JP3941622B2 - Address setting method for lighting control system and lighting apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an address setting method for a lighting control system for remotely controlling a lighting fixture.as well asIt relates to lighting equipment.
[0002]
[Prior art]
As an address setting method for a terminal device of a remote control system, a method disclosed in Japanese Patent Laid-Open No. 4-506443 has been conventionally provided. This remote control system has a configuration as shown in FIG. 25. The terminal device 100 generates a temporary address using a random number, an interface unit 101 that transmits and receives command signals, a control circuit 102 that performs signal processing of command signals, and the like. The control device 200 includes a terminal control unit 105 including a provisional address generation circuit 103 and a timer circuit 104, and a storage unit 106 that stores an address transmitted from the terminal control unit 105. The control device 200 is an interface that transmits and receives command signals. Unit 201, a control circuit 202 that performs signal processing of command signals, a control unit 204 that includes provisional address information transmitted from terminal device 100 and that determines a regular individual address, and a control unit 204, And a storage unit 205 for storing individual addresses transmitted fromThe control device 200 and the terminal device 100 are connected via a signal line L. The address setting method in this remote control system is as follows.
[0003]
First, as shown in FIG. 26, after the power is supplied to the control device 200 and the terminal device 100 (step S1), random numbers are generated by the temporary address generation circuit 103 in the terminal control unit 105 of the terminal device 100. Then, a temporary address is generated based on the random number (step S2), and the temporary address is output to the control circuit 102 in the terminal control unit 105. After the provisional address is output to the control circuit 102, the timer circuit 104 starts operation, and a transmission timing signal for transmitting the provisional address to the control device 200 is generated (step S3). The transmission timing signal is generated based on a time proportional to the provisional address value. Based on this transmission timing signal, the provisional address is transmitted from the terminal control unit 105 via the interface unit 101 as shown in step S4. The temporary address is stored in the storage unit 106 in the terminal device 100 (step S5).
[0004]
The control circuit 202 in the control unit 204 of the control device 200 outputs the temporary address received through the interface unit 201 to the address determination circuit 203 as shown in step S6. The address determination circuit 203 receives the input provisional address value, determines the individual addresses in ascending order of the provisional address values as shown in step S7, and assigns the individual address to the terminal device 100 having the provisional address. While transmitting in step S8, this individual address is stored in the memory | storage part 205 in the control apparatus 200 (step S10). Further, in the terminal device 100, when the individual address is received via the interface unit 101, it is transmitted and stored as a regular individual address to the storage unit 106 in the terminal device 100 (step S9).
[0005]
The conventional address setting step is started when the power is turned on. If the address setting operation is automatically performed every time the power is turned on, the desired address set when the remote control system is introduced is A different address may be set each time the power is turned on. For example, if the address setting is changed every time the control system is powered down for maintenance work, system management becomes very troublesome.
[0006]
In addition, a remote control system that employs an address setting method that uses a temporary address using a random number has been conventionally provided (see Japanese Patent Publication No. 8-506443).
[0007]
This remote control system is configured as shown in FIG. 27. The control device 300 includes a control unit 301 that performs signal processing and generation of command signals, and a terminal device 400 that is a controlled device.₁And a storage unit 302 that stores information associated with the provisional address of the terminal device 400.₁Are a random number generator 401 for generating a temporary address, a comparator 402 for comparing the size of the search command signal transmitted from the control device 300 with the size of the temporary address, and a storage unit for storing the temporary address and the individual address. 403 is provided. These control device 300 and terminal device 400₁... are connected via a signal line L, and the terminal device 400 according to a command signal transmitted from the control device 300.₁... works.
[0008]
The address setting method in this remote control system is as follows. First, as shown in FIG.₁... indicates an initialization command signal to the terminal device 400.₁(Step S10). This initialization command signal is sent to the terminal device 400.₁When receiving ..., each terminal device 400₁The random number generator 401 in FIG. 6 generates a tentative address by generating random numbers that are not related to each other (step S11), and each terminal device 400.₁Are stored in the storage unit 403. Terminal device 400₁When each generates a provisional address, the control device 300 transmits the terminal device 400.₁Based on the provisional address value of ..., the terminal device 400 connected in the remote control system₁In order to determine the order of..., A search command signal is generated by the control unit 301 in the control device 300, and the terminal device 400.₁... is transmitted to (step S12). This search command signal includes an arbitrary search value A that divides the range X of the provisional address value generated previously into a first section X1 and a second section X2 shown in FIG.
[0009]
Terminal device 400₁When the search command signal transmitted from the control device 300 is received,...₁... The temporary address generated by the white is read from the storage unit 401, and the comparison unit 402 compares the search value A included in the search command signal with the size of the temporary address value. When the temporary address value is smaller than the search value A, the terminal device 400₁... transmits a response signal to the control device 300. Here, the terminal device 400₁The provisional address generated in step 501 is the smallest, and the terminal device 400_ThreeThe temporary address generated by the terminal device 400 is the largest, and the terminal device 400₂Suppose that the temporary address generated in is between them.
[0010]
First, the control device 300 scans the search value A of the search command signal in the range of a small number to a large number, and the terminal device 400.₁Identifies that has the minimum provisional address. The control device 300 includes a terminal device 400₁When the response signal is received (step S13), the control device 300 sets the current search value A to the terminal device 400 having the smallest temporary address.₁Is stored in the storage unit 302 (step S14). Next, the control device 300 is connected to the terminal device 400.₁A special command signal accepted only by the terminal device 400₁By transmitting to the terminal device 400₁Is made insensitive to subsequent transmission of search command signals.
[0011]
The control device 300 includes a terminal device 400₂Is the remaining terminal device 400₁The search value A of the search command signal is incremented until the response signal is transmitted as having the smallest provisional address (step S15).
[0012]
Further, the control device 300 includes a terminal device 400.₂When the response signal from the terminal device 400 is received (step S13), the current search value A is obtained from the terminal device 400.₂Is stored in the storage unit 302 as a second terminal device (step S14), and the terminal device 400 is stored.₂Is insensitive to the transmission of other search command signals, and the terminal device 400_ThreeThe operation of incrementing the search value of the search command signal is continued until the response signal is transmitted (step S15).
[0013]
The control device 300 includes a terminal device 400_ThreeWhen the response signal from the terminal device 400 is received (step S13), the current search value A is obtained from the terminal device 400._ThreeThe third terminal device 400₁Is stored in the storage unit 302 (step S14), and the terminal device 400 is stored._ThreeIs insensitive to the transmission of other search command signals, and the remaining terminal device 400₁The search command signal is continuously transmitted to.
[0014]
In this conventional example, since there are no more terminal devices, the search value is incremented until the control device 300 reaches the upper limit without receiving a response signal thereafter.
[0015]
Reaching this upper limit means that the search value A and the terminal device 400₁It means that the creation of the list that associates ... is finished. Thereafter, the control device 300 is connected to the terminal device 400.₁How many terminal devices 400 during the search of₁... (here, 3) are determined to respond, and an individual address is generated for each of them (step S16). Terminal device 400₁Can be distinguished on the basis of the range of the associated search value A, the individual address created above is based on the related information stored in the storage unit 302 of the control device 300.₁... (step S17), and each terminal device 400 is transmitted.₁Are stored as individual addresses in the storage unit 401 (step S18).
[0016]
By repeatedly performing the address setting method as described above, a plurality of terminal devices 400 are provided.₁An individual address can be automatically set to…. However, if address setting is performed continuously, each terminal device 400₁There is a problem that the address setting operator cannot assign a desired address number to.
