JP2010044950A - Fluorescent lamp monitoring system and wireless terminal for monitoring fluorescent lamp - Google Patents

Abstract

An illumination apparatus using an existing fluorescent lamp can be introduced without being changed, and the lighting state of a fluorescent lamp to be monitored installed in a remote place is monitored.
A power receiving terminal hole is provided for acquiring electric power from a pin terminal constituting a feed line between a rapid start type fluorescent lamp and a lighting device to which the fluorescent lamp is mounted. An optical sensor 4 that operates with the power acquired through the power receiving terminal hole 122 is provided to detect the operating state of the fluorescent lamp. A wireless transmission unit 6 that wirelessly transmits the detection result of the optical sensor 4 and the terminal ID for identifying the fluorescent lamp monitoring wireless terminal 1 to the management center is provided. The wireless transmission unit 6 operates with the power acquired through the power receiving terminal hole 122. The management center displays the received detection result of the optical sensor 4 and the position ID on the screen to grasp the state of the fluorescent lamp.
[Selection] Figure 1

Description

  The present invention relates to a fluorescent light monitoring system and a fluorescent light monitoring wireless terminal that can easily grasp the lighting state of a fluorescent light to be monitored installed in a remote place by using a wireless communication terminal. .

  There are many facilities that use fluorescent lamps for lighting equipment, such as houses, commercial facilities, and public facilities. However, as for the life of the fluorescent lamp, generally, the fluorescent lamp starts to blink, and when it is noticed, the facility manager or the like replaces the lamp.

  However, this method requires notification to the administrator etc. after the fluorescent lamp blinks and it is replaced with a new fluorescent lamp, which makes it difficult to respond quickly and hinders business operations. May give a bad impression to customers.

  In addition, as a monitoring device for lighting equipment in a large-scale facility, for example, communication is performed between the management center and lighting equipment such as fluorescent lamps installed at a plurality of remote locations. A method for monitoring whether or not each fluorescent lamp is abnormal has been proposed (see, for example, Patent Document 1).

  If the monitoring device for lighting equipment disclosed in Patent Document 1 is used, if any of a plurality of fluorescent lamps installed in a remote place is in a non-lighting state, the number of fluorescent lamps in a non-lighting state and The installation location can be grasped at the management center. Therefore, it is not necessary to go to the site where the lighting equipment is installed and check whether the lighting equipment is abnormal.

  Conventionally, there has been disclosed a technique for detecting the life of a fluorescent lamp or abnormal lighting at an early stage and enabling stable and stable lighting / dimming control of the discharge lamp (see, for example, Patent Document 2).

  In the technique disclosed in Patent Document 2, the fluorescent lamp is turned on by the fluorescent lamp lighting means, the light quantity of the fluorescent lamp is detected by the light quantity detection means using the light quantity sensor, and the light control is performed based on the detection result. A lighting signal for dimming control of the fluorescent lamp is generated by the duty control means. In addition, the tube current measuring means measures the tube current of the fluorescent lamp, and the abnormality detection means detects the lighting abnormality of the fluorescent lamp from the measurement result of the tube current measuring means. Is turned off, and the lighting means displays the lighting abnormality.

JP 2001-250698 A JP 2000-286089 A

  However, the above-described lighting equipment monitoring apparatus disclosed in Patent Document 1 has a complicated and large-scale system configuration, and can be implemented in a lighting equipment in a large-scale facility. There was a problem that could not be introduced.

  Further, although the technology disclosed in the discharge lamp driving device described in Patent Document 2 can be implemented in an image forming apparatus such as a copying machine, the disclosed technical means is used as it is in a house or the like. It is difficult to introduce it for monitoring fluorescent lamps.

  The present invention is intended to solve the problem of such a conventional configuration, can be introduced without changing the lighting equipment using the existing fluorescent lamp, and is installed in a remote place An object of the present invention is to provide a fluorescent lamp monitoring wireless terminal and a fluorescent lamp monitoring system capable of monitoring the lighting state of a target fluorescent lamp.

  In order to achieve the above object, a fluorescent lamp monitoring system according to the present invention includes a power receiving unit that acquires power from a feed line between a rapid start type fluorescent lamp and a lighting device to which the fluorescent lamp is mounted, and the power receiving unit. Detecting means comprising an optical sensor that operates with the power acquired in step S1 and detects the operating state of the fluorescent lamp; and communication means that operates with the power acquired by the power receiving means and transmits a detection result by the detecting means to the management center wirelessly. It is characterized by consisting of.

