the lighting fixture S1, and the request based on the control signal and the on / off state of the lighting fixture S1. Are not matched with each other, the control contacts RY1 and RY2 are switched and controlled to be closed, open, or reciprocally open and closed (steps 106 to 111).

  If the control contacts RY1 and RY2 cannot be controlled normally, a retry process is performed to repeat the switching control several times. If the retry process fails a predetermined number of times, an error notification is sent (step 112). ~ 115).

1 is an exploded perspective view showing an example of the appearance of a load control unit according to the present invention (showing a state where a load communication control unit is removed). The perspective view which shows the example of an external appearance of the load control unit of this invention (showing the state which attached the load communication control part) The block diagram which shows an example of schematic structure of this invention The figure which shows an example of the internal structure (load power supply part) of this invention The figure which shows an example of a structure of an individual load on-off discrimination means Flow chart for explaining the basic operation of the present invention Diagram showing a conventional load control unit Diagram showing the appearance of a conventional load control unit

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Load control unit 18 Connector 21 Mounting recess 22 Load control unit main body 11 Load communication control part 12 Load power supply part 13 Control relay RY1, RY2 1st, 2nd control contact 14 Contact 15a, 15b 1st, 2nd Switching terminal 16 Common terminal 17 Common connection point 19 Individual load on / off discrimination means 20 Control contact state discrimination means I AC / DC converter T1 Power supply terminal T2 Connection terminal T3 Equipment load connection terminal T4 Network connection terminal L Network signal line S1 Lighting equipment (Individual) load)
S2 Air conditioner (equipment load)
PC Notebook PC for maintenance (external equipment)
SW operation switch RY3, RY4 Monitor contact

Claims (1)

A load communication control unit provided with a network connection terminal connected to the network signal line, an equipment load connection terminal for connecting an equipment load remotely controlled through the load communication control unit, and a power supply for supplying power to the individual load In a load control unit comprising a terminal, a switch connection terminal for connecting an operation switch, and a load control unit main body having a load power supply unit incorporating a control relay controlled by the load communication control unit,
The load communication control unit is detachably connected to the load control unit main body via a connector, and the control relay is disconnected when the load communication control unit is detached from the load control unit main body. The load control unit is configured such that the first and second control contacts are held in opposite open / close states.

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