[0017]
That is, as shown in FIG.₁Arbitrary address numbers that are not related to the installation location and the arrangement of installations (in FIG. 30, the terminal device 400₁In the management of the remote control system, for example, the terminal device 400 including a lighting fixture is assigned.₁There is a risk that the location of… will be difficult to understand. Further, the terminal device 400 that performs address setting.₁When the number of... Is large, the terminal device 400 is set during the address setting operation.₁Is a different command signal from the command signal for address setting, for example, the terminal device 400₁The command signal for operating ... is received and the terminal device 400₁The control unit (not shown) may be occupied by signal processing for operation based on the command signal, and command signal processing for address setting may not be performed normally.
[0018]
Further, as an address setting method for the remote control system, for example, a method disclosed in JP-A-3-252292 is also provided. As shown in FIG. 31, the remote control system includes a control device 500, a controller 600, an interface unit 700, and a terminal device 800 connected to the interface unit 700. The control device 500 is shown in FIG. The controller 600 includes a calculation processing unit 501 that performs signal processing and generation of command signals, a storage unit 502 that stores setting address values of the remote control system, and a signal transmission / reception unit 503 that transmits and receives command signals. 32B, an arithmetic processing unit 601 that performs signal processing and generation of a command signal, a storage unit 602 that stores an address value set in itself and an address value set in the interface unit 700, A display unit 603 for displaying an operation state and a setting state of the control system; And it includes an operation unit 604 for performing a predetermined operation on the control system, and a signal transceiver 605 to transmit and receive command signals. As shown in FIG. 33, the interface unit 700 includes an arithmetic processing unit 701 that performs signal processing and generation of command signals, a storage unit 702 that stores an address value set in itself, and a terminal device 800 that is controlled by a control system. And a signal transmitting / receiving unit 704 for transmitting and receiving command signals. Further, the controller 600 and the interface unit 700 are provided with address reset switches 606 and 705, which are masterpieces at the start of address setting.
[0019]
The control device 500, the controller 600, and the interface unit 700 are connected via the signal line L, and the terminal device 800 connected to the device connection terminal portion 703 of the interface unit 700 can be controlled by the controller 600.
[0020]
The address setting method in this remote control system is as follows.
[0021]
First, as shown in FIG. 34, when the address reset switch 705 of the interface unit 700 for setting the address is operated (step S20), the address setting is performed in the arithmetic processing unit 701 in the interface unit 700 in which the address reset switch 705 is operated. A request signal is generated (step S21), and an address setting request signal is transmitted to the control device 500 via the signal transmission / reception unit 703 (step S22).
[0022]
The control device 500 that has received the address setting request signal refers to the already-set address data stored in the storage unit 502 in the control device 500 (step S23), and selects an address other than the already used address. (Step S 24), using the address as a setting address for the interface unit 700, an address setting command signal is generated by the arithmetic processing unit 501 in the control device 500 and transmitted to the interface unit 700 via the signal transmitting / receiving unit 503. (Step S25). The interface unit 700 that has received the address setting command signal via the signal transmission / reception unit 703 stores the setting address in the storage unit 702 (step S26), and then based on the address value stored in the storage unit 702. An address set value reply signal is generated (step S27), and the address set value reply signal is transmitted to the control device 500 via the signal transmission / reception unit 703 (step S28). When the control device 500 receives the address setting value reply signal via the signal transmission / reception unit 503, the arithmetic processing unit in the control device 500 displays the address value of the address setting value reply signal and the previously transmitted address setting value. When the comparison is made at 501 (step S29) and the coincidence of the address values is confirmed, the arithmetic processing unit 501 generates an address setting completion signal (step S30), and transmits the address setting completion signal to the interface unit 700 at step S31. At the same time, the address value is stored as a predetermined address in the storage unit 501 in the control device 500 (step S32).
[0023]
However, in the address setting method as described above, the operation of the address reset switch 705 is required for each interface unit 700 for setting an address. Therefore, when the number of interface units 700 connected to the remote control system increases, the address is set. It takes time and effort to set up, and it takes a lot of time for setting work. Further, in order to operate the address reset switch 705, it is necessary to directly touch a device such as the interface unit 700, and the address setting is performed after the installation work of the remote control system (for example, the device is installed behind the ceiling) is completed. It is difficult to perform or change the address setting.
[0024]
[Problems to be solved by the invention]
As described above, in the conventional address setting method, the system setting may be changed every time the remote control system is activated. In addition, it is necessary to individually operate the terminal device that performs address setting. Therefore, when the number of set terminals increases, there is a problem that the work load increases. In addition, since the device can be directly touched when operating the terminal device, it is difficult to set or change the address after the system is installed.
[0025]
On the other hand, in the address setting method using a temporary address, there is a problem that it is difficult to understand the system management by the address number because the location of the terminal device cannot be associated with the address number.
[0026]
  The present invention has been made in view of the above-mentioned problems, and the object of the present invention is to clarify the transition of settings when assigning individual addresses to the lighting fixtures that are terminal devices, and to accurately perform address settings. Lighting control system address setting methodas well asAn object of the present invention is to provide a lighting apparatus capable of notifying a setting operator of address setting standby and address setting completion.
[0027]
[Means for Solving the Problems]
  In order to achieve the above-mentioned object, the invention of the address setting method for a lighting control system according to claim 1 outputs a plurality of lighting fixtures and one or more command signals for performing lighting control and function setting of the lighting fixtures. Multiple control units are connected on the same signal line, bidirectional communication is performed between the luminaire and the control unit via the signal line, and the luminaire is sent by the command signal addressed to its own address sent from the control unit. In the address setting method used in the controlled lighting control system, when assigning an individual address to a lighting fixture, an address setting request command signal is transmitted from at least one of the control unit or the lighting fixture, and the address setting request command signal is When received, the control unit and the lighting fixture Address to give priority to dress setSetting priorityTransition to mode operationIn the address setting priority mode, the control unit and the lighting fixture perform signal processing and operation only for the command signal for address setting, and perform signal processing and operation for the command signal for requesting lighting control of the lamp load. If no control is performed and the control unit recognizes a specific lighting fixture that assigns an individual address, the control unit and the lighting fixture interrupt the address setting operation and set an address setting standby state in which an arbitrary address number can be set. DoIt is characterized by that.
[0031]
  Claim2The invention of the address setting method of the lighting control system of claim1In the invention, the arbitrary address number is determined by operation of the operating device, and information on the determined address number is transmitted from the operating device to the lighting device by an optical signal, so that the lighting device in the address waiting state is sent to the lighting device. It is characterized by performing individual address assignment.
[0032]
  Claim3The invention of the address setting method of the lighting control system of claim1In the present invention, when the individual address is not set, an insulating member for cutting off the electric path between the lighting device in the luminaire and the lamp load is provided, and the insulating member is removed when waiting for address setting, and the energization of the lamp load is started When this is detected, the lighting apparatus starts an address setting operation.
[0033]
  Claim4The invention of the address setting method of the lighting control system of claim1In this invention, the magnetic body is attached so as to be exposed on the surface of the luminaire, and at the time of address setting standby, an electromotive voltage change caused by a change in magnetic permeability caused by another magnetic body approaching the magnetic body When this is detected, the lighting apparatus starts an address setting operation.
[0035]
  Claim5The invention of the luminaire is the above-mentioned claim.1'sA lighting apparatus used in an address setting method of a lighting control system, comprising: display means for visually displaying standby for address setting and completion of address setting; and control means for controlling the operation of the display means. It is characterized by being.