  Further, in order to achieve the above object, the fluorescent lamp monitoring system of the present invention is installed with respect to a lighting device having an illumination circuit for lighting a rapid start type fluorescent lamp and the fluorescent lamp to be monitored. A fluorescent lamp monitoring system including a fluorescent lamp monitoring wireless terminal and a management center wirelessly connected to the fluorescent lamp monitoring wireless terminal, wherein the fluorescent lamp monitoring wireless terminal is an installed fluorescent lamp. A light sensor for detecting the luminous intensity of the fluorescent light, a wireless transmission unit, and a control unit, and configured to acquire the power for operation from a pin terminal at one end of the fluorescent lamp. The sensor value is read, and the detection result is transmitted to the management center through the wireless communication unit. The management center receives the detection result first based on the received detection result of the optical sensor. The detection result of the optical sensor is stored as an initial value, and thereafter, the initial value and the current detection result of the optical sensor sent every predetermined time are compared to grasp the operating state of the fluorescent lamp. It is characterized by that.

  Furthermore, in order to achieve the above object, the fluorescent lamp monitoring wireless terminal according to the present invention is provided with a power receiving terminal hole which is inserted into a pin terminal at one end of a rapid start type fluorescent lamp and obtains electric power from the pin terminal. A substrate, a housing in which the mounting substrate is erected on a side end and attached integrally, a light sensor that is mounted with the detection surface exposed to the housing and detects the luminous intensity of the fluorescent lamp, and the interior of the housing A fluorescent light monitoring wireless terminal including a power supply unit housed in a wireless transmission unit and a control unit, wherein the mounting board is configured to receive the power receiving terminal hole when the power receiving terminal hole is inserted into the pin terminal. And the pin terminal are configured to support the housing in the vicinity of the tube surface of the fluorescent lamp, and the housing surrounds the detection surface of the optical sensor and has an opening. Funnel-shaped shield whose edge is in contact with the tube surface of the fluorescent lamp And the power supply unit is configured to supply power acquired through the power receiving terminal hole to the optical sensor, the wireless transmission unit, and the control unit, and the control unit includes a timer, and the timer The detection result of the optical sensor and the terminal ID for identifying the fluorescent lamp monitoring wireless terminal are transmitted to the management center through the wireless transmission unit based on the transmission cycle timed at (1).

  The fluorescent lamp monitoring system and the fluorescent lamp monitoring wireless terminal of the present invention can be introduced without changing existing lighting equipment, and can easily monitor the operating state of the fluorescent lamp. In addition, even in places where it is difficult to use telephone line facilities such as ceilings, the use of fluorescent light monitoring wireless terminals allows the management center to easily grasp the contents of abnormalities related to the lighting state of fluorescent lights. Therefore, the installation position of the fluorescent lamp can be easily grasped, and the on-site inspection confirmation work currently being performed becomes unnecessary.

  Furthermore, since the power for operation of the fluorescent lamp monitoring wireless terminal mounted on the lighting device is obtained from the pin terminal at one end of the fluorescent lamp, there is no need for wiring work or securing of a wiring space. In addition, since there are no restrictions due to wiring, it is possible to immediately install a wireless terminal for fluorescent lamp monitoring.

  Hereinafter, the best mode for carrying out the present invention will be described with reference to FIGS.

  FIG. 1A is a perspective view showing an embodiment of a fluorescent lamp monitoring wireless terminal according to the present invention, and FIG. 1B is a schematic configuration diagram showing a cross section of a main part of the fluorescent lamp monitoring wireless terminal. It is. FIGS. 2A and 2B are explanatory views showing a process of mounting the fluorescent lamp monitoring wireless terminal shown in FIG. 1A to the pin terminal at one end of the rapid start type fluorescent lamp.

  3A is an explanatory diagram showing an installation image of the fluorescent lamp monitoring system according to the present invention, and FIG. 3B is an explanatory diagram showing an example of a display screen of a detection result by a host computer installed in the management center. FIG. FIG. 4 is a flowchart showing the monitoring process of the fluorescent lamp monitoring wireless terminal of FIG. FIG. 5 is a flowchart showing the monitoring process of the management center in FIG.