[0036]
  Claim6The invention of the lighting apparatus is claimed in claim5In the invention, the display means is a lamp load, and the control means is provided with lighting control means for blinking lighting or dimming lighting.
[0037]
  Claim7The invention of the lighting apparatus is claimed in claim5In the invention, the display means is composed of a lamp that moves upward and downward with an auto-lifter device, and when the address setting standby and address setting are completed as a control means, the auto-lifter device is operated to move the lamp up and down. It is characterized by comprising.
[0038]
  Claim8The invention of the lighting apparatus is claimed in claim5In the invention, a lighting control unit that uses a high-intensity discharge lamp as a lamp load, includes a light compensation light source, uses the light compensation light source as the display unit, and lights the light compensation light source when address setting standby and address setting are completed. It is characterized by having.
[0039]
DETAILED DESCRIPTION OF THE INVENTION
  Embodiments of the present invention will be described below.
(BasicForm 1)
BookBasicThe form constitutes a lighting control system, and as shown in FIG. 1, one or a plurality of control units 1, a plurality of lighting fixtures 2, and a signal for connecting the control unit 1 and the lighting fixtures 2. The control unit is composed of a line 3, a lighting device 2, a power supply line 5 for supplying power to the control unit 1, and an operating device 4 connected to the control unit 1 and capable of instructing an operation for the lighting control system. 1 and the lighting fixture 2 perform two-way communication via the signal line 3. In FIG. 1, only one lighting fixture 2 is shown, but a plurality of signal fixtures 3 are connected.
[0040]
The control unit 1 includes a control unit 10 that performs signal processing and signal generation of a command signal, and a signal transmission / reception unit 11 that performs transmission and reception of the command signal, and the lighting fixture 2 is a control that performs signal processing and signal generation of the command signal. The unit 20 includes a signal transmission / reception unit 21 that transmits and receives command signals, a storage unit 22 that stores its own individual address, and a lighting device 23 that performs lighting control of the lamp load La.
[0041]
The operation device 4 includes an operation switch unit 40 that instructs a desired operation (ranf lighting control, address setting, etc.) to the illumination control system, and a signal generation unit 41 that generates a signal based on an instruction from the operation switch unit 40. Become.
[0042]
  BookBasicIn the lighting control system of the embodiment, the lighting control of the lighting fixture 2 and the setting of the address and function for the lighting fixture 2 can be performed based on the content of the command signal transmitted from the control unit 1.
[0043]
For example, in order to turn on (or turn off) the lamp load La of the luminaire 2, as shown in FIG. 2, the on button 40a (or the off button 40b) of the operation switch unit 40 provided on the front surface of the operation device 4 is pressed. Based on the operation content of the operation switch unit 40, a signal generation unit 41 in the operation device 4 generates a lamp-on signal (or lamp-off signal) and transmits it to the control unit 1. When the control unit 1 receives the lamp-on signal (or lamp-off signal) transmitted from the operation unit 4, the control unit 1 outputs the signal to the control unit 10 in the control unit 1, and the control unit 10 outputs the lamp-on signal (or Based on the lamp off signal), a lamp lighting command signal (or lamp extinguishing command signal) is generated. The lamp turn-on command signal (or lamp turn-off command signal) is transmitted to the predetermined lighting fixture 2 via the signal transmission / reception unit 11, and the lamp turn-on command signal (or lamp turn-off command signal) is received via the signal transmission / reception unit 21. The luminaire 2 performs signal processing of the lamp lighting command signal (or lamp extinguishing command signal) in the control unit 10 and instructs the lighting device 23 in the lighting fixture 2 to turn on (or turn off) the lamp load La. Is output. The lighting device 23 performs lamp power control for turning on (or turning off) the lamp load La according to an instruction from the control unit 10.
[0044]
When individually specifying the lighting fixture 2 that transmits the lamp lighting command signal (lamp extinction command signal), the individual address set in the lighting fixture 2 is used. As shown in FIG. 3, the lamp lighting command signal (or lamp extinguishing command signal) received by the designated lighting fixture 2 includes a start bit ST and an address AD of the lighting fixture 2 that turns on (or turns off) the lamp load La. The command data CT for operating instructions (in this case, lamp lighting) and the stop bit SP are included.
[0045]
Further, after the lighting control system is attached and wired, when an individual address is assigned to each lighting fixture 2 in the lighting control system, the address setting start button B1 of the operation switch unit 40 of the operating device 4 is set. When the button is pressed, an address setting start signal is generated by the signal generation unit 41 in the operation unit 4 based on the operation content of the operation switch unit 40 and transmitted to the control unit 1.
[0046]
When the control unit 1 receives the address setting start signal transmitted from the operation device 4, the control unit 1 outputs the signal to the control unit 10 in the control unit 1, and the control unit 10 based on the address setting start signal, An address setting start command signal is generated. The address setting start command signal is transmitted to the lighting fixture 2 in the lighting control system via the signal transmission / reception unit 11. When each luminaire 2 receives the address setting start command via the signal transmitting / receiving unit 21, the control unit 10 performs signal processing to set the address setting priority mode. After each lighting fixture 2 has shifted to the address setting priority mode, in the address setting priority mode, in the lighting control system, the control unit 1 recognizes a specific lighting fixture 2 that performs address assignment processing, and the control unit 1 The step of transmitting the individual address generated in the control unit 1 to the recognized specific lighting fixture 2 and the specific lighting fixture 2 receiving the individual address transmitted from the control unit 1 Are stored in the storage unit 22, and the step of confirming that the control unit 1 has assigned the individual addresses to the lighting fixtures 2 is performed, and the individual addresses are assigned to all the lighting fixtures 2 in the lighting control system. The process through the above steps can be repeated until Accordingly, the address setting is made for each lighting fixture 2.
[0047]
In FIG. 2, reference numeral 40c denotes an operation unit for setting a dimming level, and this dimming level is also transmitted to the luminaire 2 of the corresponding address by the signal in the form shown in FIG.
[0048]
  The lighting device 23 of the luminaire 2 includes, for example, an AC / DC conversion circuit 23a, an inverter circuit 23b, and a load resonance circuit 23c as shown in FIG. 4, and corresponds to the dimming level set by the operation of the operation unit 40c. It has a dimming function for dimming by controlling the power to the lamp load La based on the dimming signal. The followingBasic form andIt is assumed that the lighting device 23 of the embodiment is configured similarly.
(BasicForm 2)
BookBasicThe form isBasicLike the lighting control system of the first embodiment, as shown in FIG. 5, one or a plurality of control units 1, a plurality of lighting fixtures 2, a signal line 3 connecting the control unit 1 and the lighting fixture 2, The illumination control system includes a power line (not shown), and the control unit 1 and the luminaire 2 perform two-way communication via the signal line 3. The control unit 1 is connected to an operating device 4 that can instruct an operation for the lighting control system.
[0049]
As shown in FIG. 6, the control unit 1 generates a control unit 10 that performs command signal processing and signal generation, a signal transmission / reception unit 11 that transmits and receives command signals, and an individual address that is assigned to the lighting fixture 2. The address generation circuit 12 includes a storage unit 13 that stores an individual address assigned to the luminaire 2, and an operation unit interface unit 14 that receives a signal transmitted from the operation unit 4.
[0050]
As shown in FIG. 7, the luminaire 2 includes a control unit 20 that performs signal processing and signal generation of command signals, a signal transmission / reception unit 21 that transmits and receives command signals, and a storage unit 22 that stores its own individual address. A temporary address generation circuit 24 for generating a temporary address to be used for address setting, a timer circuit 25 for setting a transmission delay time for transmission of the temporary address notification command signal, and temporary address generation and transmission delay time setting. A random number generation circuit 26 for generating a random number to be used at the time, and a lighting device 23 for controlling the lighting of the lamp load La.
[0051]
As shown in FIG. 8, the operation device 4 generates an operation switch unit 40 for instructing a desired operation (lamp lighting control, address setting, etc.) to the illumination control system, and a signal based on the instruction from the operation switch unit 40. And a signal output interface unit 42 for transmitting the signal generated by the signal generation unit 41 to the control unit 1. The operation switch section 40 has a configuration similar to that shown in FIG. 2 and includes an address setting start button B1 that is operated when address setting is started.
[0052]
  BookBasicIn the lighting control system of the embodiment, a method for assigning individual addresses to the respective lighting fixtures 2 connected to the signal line 3 is as follows.
[0053]
First, when the address setting start button B1 provided in the operation switch unit 40 of the operation device 4 is operated, the signal generation unit 41 in the operation device 4 performs the transition to the address setting priority mode by operating the address setting start button B1. An “address setting request signal” is generated and transmitted to the control unit 1 via the signal output interface unit 42.
[0054]
When the control unit 1 receives the “address setting request signal” transmitted from the operation unit 4 via the operation unit interface unit 14, the control unit 1 outputs the signal to the control unit 10 in the control unit 1. Then, based on the “address setting request signal”, an “address setting start command signal” for causing the lighting fixture 2 in the lighting control system to recognize the start of address setting is generated, and the operation mode of the control unit 1 itself Is placed in “address setting priority mode”.
[0055]
The “address setting start command signal” previously generated by the control unit 10 is transmitted to each luminaire 2 in the lighting control system via the signal transmission / reception unit 11 in the control unit 10.
[0056]
When each luminaire 2 receives the “address setting start command” via the signal transmission / reception unit 21 in the luminaire 2, the control unit 20 performs signal processing of the “address setting start command signal”. Recognizing that the address setting operation starts, each lighting apparatus 2 sets its own operation mode to the “address setting priority mode”.
[0057]
Through the above steps, the entire lighting control system is placed in the “address setting priority mode” as shown in FIG.
[0058]
Incidentally, the connection form between the operation device 4 that outputs the “address setting request signal” and the control unit 1 that receives the signal can be connected in either a wired connection or a wireless connection.
[0059]
When the operation unit 4 and the control unit 1 are connected wirelessly, for example, an infrared transmission unit is used for the signal output interface unit 42 in the operation unit 4 and an infrared light receiving unit is used for the operation unit interface unit 14 of the control unit 1. This is possible.
[0060]
Further, in the “address setting priority mode”, an operation of performing signal processing on a command signal for address setting in the control unit 10 of the control unit 1 and the control unit 20 in the lighting fixture 2 becomes effective. The control unit 10 of the control unit 1 and the control unit 20 of the luminaire 2 are provided with an operation mode determination unit, and the system is set to “address setting priority mode” by the “address setting start command signal”. Even when a signal for requesting lighting control of the lamp load La is output from the operating device 4 when placed, the control unit 1 is a signal requesting lighting control by the operation mode determination unit in the control unit 10. The command signal for lighting control which discriminate | determines and transmits to the lighting fixture 2 is not produced | generated.
[0061]
Furthermore, in a state in which the same “address setting priority mode” is set, the luminaire 2 sends a command signal for controlling the lighting of the lamp load La transmitted via the signal line 3 in the luminaire 2. When the signal is received via the signal transmission / reception unit 21, an operation mode determination unit (not shown) in the control unit 10 determines the content of the command signal and instructs the lighting device 23 of the lighting control content included in the command signal. Each has a function that does not perform signal processing.
[0062]
Thus, as described above, when the address assignment to the lighting control system is performed, the step of shifting to the “address setting priority mode” by the “address setting start command signal” is provided. It is possible to clearly distinguish between a normal operation state in which the lighting control is performed and an operation state in which the address setting operation to the lighting fixture 2 is prioritized.
[0063]
Therefore, the address setting operation can be validated only when the user of the lighting control system wants to set the address to the lighting fixture 2, and the address setting operation, the address setting execution operation in the control unit 1 and the lighting fixture 2 can be performed. Certainty can be increased. Therefore, the problem that the address setting is changed every time the lighting control system is started is solved, and the address setting cannot be executed accurately by the signal processing of the command signal that requests the lighting control during the address setting. Without such a problem, it is possible to perform signal processing with priority given to the command signal for address setting.
[0064]
In addition, when starting address setting, the lighting control system may be placed in the “address setting priority mode” all at once by the “address setting start command signal” generated by the control unit 1 based on the address setting start request from the operation device 4. Therefore, the setting start operation required for each lighting fixture 2 for performing address setting becomes unnecessary, and the burden on the address setting operator is reduced.
[0065]
Next, address assignment for individual lighting fixtures 2 will be described with reference to FIG.
[0066]
First, a temporary address generation step will be described. When each lighting fixture 2 in the lighting control system shifts to the “address setting priority mode”, the control unit 20 in each lighting fixture 2 causes the random number in the lighting fixture 2 to be changed. The generation circuit 26 is instructed to generate a random number. In response to the instruction from the control unit 20, the random number generation circuit 26 generates a random number in step a of FIG. 9 and outputs it to the control unit 20. In this case, in order to reduce the probability that the generated random numbers coincide with each other in each lighting fixture 2, the range of values that can be taken by the random number generated by the random number generation circuit 26 can be the individual address value set in the lighting fixture 2. It is desirable to make it larger than the range. When receiving the random number generated by the random number generation circuit 26, the control unit 20 instructs the temporary address generation circuit 24 to generate a temporary address based on the random number. Upon receiving the temporary address generation instruction, the temporary address generation circuit 24 generates a temporary address based on the random number value (step b in FIG. 9), and stores the temporary address value in the storage unit 22. Further, the control unit 20 outputs an instruction to set a signal transmission delay time to the timer circuit 25 based on the random number generated by the random number generation circuit 26. Receiving the instruction, the timer circuit 25 sets a signal transmission delay time based on the random number value (step c in FIG. 9), and outputs it to the control unit 20. Even if the control unit 1 receives the lamp-on signal transmitted from the controller 4 during the operation, the operation mode determination unit in the control unit 10 of the control unit 1 controls the lighting of the lamp load La. This command signal is requested, and it is determined that the own unit is in the “address setting priority mode”, and the lamp lighting command signal is not generated.
[0067]
Next, the temporary address notification step of FIG. 9 will be described.
[0068]
First, when step c is completed, the control unit 20 in the luminaire 2 reads the previously generated temporary address value from the storage unit 22 and displays a “temporary address notification command signal” including information on the temporary address value. 9, this “temporary address notification command signal” is transmitted to the control unit via the signal transmission / reception unit 21 after a transmission delay time (e in FIG. 9) set based on the random number value by the timer circuit 25. 1 is transmitted (timing t1 in FIG. 9).