  First, the fluorescent lamp monitoring wireless terminal 1 will be described with reference to FIGS. 1A and 1B and FIGS. 2A and 2B.

  The fluorescent lamp monitoring wireless terminal 1 is characterized in that the operating power of the fluorescent lamp monitoring wireless terminal 1 is changed between a rapid start fluorescent lamp 2 and an illumination device (not shown) to which the fluorescent lamp 2 is mounted. It is to acquire from the feeding line between.

  Specifically, in a lighting device that uses a rapid start type fluorescent lamp 2 with a straight tube shape, pin terminals 21 provided at both ends of the fluorescent lamp 2 are respectively inserted into sockets (not shown) provided on the lighting device side. The fluorescent lamp monitoring wireless terminal 1 of the present invention is configured to perform electrical connection and mechanical engagement, but the pin terminal 21 on one end side of the pin terminals 21 provided at both ends of the fluorescent lamp 2 is used. The power for operation is obtained from the system.

  As is well known, this rapid start type fluorescent lamp 2 is configured so that a small amount of current always flows through the filament when the power source of the fluorescent lamp 2 is in an on state. The power for operation of the fluorescent lamp monitoring wireless terminal 1 can be acquired from the pin terminal 21.

  Further, by adopting a configuration in which the fluorescent lamp monitoring wireless terminal 1 acquires power from the pin terminal 21, the fluorescent lamp monitoring wireless terminal 1 itself is turned on following the on / off operation of the fluorescent lamp 2. -Since an off operation is also performed, continuous operation is possible with the fluorescent lamp 2 mounted.

  As shown in FIGS. 1A and 1B, the casing 11 of the fluorescent lamp monitoring wireless terminal 1 is integrally formed of a silicon material having excellent weather resistance and heat resistance. Thus, since the housing | casing 11 is integrally molded with a silicon material, it also has waterproofness and can be used outdoors.

  Further, a shielding part 111 formed in a funnel shape is provided on the upper surface side of the housing 11. When the shielding portion 111 is in contact with the outer peripheral surface of the tube of the fluorescent lamp 2, the shielding portion 111 is formed in a funnel shape that spreads outward so as to become familiar with and come into close contact with the outer peripheral surface of the tube. Can be suppressed, dust-proofing of the optical sensor 4 to be described later, and erroneous measurement of the light intensity measurement value due to external light can be suppressed.

  In the housing 11, a power supply unit 3, an optical sensor 4, a control unit 5, and a wireless transmission unit 6 described later are provided.

  Further, the mounting substrate 12 is erected on one side end of the housing 11, and the upper end portion 121 is protruded higher than the uppermost portion of the shielding portion 111 and is integrally attached. In addition, two power receiving terminal holes 122 are provided in the upper end portion 121 of the mounting substrate 12.

  The two power receiving terminal holes 122 are made of conductive rubber, and are configured to be inserted and electrically connected to the pin terminal 21 of the fluorescent lamp 2 so as to obtain electric power from the pin terminal 21. The power acquired from the pin terminal 21 is wired so as to be supplied to the power supply unit 3 through the power supply line 123.

  Further, as shown in FIGS. 2A and 2B, the power receiving terminal hole 122 inserts the pin terminal 21 and receives power when the tip end portion of the pin terminal 21 is inserted and connected to the socket of the lighting device. The housing 1 is supported in the vicinity of the fluorescent lamp 2 by the mechanical engagement between the terminal hole 122 and the pin terminal 21. At this time, the mounting substrate 12 is mounted in a state of being sandwiched in a gap generated between the base portion 22 provided at the end of the fluorescent lamp 2 and the socket of the lighting device.

  The power supply unit 3 converts the AC voltage acquired from the pin terminal 21 through the power receiving terminal hole 122 and the power supply line 123 into a DC voltage, and is stable to the optical sensor 4, the control unit 5, and the wireless transmission unit 6. Supply power for operation.

  The optical sensor 3 is embedded in the upper surface of the housing 11 with the light receiving surface exposed. The optical sensor 3 is arranged on the inner bottom surrounded by the light shielding portion 111 and the mounting substrate 12 and is configured to detect the lighting state of the fluorescent lamp 2.