[0069]
Next, when the control unit 1 receives the “temporary address notification command signal” transmitted from the lighting fixture 2 via the signal transmission / reception unit 11, the control unit 1 performs signal processing on the “temporary address notification command signal”. Based on the above, an instruction to generate a formal individual address to be assigned to the luminaire 2 is output to the address generation circuit 12. The address generation circuit 12 generates an individual address based on the instruction (step f in FIG. 9) and outputs it to the control unit 10. Upon receiving the formal individual address generated by the address generation circuit 12, the control unit 10 sets the individual address on the side of the luminaire 2 that has transmitted the “provisional address notification command signal”. A setting command signal "is generated (step g in FIG. 9). The “individual address value setting command signal” includes information on the temporary address value and information on the formal individual address value. The “individual address value setting command signal” is transmitted to the “temporary address” via the signal transmitting / receiving unit 11. The notification command signal "is transmitted to the lighting fixture 2 that has transmitted (timing t2 in FIG. 9).
[0070]
When the lighting fixture 2 receives the “individual address value setting command signal” via the signal transmission / reception unit 21, the control unit 20 performs signal processing, and the individual address value included in the “individual address value setting command signal”. Is stored in the storage unit 22 (step h in FIG. 9). The control unit 20 generates an “individual address setting completion command signal” in step i of FIG. 9 and transmits it to the control unit 1 via the signal transmitting / receiving unit 21 (timing t3 in FIG. 9).
In the next individual address registration step to the control unit 1, when the control unit 1 receives the "individual address setting completion command signal", the individual address included in the previously transmitted "individual address value setting command signal" is It stores in the memory | storage part 22, and the address setting process with respect to the said lighting fixture 2 is complete | finished.
[0071]
Next, the process of repeating the individual address setting will be described. In this process, after the completion of step i, the signal transmission delay time e ′ is passed, and the lighting apparatus 2 in which the individual address is set in the signal processing continues. In the lighting fixture 2, a signal transmission delay time different from the signal transmission delay time set in the lighting fixture 2 for which the individual address is set is set, and the “temporary address notification command signal” is transmitted from the lighting fixture 2. As a result, the same signal processing as described above is performed in the control unit 1 and the lighting fixture 2.
[0072]
Thereafter, individual address setting for each lighting fixture 2 is successively and continuously performed. (Steps a 'to i')
Then, after the control unit 1 receives the “individual address setting completion command signal”, the control unit 1 does not receive the “individual address setting completion command signal” from the lighting fixture 2 for a certain time (step j in FIG. 9). The control unit 10 of the unit 1 determines that the individual address setting has been completed for all the lighting fixtures 2 in the lighting control system, and generates an “address setting priority mode release command signal” (step k in FIG. 9). The signal is transmitted via the signal transmission / reception unit 11 at timing t4 in FIG. When each of the lighting fixtures 2 in the lighting control system receives the “address setting priority mode release command signal” via the signal transmission / reception unit 21 at timing t5 (approximately t4) in FIG. 9, the control unit 20 performs signal processing. Then, it releases its own “address setting priority mode” and returns to the operation mode in which the normal lighting control is performed.
[0073]
  More booksBasicIn the address setting method employed in the embodiment, after the lighting control system shifts to the “address setting priority mode”, it is possible to automatically and continuously perform address setting for all the lighting fixtures 2 in the system. Therefore, the burden on the address setting work is reduced for the setting worker. Further, for the address setting, an operation of directly touching the lighting fixture 2 is not necessary, and address setting after the lighting control system is installed and setting change work can be easily performed.
(Embodiment1)
  This embodimentBasicThe illumination control system shown in FIG. 4 similar to the second embodiment is characterized in that it is performed as follows when individual addresses are assigned to the respective lighting fixtures 2 in the illumination control system. The circuit configuration of each part isBasic form 26 to 8 will be referred to.
[0074]
That is, when the address setting start button B1 provided in the operation switch unit 40 of the operation device 4 shown in FIG. 10 is operated, the signal generation in the operation device 4 is generated based on the operation content. An “address setting request signal” is generated by the unit 41 and transmitted to the control unit 1 via the signal output interface unit 42. When the control unit 1 receives the “address setting request signal” transmitted from the operating unit 4 via the operating unit interface unit 14, the control unit 1 outputs the “address setting request signal” to the control unit 10 in the control unit 1. Based on the “address setting request signal”, the control unit 10 generates an “address setting start command signal” for causing the lighting fixture 2 in the lighting control system to recognize the start of address setting, and the control unit 1. Put itself in "address setting priority mode".
[0075]
The “address setting start command signal” previously generated by the control unit 10 is transmitted to each lighting fixture 2 in the lighting control system via the signal transmission / reception unit 11 in the control unit 1.
[0076]
When each of the lighting fixtures 2 receives the “address setting start command signal” via the signal transmission / reception unit 21 in the lighting fixture 2, the control unit 20 performs signal processing of the “address setting start command signal”, and the control unit 20 recognizes that the address setting process starts thereafter, and each luminaire 2 puts itself in the “address setting priority mode”.
[0077]
Through the above steps, the entire illumination control system is placed in the “address setting priority mode” as shown in FIG.
[0078]
Next, when each lighting fixture 2 in the lighting control system shifts to the “address setting priority mode”, the control unit 20 in each lighting fixture 2 generates a random number to the random number generation circuit 26 in the lighting fixture 2. Instruct. In response to the instruction from the control unit 20, the random number generation circuit 26 generates a random number in step a of FIG. 11 and outputs the random number to the control unit 20. As for the random number generation circuit 26, there is a method in which a function for detecting the bus voltage of the signal line 3 is provided, and a random number is generated based on the variation value of the bus voltage generated depending on the connection location of the lighting fixture 2 (Japanese Patent Laid-Open 11-214166).
[0079]
When receiving the random number generated by the random number generation circuit 26, the control unit 20 instructs the temporary address generation circuit 24 to generate a temporary address based on the random number. Upon receiving the temporary address generation instruction, the temporary address generation circuit 24 generates a temporary address based on the random number value in step b of FIG. 11 and stores the address value in the storage unit 22 via the control unit 20. Further, the control unit 20 outputs an instruction to set a signal transmission delay time to the timer circuit 25 based on the random number generated by the random number generation circuit 26. Upon receiving the instruction, the timer circuit 25 sets the signal transmission delay time based on the random number value as shown in step c of FIG.
[0080]
Next, when step c is completed, the control unit 20 in the luminaire 2 reads the generated temporary address value from the storage unit 22 and outputs a “temporary address notification command signal” including information on the temporary address value in FIG. The “temporary address notification command signal” generated in step d is transmitted to the control unit 1 via the signal transmission / reception unit 21 in accordance with the transmission delay time e set based on the random number value by the timer circuit 25 (FIG. 11). Timing t1).
[0081]
Next, when the control unit 1 receives the “temporary address notification command signal” transmitted from the lighting fixture 2 via the signal transmission / reception unit 11, the control unit 1 performs signal processing on the control unit 10 and outputs a “temporary address confirmation command signal”. In addition to the generation at step f in FIG. The luminaire 2 that has received the “provisional address confirmation command signal” performs signal processing in the control unit 20, puts itself in the “individual address setting standby”, and visually sees that it has transmitted the temporary address to the control unit 1. In order to display automatically, a blink control instruction for the lamp load La is generated and output to the lighting device 23.
[0082]
This blinking control instruction is an instruction for the setting operator to visually recognize the lighting apparatus 2 in “individual address setting standby”.Basic form 2In the “address setting priority mode” described above, there is no contradiction with a function that does not perform signal processing of a command signal for lighting control.
[0083]
The lighting device 23 in the lighting fixture 2 that has received the blink control instruction performs power control of the lamp load La for blinking the lamp load La. The luminaire 2 that is in “individual address setting standby” can be visually recognized by the setting operator confirming the luminaire 2 that is blinking.
[0084]
Next, after the lighting apparatus 2 for “individual address setting standby” is set, the setting operator operates the individual address selection buttons B21 and B21 of the operation unit 4 to display a desired address number to be assigned to the lighting apparatus 2. The address number displayed at 43 is determined by up / down. When the individual address transmission button B3 is operated after the desired address number is determined, the signal generation unit 41 in the controller 4 generates an address information signal including information on the individual address value (step g in FIG. 11). ) And transmitted to the control unit 1 through the signal output interface unit 42. When the control unit 1 receives the address information signal via the interface for the operation device 4, the control unit 20 performs signal processing, and includes an “individual address value including an address number desired by the setting operator included in the address information signal. A setting command signal "is generated in step h of FIG. 11, and is transmitted to the luminaire 2 in the individual address setting standby state via the signal transmitting / receiving unit 11 (timing t3 in FIG. 11).
[0085]
Next, when the luminaire 2 receives the “individual address setting command signal”, the control unit 20 performs signal processing, and stores the individual address value included in the “individual address setting command signal” in the storage unit 22 (FIG. 11 step i). Further, the control unit 20 generates an “individual address setting completion command signal” (step j in FIG. 11), and transmits it via the signal transmission / reception unit 21 (timing t4 in FIG. 11).
[0086]
When receiving the “individual address setting completion command signal”, the control unit 1 stores the individual address included in the previously transmitted “individual address setting command signal” in the storage unit 13.
[0087]
Further, the control unit 20 generates a dimming light lighting instruction for the lamp load La and outputs it to the lighting device 23 in order to visually display that the address setting to the lighting fixture 2 has been completed.
[0088]
The lighting device 23 performs the power control of the lamp load La for dimming and lighting the lamp load La load La in response to the instruction, and visually notifies the setting operator that the address setting to the lighting fixture 2 has been completed. .
[0089]
As a means for visually displaying completion of address setting to the lighting fixture 2, for example, a display light source Lb is provided on the surface of the lighting fixture 2 as shown in FIG. 12, and the light source Lb is blinked or dimmed. Anyway.
[0090]
As shown in FIG. 13, in the case of the lighting fixture 2 provided with the auto lifter device 50 for high ceiling use, when the address setting is completed, the lamp of the lighting fixture 2 is indicated by an arrow by driving the motor of the auto lifter device 50. You may make it move up and down.
[0091]
Further, as shown in FIG. 14, for the lighting fixture 2 having the light compensation light source Lc using the high-intensity discharge lamp as the lamp load La, the address setting to the lighting fixture 2 is completed by turning on the light compensation light source Lc. Is displayed visually.
[0092]
By repeatedly performing the address setting operation repeatedly through the transmission delay time e, it is possible to set individual addresses for all the lighting fixtures 2 in the lighting control system.
[0093]
Then, as shown in FIG. 11, when setting of individual addresses is completed for all the lighting fixtures 2 by repeating steps a ′ to j ′ after a delay time e, the address setting end button B4 of the operation device 4 is operated. To do. When this operation is performed, an “address setting end signal” is generated by the signal generation unit 41 in the operation device 4 (step k in FIG. 11), and is transmitted to the control unit 1 via the signal output interface unit 42. When the control unit 1 receives the “address setting end signal” via the operation unit interface unit 14, the control unit 20 generates an “address setting priority mode release command signal” (step l in FIG. 10). It transmits via the transmission / reception part 11 (timing t5 of FIG. 11). When each lighting fixture 2 in the lighting control system receives an “address setting priority mode release command signal” via the signal transmitting / receiving unit 21 (timing t6 in FIG. 11), the control unit 20 performs signal processing, Cancel the “address setting priority mode” and return to the operation mode for normal lighting control. Then, the address setting priority mode of the lighting control system ends.
[0094]
In the address setting method in the present embodiment described above, the address setting operator visually confirms the luminaire 2 that has notified the temporary address to the control unit 1, and the address number desired by the setting operator using the operation device 4. Can be assigned to the lighting fixture 2, an address number associated with the installation location of the lighting fixture 2 can be assigned, and maintenance management of the lighting control system is facilitated.
[0095]
  FIG. 15 shows an example of setting the address numbers (numbers in the block of the lighting fixture 2 in the figure) of each lighting fixture 2 in the present embodiment.
(Embodiment2)
  Embodiment1In the step of assigning a desired individual address of the setting operator from the operating device 4 to the lighting device 2 in the address setting standby state, the operating device 4 applies the lighting device 2 to the lighting device 2 without going through the control unit 1. There is also a method of directly assigning individual addresses.
[0096]
As shown in FIG. 16, the luminaire 2 includes a control unit 20 that performs signal processing and signal generation of command signals, a signal transmission / reception unit 21 that transmits and receives command signals, a storage unit 22 that stores its own individual address, and an address Temporary address generation circuit 24 for generating a temporary address used for setting, timer circuit 25 for setting a transmission delay time for command signal transmission, temporary address generation circuit 23, and a random number used for setting the transmission delay time A random number generating circuit 26 for generating the light, a lighting device 23 for performing lighting control of the lamp load La, and an optical signal receiving unit 26 for receiving an optical signal transmitted by the operating device 4.
[0097]
On the other hand, as shown in FIG. 17, the operation device 4 corresponds to the operation switch unit 40 and the operation switch unit 40 that instruct a desired operation (lamp load lighting control, address setting, etc.) to the lighting control system. According to the specified address number, an address generation circuit 45 that generates an individual address, a signal generation unit 41 that generates a signal based on an instruction from the operation switch unit 41, and a signal generated by the signal generation unit 41 is converted into an optical signal. The lighting control system is provided with an optical signal transmission unit 44 for transmission to the control unit 1, and the illumination control system is set to the address setting priority mode by operating the address setting start button B1 provided in the operation switch unit 40 as shown in FIG. In the state where the specific lighting fixture 2 is waiting for the individual address setting, the setting operator sets a desired address to be assigned to the lighting fixture 2. Determined by operating the individual address selection buttons B21, B22 of the numbers operating device 4.
[0098]
When the individual address transmission button is operated after the desired address number is determined, the address generation circuit 12 in the controller 4 generates an “individual address setting command signal” including the address number information, and transmits the optical signal. To the unit 44. The optical signal transmission unit 44 converts the “individual address setting command signal” as an optical signal, and transmits the optical signal to the lighting apparatus 2 in the individual address setting standby state. In order to accurately transmit the “individual address setting command signal” to the luminaire 2, an infrared signal having a directivity or a laser beam is used as the form of the optical signal.
[0099]
Now, when the lighting fixture 2 receives the “individual address setting command signal” via the optical signal light receiving unit 26, the control unit 20 performs signal processing, and sets the address value by value included in the “individual address setting command signal”. Store in the storage unit 22.
[0100]
Further, as another means for directly assigning an individual address to the luminaire 2 from the operation device 4, for example, a connection in which the lamp load La is not energized before setting the individual address to the luminaire 22 as shown in FIG. An insulating member 60 interposed between the pin 61 and the blade holder 63 of the lamp holder 62 is provided, and when assigning individual addresses, the insulating member 60 is removed, and the luminaire 2 in which the lamp load La is energized in order. There is also a method for assigning individual addresses.
[0101]
With respect to this configuration, as shown in FIG. 20, the control unit 20 in the luminaire 2 is provided with a lamp conduction detecting unit 20a to detect that the lamp load La is electrically connected.