  The control unit 5 includes a timer, and after the fluorescent lamp 2 is turned on, the lighting state of the fluorescent lamp 2 is stabilized, for example, 30 minutes later, the measured value of the optical sensor 4 and the fluorescent lamp monitoring The terminal ID for identifying the wireless terminal 1 is transmitted to the management center 7 shown in FIG. Thereafter, based on the transmission cycle timed by the timer, the detection result of the optical sensor 4 and the terminal ID are periodically transmitted to the management center 7 through the wireless transmission unit 6. Further, even when the luminous intensity of the fluorescent lamp 2 is suddenly lowered, the abnormal value is controlled to be transmitted to the management center 7 together with the terminal ID.

  Next, the monitoring process of the fluorescent lamp monitoring wireless terminal 1 will be described based on the flowchart shown in FIG.

  First, the power source of the fluorescent lamp 2 is turned on (step S1). At the same time as the power is turned on, after the fluorescent lamp 2 is turned on, as a means for measuring whether or not the lighting state is sufficiently stable, the timer of the control unit 5 starts 30 minutes ( Step S2).

  After the timer of the control unit 5 is started, the light intensity value of the optical sensor 4 is read (step S3). Next, it is checked whether or not the light intensity value read by the optical sensor 4 is equal to or greater than a preset threshold value, that is, whether or not the fluorescent lamp 2 is in a lighting state (step S4).

  If it is determined in step S4 that the luminous intensity is equal to or less than the threshold value, the process proceeds to step S7 with “NO”, and the wireless transmission unit 6 transmits an abnormal value to the management center 7. On the other hand, if it is determined that the luminous intensity is equal to or greater than the threshold value, “YES”, the process proceeds to the next step S5, and it is confirmed whether the time counted by the timer started in step S2 has passed 30 minutes.

  If the timer has not yet counted 30 minutes at the time of step S5, the process returns to step S3 with “NO”, and the light intensity value of the optical sensor 4 is read again. As described above, the reason for returning to step S3 is that the fluorescent lamp 2 has been turned on shortly and the lighting state is not stable. Therefore, the light intensity value of the photosensor 4 read in the previous step S3 is This is because normal readings are not obtained.

  On the other hand, if the timer has counted 30 minutes, “YES”, the process proceeds to the next step S6, the normal reading value of the optical sensor 4 and the terminal ID are transmitted to the management center 7, and in step S2. Start the timer for 30 minutes again. As described above, in the fluorescent lamp monitoring wireless terminal 1 according to this embodiment, when the detection result is in a steady state, the detection result of the optical sensor 4 and the terminal ID are sent to the management center 7 once every 30 minutes. Is configured to send.

  Next, with respect to the fluorescent lamp monitoring system according to the present invention, an explanatory diagram showing an installation image of the fluorescent lamp monitoring system of FIG. 3A and a display screen of detection results by the host computer installed in the management center of FIG. This will be described based on an explanatory diagram showing an example.

  As shown in the overall configuration of the fluorescent lamp monitoring system in FIG. 3A, for example, a plurality of lighting devices are installed from the first floor to the third floor of a building. According to the example shown in FIG. 3A, on the first floor, there are two lighting devices “terminals” on which the rapid start type fluorescent lamp 2 having a straight tube shape and the above-described fluorescent lamp monitoring wireless terminal 1 are mounted. ID code A and B "are installed, and on the second floor, similarly, two lighting devices" terminals "equipped with a straight tube-type rapid start type fluorescent lamp 2 and the above-described fluorescent lamp monitoring wireless terminal 1 are installed. "ID code C and D" are installed, and similarly on the third floor, a lighting device "terminal ID code" equipped with a straight-tube rapid start fluorescent lamp 2 and the above-described fluorescent lamp monitoring wireless terminal 1 is installed. E and F "are installed.

  Furthermore, the management center 7 is installed on the second floor. The management center 7 processes, for example, a wireless reception terminal 71 that receives a detection information signal composed of the detection result of the optical sensor 4 and the terminal ID transmitted from the fluorescent lamp monitoring wireless terminal 1, and the received detection information signal. And a host computer 72 for displaying the screen.

  On the host computer 72 of the management center 7, a management list indicating which fluorescent lamp monitoring wireless terminal 1 having which terminal ID is attached to which fluorescent lamp 2 is installed at which position on which floor can be updated. Information stored in advance in the internal memory.

  Further, the management center 7 stores the detection information transmitted from each fluorescent lamp monitoring wireless terminal 1 in the internal memory, leaves the stored information in the management list as updatable history information, The lighting state of the fluorescent lamp 2 is displayed on the screen as shown in FIG.