[0102]
Thus, if the insulating member 60 is removed while the lighting fixture 2 is in the individual address setting standby state, the lamp conduction detection unit 20a of the control unit 20 in the lighting fixture 2 has the lamp load La of the lighting fixture 2 electrically The random number generator 26 is instructed to generate a random number. In response to the instruction from the control unit 20, the random number generation circuit 26 generates a random number and outputs it to the control unit 20. When receiving the random number generated by the random number generation circuit 26, the control unit 20 instructs the temporary address generation circuit 24 to generate a temporary address based on the random number. Upon receiving the temporary address generation instruction, the temporary address generation circuit 24 generates a temporary address based on the random number value and stores the address value in the storage unit 22 via the control unit 20. The control unit 20 in the luminaire 2 reads the previously generated temporary address value from the storage unit 22, generates a “temporary address notification command signal” including information on the temporary address value, and passes the signal transmission / reception unit 21. Is transmitted to the control unit 1. When the control unit 1 receives the “provisional address notification command signal” transmitted from the lighting fixture 2 via the signal transmission / reception unit 11 (see FIG. 6), the control unit 10 (see FIG. 6) in the control unit 1 Processing is performed, and the individual address data stored in the storage unit 13 (see FIG. 6) is referred to and an unused address number is confirmed. When the control unit 10 grasps the unused address number, the control unit 10 outputs an instruction to generate the minimum value among the unused addresses as the individual address value to the address generation circuit 12 (see FIG. 6). The address generation circuit 12 generates an individual address based on the instruction and outputs it to the control unit 10. When the control unit 10 receives the individual address generated by the address generation circuit 12, the control unit 10 generates an “individual address setting command signal” and transmits it via the signal transmission / reception unit 11.
[0103]
When the corresponding lighting fixture 2 receives the “individual address setting command signal”, the control unit 20 performs signal processing and stores the individual address value included in the “individual address setting command signal” in the storage unit 22.
[0104]
  In the lighting apparatus 2 waiting for individual address setting, as another method in which the lighting apparatus 2 moves to the step of generating a temporary address, as shown in FIG. 21, the magnetic body 70 is exposed on the surface of the lighting apparatus 2 and attached. When the address is set, the magnetic body 71 caused by a change in magnetic permeability caused by bringing another magnetic body 71 attached to the tip of the bar 72 by the setting operator M close to the magnetic body 70 provided in the lighting fixture 2. As shown in FIG. 22, there is also a method of detecting an electromotive voltage change by an electromotive voltage change detecting unit 20b provided in the control unit 20, and using the electromotive voltage change detection as a trigger to shift to temporary address generation. In this method, the embodiment1Similarly, the address number desired by the setting worker M can be assigned to the lighting fixture 2. Therefore, an address number associated with the installation location of the lighting fixture 2 can be assigned, and maintenance management of the lighting control system is facilitated.
(Embodiment3)
  In the present embodiment, an address when a lighting fixture 2 ′ with no individual address set is newly connected as shown in FIG. 23 to the lighting control system in which the individual address has been set by the method described in the above embodiments. It relates to the setting method. The circuit configuration of the lighting fixtures 2 and 2 ′, the circuit configuration of the control unit 1, and the circuit configuration of the operation unit 4 are as follows:BasicAlthough it is basically the same as the system of form 2, the method of this embodiment can be applied to the method of any embodiment.
[0105]
Thus, when the new lighting fixture 2 'is connected to the signal line 3 and the power is turned on, the control unit 20 in the lighting fixture 2' inquires the storage unit 22 whether or not an individual address is set. In response to this inquiry, when the control unit 20 recognizes that the individual address is not set in the lighting fixture 2 ′, it generates an “address setting request command signal” as shown in step a of FIG. While transmitting via the transmission / reception part 21, the said lighting fixture 2 'itself is set into "address setting priority mode." When the control unit 1 receives the “address setting request command signal” transmitted from the lighting fixture 2 ′, the control unit 10 in the control unit 1 performs signal processing, and stores the individual address data stored in the storage unit 13. The unused address number is referred to and confirmed (step b in FIG. 24). When the control unit 10 knows the unused address number, it outputs an instruction to generate one of the unused addresses as an individual address value to the address generation circuit 12. Based on the instruction, the address generation circuit 12 generates an individual address in step c of FIG. 23 and outputs it to the control unit 10. When the control unit 10 receives the individual address generated by the address generation circuit 12, it generates an “individual address setting command signal” and transmits it via the signal transmission / reception unit 11 (timing t2 in FIG. 24). When the lighting device 2 ′ receives the “individual address setting command signal”, the control unit 20 performs signal processing, and stores the individual address value included in the “individual address setting command signal” in the storage unit 22 (FIG. 24 step d). Then, at step e, an “individual address setting completion command signal” is generated, and at timing t3, an “individual address setting completion command signal” is transmitted via the signal transmitting / receiving unit 21 to end the address setting priority mode.
[0106]
As described above, when a lighting fixture 2 ′ whose individual address is not set is newly connected in the lighting control system, only the newly connected lighting fixture 2 ′ is individually switched to the “address setting priority mode”. Address setting processing can be performed, and the address setting for the added lighting fixture 2 'can be easily performed without changing the individual address of the lighting fixture 2 originally in the system.
[0107]
【The invention's effect】
  The invention of the address setting method of the lighting control system according to claim 1 is characterized in that a plurality of lighting fixtures and one or a plurality of control units for outputting command signals for performing lighting control and function setting of the lighting fixtures are on the same signal line. Used in a lighting control system in which two-way communication is performed between a lighting fixture and a control unit via a signal line, and the lighting fixture is controlled by a command signal addressed to its own address sent from the control unit. In the address setting method, when assigning an individual address to a lighting fixture, an address setting request command signal is transmitted from at least one of the control unit or the lighting fixture, and when the address setting request command signal is received on the other side, the control unit, lighting Each device has an address that prioritizes address setting. ScanSetting prioritySince the mode operation is performed, the address can be set without being affected by other command signals when the address is set, and the address can be set accurately.
  Further, in the address setting priority mode, the control unit and the lighting fixture perform signal processing and operation only for the command signal for address setting, and perform signal processing and operation for the command signal for requesting lighting control of the lamp load. Since it is not performed, there is no processing load of a command signal for requesting lighting control, and command processing for address setting can be performed reliably.
Furthermore, when the control unit recognizes a specific lighting fixture to which individual address assignment is performed under the address setting priority mode, the control unit and the lighting fixture interrupt the address setting operation and can set an arbitrary address number. Since the setting standby state is set, the address number desired by the setting operator can be assigned to a specific lighting fixture..
[0112]
  Claim2The invention of the address setting method of the lighting control system of claim1In the invention, the arbitrary address number is determined by operation of the operating device, and information on the determined address number is transmitted from the operating device to the lighting device by an optical signal, so that the lighting device in the address waiting state is sent to the lighting device. Since individual address assignment is performed, the setting operator can directly assign a desired address number to a specific lighting fixture using an operating device, for example, an address number associated with the installation location of the lighting fixture can be assigned. Thus, maintenance management of the lighting control system is also facilitated.
[0113]
  Claim3The invention of the address setting method of the lighting control system of claim1In the present invention, when the individual address is not set, an insulating member for cutting off the electric path between the lighting device in the luminaire and the lamp load is provided, and the insulating member is removed when waiting for address setting, and the energization of the lamp load is started. Since the address setting operation is started in the lighting fixture, the setting operator can directly specify the individual lighting fixture that the address setting operation is to be started.
[0114]
  Claim4The invention of the address setting method of the lighting control system of claim1In this invention, the magnetic body is attached so as to be exposed on the surface of the luminaire, and at the time of address setting standby, an electromotive voltage change caused by a change in magnetic permeability caused by another magnetic body approaching the magnetic body Since the address setting operation is started in the lighting fixture, the setting operator can directly specify the individual lighting fixture that the address setting operation is to be started.
[0116]
  Claim5The invention of the luminaire is the above-mentioned claim.1Address setting method of lighting control systemTo the lawSince it is a lighting fixture used, it is provided with a display means for visually displaying that address setting standby and address setting are completed, and a control means for controlling the operation of the display means. It is possible to visually confirm that the address setting standby and address setting of the lighting fixture have been completed.
[0117]
  Especially claims6The invention of the lighting apparatus is claimed in claim5In this invention, the display means is a lamp load, and the control means is provided with a lighting control means for blinking lighting or dimming lighting, so that the lamp load provided in the lighting fixture can be used as it is as the display means.
[0118]
  And claims7The invention of the lighting apparatus is claimed in claim5In the invention, the display means is composed of a lamp that moves upward and downward with an auto-lifter device, and when the address setting standby and address setting are completed as a control means, the auto-lifter device is operated to move the lamp up and down. Therefore, in a lighting fixture that is moved up and down by the auto-lifter device, the auto-lifter device can be used as display means as it is.
[0119]
  Claim8The invention of the lighting apparatus is claimed in claim5In the invention, a lighting control unit that uses a high-intensity discharge lamp as a lamp load, includes a light compensation light source, uses the light compensation light source as the display unit, and lights the light compensation light source when address setting standby and address setting are completed. Therefore, the light compensation light source attached to the luminaire using the high-intensity discharge lamp can be used as the display means as it is.
[Brief description of the drawings]
FIG. 1 of the present inventionBasic1 is a system configuration diagram of form 1. FIG.
FIG. 2 is a front view of the operating device used in the above.
FIG. 3 is a format explanatory diagram of a lamp lighting command signal used in the above.
FIG. 4 is a circuit configuration diagram showing an example of a lighting device for a lighting fixture used in the above.
FIG. 5 shows the present invention.BasicIt is a system configuration | structure figure of the form 2.
FIG. 6 is a circuit configuration diagram of a control unit used in the above.
FIG. 7 is a circuit configuration diagram of a lighting fixture used in the above.
FIG. 8 is a circuit configuration diagram of an operating device used in the above.
FIG. 9 is an operation explanatory view of the control unit and the lighting fixture under the address setting priority mode same as above.
FIG. 10 shows an embodiment of the present invention.1It is a front view of the operation device used for.
FIG. 11 is an operation explanatory diagram of the control unit and the lighting fixture under the address setting priority mode same as above.
FIG. 12 is a bottom view of an example of a lighting fixture used in the above.
FIG. 13 is a side view of another example of the lighting fixture used in the above.
FIG. 14 is a side sectional view of another example of the lighting fixture used in the above.
FIG. 15 is a diagram illustrating an example of address setting for the lighting apparatus according to the above.
FIG. 16 shows an embodiment of the present invention.2It is a circuit block diagram of an example of the lighting fixture used for.
FIG. 17 is a circuit configuration diagram of an operating device used in the above.
FIG. 18 is a front view of an operating device used in the above.
FIG. 19 is a main part configuration diagram of another example of the lighting fixture used in the above.
FIG. 20 is a circuit configuration diagram of another example of the lighting fixture used in the above.
FIG. 21 is a perspective view of another example of the lighting fixture used in the above.
FIG. 22 is a circuit configuration diagram of another example of the lighting fixture used in the above.
FIG. 23 shows an embodiment of the present invention.3FIG.
FIG. 24 is an explanatory diagram of address setting for the luminaire to be added same as above.
FIG. 25 is a system configuration diagram of a conventional example.
FIG. 26 is a flowchart up to the determination of the individual address of the terminal device.
FIG. 27 is a system configuration diagram of another conventional example.
FIG. 28 is a flowchart up to the determination of the individual address of the terminal device.
FIG. 29 is an explanatory diagram of a relationship between a search value of a search command signal used in the above and a temporary address.
FIG. 30 is an example of address setting in the same as above.
FIG. 31 is a system configuration diagram of another conventional example.
FIG. 32A is a circuit configuration diagram of a control device used in the above.
  (B) is a circuit configuration diagram of the controller used in the above.
FIG. 33 is a circuit configuration diagram of a terminal device and an interface used in the above.
FIG. 34 is a flowchart for explaining address setting as described above.
[Explanation of symbols]
1 Control unit
2 lighting equipment
3 signal lines
4 controller
10 Control unit
11 Signal transceiver
20 Control unit
21 Signal transmitter / receiver
22 Memory unit
23 Lighting device
40 Operation switch section
41 Signal generator
La lamp load

Claims (8)

A plurality of lighting fixtures and one or a plurality of control units that output command signals for lighting control and function setting of the lighting fixtures are connected on the same signal line, and a signal line is connected between the lighting fixtures and the control unit. In the address setting method used in the lighting control system in which bidirectional communication is performed and the lighting fixture is controlled by a command signal addressed to its own address sent from the control unit, when assigning an individual address to the lighting fixture, When the address setting request command signal is transmitted from at least one of the control unit or the lighting fixture and the address setting request command signal is received on the other side, the control unit and the lighting fixture are set to operate in the address setting priority mode in which the address setting has priority. migrated, the address setting priority mode Under the control mode, the control unit and the lighting fixture perform signal processing and operation only on the command signal for address setting, and do not perform signal processing and operation on the command signal that requests the lighting control of the lamp load. When the unit recognizes a specific lighting fixture for performing individual address assignment, the control unit and the lighting fixture interrupt an address setting operation and set an address setting standby state in which an arbitrary address number can be set. Address setting method for lighting control system. The arbitrary address number is determined by the operation of the operating device, and the information of the determined address number is transmitted from the operating device to the lighting device by an optical signal, thereby assigning the individual address to the lighting device in the address standby state. address setting method of lighting control system of claim 1, wherein the performing. In the state where the individual address is not set, an insulating member is provided that cuts off the electric path between the lighting device in the lighting fixture and the lamp load, and the start of energization to the lamp load is detected by removing the insulating member when waiting for address setting. The address setting method of the lighting control system according to claim 1, wherein an address setting operation is started in the lighting fixture . A magnetic body is attached so as to be exposed on the surface of the lighting fixture, and a change in electromotive voltage caused by a change in magnetic permeability caused when another magnetic body is brought close to the magnetic body is detected during address setting standby. The address setting method of the lighting control system according to claim 1 , wherein an address setting operation is started in the lighting fixture . A lighting apparatus used in the address setting method of the lighting control system according to claim 1, wherein the display unit visually displays that the address setting standby and the address setting are completed, and the control for controlling the operation of the display unit. luminaire, characterized in that it comprises a means. 6. The lighting apparatus according to claim 5, wherein the display means is a lamp load, and the lighting means is a blinking lighting or dimming lighting as the control means. The display means is composed of a lamp that moves upward and downward with an auto-lifter device, and comprises a means for operating the auto-lifter device to move the lamp up and down when address setting standby and address setting are completed as a control means. The lighting fixture according to claim 5, wherein A high-intensity discharge lamp is used as a lamp load, a light compensation light source is provided, a light compensation light source is used as the display means, and lighting control means for turning on the light compensation light source when address setting standby and address setting are completed is provided. The lighting fixture according to claim 5.

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