  According to the screen display illustrated in FIG. 3B, three fluorescent lamps of “terminal ID codes A and B” installed on the first floor and “terminal ID code D” installed on the second floor. 2 is displayed as “OK” and is in a normal lighting state, and it can be confirmed that there is no problem. The fluorescent lamp 2 of “terminal ID code C” installed on the second floor is displayed as “abnormal”, and it can be confirmed that it is abnormally turned off or blinking.

  In addition, the fluorescent lamp 2 of “terminal ID code E” installed on the third floor is displayed as “life”, and the detection result by the optical sensor 4, that is, the luminous intensity becomes a predetermined threshold value or less, and “terminal ID code E It can be confirmed that the fluorescent lamp 2 is in the replacement period.

  Further, the fluorescent lamp 2 of the “terminal ID code F” lighting device installed on the third floor is displayed as “off”, and the lighting device installed in the “terminal ID code F” is turned off. I can confirm that. This “off” display indicates that transmission from the fluorescent lamp monitoring wireless terminal 1 that has acquired power from the fluorescent lamp 2 because the power to the lighting device of “terminal ID code F” is turned off, for example, When it stops for 30 minutes or more, it is configured to perform a turn-off notification display.

  Next, the monitoring process of the host computer 72 installed in the management center 7 configured as described above will be described based on the flowchart shown in FIG. In this flowchart, in order to make the explanation easy to understand, light transmitted from one fluorescent lamp monitoring radio terminal 1 among the fluorescent lamp monitoring radio terminals 1 attached to each of the fluorescent lamps 2 is transmitted. A process of receiving a detection information signal composed of the detection result of the sensor 4 and the terminal ID will be described.

  First, it waits for reception of a detection information signal consisting of the detection result of the optical sensor 4 and the terminal ID transmitted from the fluorescent lamp monitoring wireless terminal 1 attached to each fluorescent lamp 2 every 30 minutes (step S11). In the next step S12, it is confirmed whether or not a detection information signal has been received.

  If it is confirmed in step S12 that the detection information signal has not been received, the process proceeds to step S18 with “NO”. In this step S18, it is confirmed whether or not there is a reception record for 30 minutes or more. If 30 minutes have not passed, “NO” is returned to the reception standby state in step S11. If it is confirmed in step S18 that there is no reception record for 30 minutes or more, the process proceeds to "YES" in step S19. If no reception record is received for 30 minutes or more, it is determined that the fluorescent lamp 2 is turned off. Then, “OFF” is displayed on the screen of the host computer 72, and the process returns to the reception standby state in step S11.

  On the other hand, if it is confirmed in step S12 that the detection information signal has been received, the process proceeds to the next step S13 with “YES” to identify the terminal ID. Then, it progresses to step S14 and it is confirmed whether the detected value of the received optical sensor 4 is a normal reading value. In step S14, as a result of confirmation, the signal transmitted from the fluorescent lamp monitoring wireless terminal 1 indicates that the luminous intensity value read by the optical sensor 4 in step S7 in FIG. 4 is equal to or less than a preset threshold value. If it is "value transmission", the process proceeds to step S20 with "NO".

  In step S20, if the light intensity value read by the optical sensor 4 has already been set as an initial value, the initial value is cleared and “abnormal” is displayed on the screen of the host computer 72 (step S21). After that, a reception standby state of step S22 is entered. If the reception is confirmed again in step S23, the process returns to step S13 to identify the terminal ID. If reception is not confirmed in step S23, “abnormal” is continuously displayed on the screen of the host computer 72.

  If it is confirmed in step S14 that the received detection value of the optical sensor 4 is a normal reading value, that is, a normal reading value in step S6 in FIG. Check if the value is set. If the initial value is not set, “NO”, the process proceeds to step S24, and after setting the read value as the initial value, the fact that the fluorescent lamp 2 is in a normally lit state is displayed on the screen of the host computer 72. (Step S17).

  If it is confirmed in step S15 that the initial value is set, the process proceeds to step S16 to check whether or not the current read value is 70% or more of the initial value.

  If it is confirmed in this step S16 that the current reading value is 70% or more of the initial value, “YES” indicates that the fluorescent lamp 2 is normally lit on the screen of the host computer 72 ( Step S17). On the other hand, if it is confirmed that the current reading value is less than 70% of the initial value, the process proceeds to step S25, and after the initial value is cleared, the fluorescent lamp 2 is replaced on the screen of the host computer 72. “Life” indicating that the situation is required (step S26) is displayed, and the process returns to step S11 to prepare for the next reception.

  According to this embodiment described above, the quantitative life of the fluorescent lamp 2 can be sensed quickly and reported to the management center 7. Moreover, even if the fluorescent lamp 2 is blinked or unintentionally turned off, an automatic notification can be immediately made to the management center 7.

1 is a perspective view illustrating an embodiment of a fluorescent lamp monitoring wireless terminal according to the present invention and a schematic configuration diagram of a cross-section of a main part of the fluorescent lamp monitoring wireless terminal. It is explanatory drawing which shows the process in which the radio | wireless terminal for fluorescent lamp monitoring shown in FIG. 1 is mounted | worn with the pin terminal of the end of a rapid start type | mold fluorescent lamp. It is explanatory drawing which shows the installation image of the fluorescent lamp monitoring system which concerns on this invention, and explanatory drawing which shows the example of a display screen of the detection result by the host computer installed in the management center. It is a flowchart which shows the monitoring process of the wireless terminal for fluorescent lamp monitoring of FIG. It is a flowchart which shows the monitoring process of the management center of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Radio terminal for fluorescent lamp monitoring 11 Housing | casing 111 Shielding part 12 Mounting board 121 Upper end part 122 Power receiving terminal hole 123 Power supply line 2 Fluorescent lamp 21 Pin terminal 22 Base part 3 Power supply part 4 Optical sensor 5 Control part 6 Wireless transmission part 7 Management center 71 Wireless receiving terminal 72 Host computer

Claims (3)

A power receiving means for acquiring power from a feeding line between a rapid start type fluorescent lamp and a lighting device to which the fluorescent lamp is mounted;
Detection means comprising an optical sensor that operates with the power acquired by the power reception means and detects the operating state of the fluorescent lamp;
A communication unit that operates with the power acquired by the power reception unit and wirelessly transmits a detection result by the detection unit to a management center;
A fluorescent lamp monitoring system comprising: An illumination device having an illumination circuit for lighting a rapid start type fluorescent lamp;
A fluorescent light monitoring wireless terminal installed for the fluorescent light to be monitored;
A management center wirelessly connected to the fluorescent lamp monitoring wireless terminal;
A fluorescent lamp monitoring system comprising:
The fluorescent lamp monitoring wireless terminal includes an optical sensor that detects the luminous intensity of an installed fluorescent lamp, a wireless transmission unit, and a control unit, and acquires operating power from a pin terminal at one end of the fluorescent lamp. To configure
The control unit is configured to read the value of the optical sensor every predetermined time and transmit the detection result to the management center through the wireless communication unit,
The management center stores the detection result of the first received optical sensor as an initial value based on the received detection result of the optical sensor, and thereafter the current value of the optical sensor sent every predetermined time after the initial value. A fluorescent lamp monitoring system configured to grasp an operating state of the fluorescent lamp by comparing with a detection result. A mounting board provided with a power receiving terminal hole that is inserted into a pin terminal at one end of the rapid start type fluorescent lamp and acquires power from the pin terminal;
A case in which the mounting substrate is erected on the side end and attached integrally;
An optical sensor that exposes a detection surface to the housing and attaches it to detect the intensity of the fluorescent lamp; and
A fluorescent lamp monitoring wireless terminal comprising a power supply unit housed in the housing, a wireless transmission unit and a control unit,
The mounting board supports the casing in the vicinity of the tube surface of the fluorescent lamp by mechanical engagement between the power receiving terminal hole and the pin terminal when the power receiving terminal hole is inserted into the pin terminal. To configure
The casing is integrally provided with a funnel-shaped shielding portion that surrounds the detection surface of the optical sensor and whose opening edge portion contacts the tube surface of the fluorescent lamp,
The power supply unit is configured to supply the power acquired through the power receiving terminal hole to the optical sensor, the wireless transmission unit, and the control unit,
The control unit includes a timer, and transmits a detection result of the optical sensor and a terminal ID for identifying the fluorescent lamp monitoring wireless terminal to the management center through the wireless transmission unit based on a transmission cycle timed by the timer. A wireless terminal for fluorescent lamp monitoring, which is configured as described above.

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