JP6824048B2 - Floodlight circuit - Google Patents

Description

The present invention relates to a floodlight circuit that projects light in an intermittent cycle.

Conventionally, for example, in a production line in an automobile factory, a photoelectric sensor has been used to detect a vehicle body flowing on a belt conveyor. This photoelectric sensor irradiates light (visible light, infrared light, etc.) from the light projecting circuit and receives the light in the light receiving circuit to detect the vehicle body (detection target) that has entered between the paths of the irradiation light. (See, for example, Patent Document 1).

Here, in order to secure a distance from the detection target object or to increase the degree of freedom in the size and shape of the detection target object, the photoelectric sensor is always required to have long-distance detection performance. Here, long-distance detection is possible by increasing the amount of light during irradiation, but there is a limit to the amount of current supplied to the LED from the viewpoint of reliability of the LED used in the floodlight circuit. Further, since the photoelectric sensor is required to have a small housing, it is not possible to irradiate using a plurality of LEDs as in a lighting fixture. Therefore, usually, the projected light signal given to the LED is used as an intermittent signal, and the current supplied to the LED is strengthened for a short time to satisfy the allowable power value. Then, in the light receiving circuit, sensing is performed by integrating or demodulating the received minute intermittent signal by internal signal processing.

Japanese Unexamined Patent Publication No. 2005-257531

On the other hand, in general, the floodlight circuit and the light receiving circuit are easily affected by temperature. In particular, the light receiving circuit amplifies a minute photocurrent several thousand times to several hundred thousand times. Then, in order to determine the presence or absence of the object to be detected based on the signal level after reception, not only the temperature stability at the time of projecting light but also the temperature stability in the light receiving circuit is important. Further, as a problem peculiar to the photoelectric sensor, the influence of internal heat generation is large because of the small housing. In particular, in a reflection type photoelectric sensor in which the light emitting circuit and the light receiving circuit are provided in the same housing, the influence of internal heat generation is remarkable.

That is, a floodlight circuit that requires high output becomes a heating element, and a light receiving circuit that amplifies a minute signal is easily affected by the heating element. In particular, since the internal temperature of the device is not constant when the power is turned on, the floodlight circuit and the light receiving circuit may malfunction.

Therefore, conventionally, the warm-up operation is performed for several hours after the power is turned on. However, in this case, it is necessary to stop the production line until the photoelectric sensor operates stably, which leads to a decrease in productivity. For example, even if the production line is restarted after the production line is stopped for a reason other than the photoelectric sensor, production cannot be resumed until the internal temperature of the photoelectric sensor stabilizes, which affects the production schedule. I will give it.
Therefore, it has been desired to shorten the time until the photoelectric sensor becomes usable after the power is turned on.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a floodlight circuit capable of shortening the time required for the floodlight circuit to become usable after the power is turned on.

The light projecting circuit according to the present invention includes a light projecting unit that projects light, a drive circuit that drives the light projecting unit, a temperature measuring unit that measures the internal temperature, and a first unit that determines whether a predetermined time has elapsed. The judgment unit, the second judgment unit that determines whether the change in the internal temperature measured by the temperature measurement unit is within the specified temperature range, and the second judgment unit determine that the change in the internal temperature is larger than the specified range. a control unit for operating the first determination unit when, if a change in the internal temperature is determined to be larger than the specified range by the second judgment unit, Rukoto to operate the driving circuit first discontinuous cycle or continuously When it is determined by the first determination unit that the specified time has elapsed, the drive circuit is operated in the second intermittent cycle to project the light onto the projection unit. and a switching unit for light, the first intermittent cycle is characterized by a short cycle for the second intermittent cycles.

According to the present invention, since it is configured as described above, it is possible to shorten the time required for the floodlight circuit to become usable after the power is turned on.

It is a figure which shows the structural example of the floodlight circuit which concerns on Embodiment 1 of this invention. It is a figure which shows the operation example of the floodlight circuit which concerns on Embodiment 1 of this invention. 3A and 3B are diagrams for explaining the effect of the floodlight circuit according to the first embodiment of the present invention, and FIG. 3A is a diagram showing a drive cycle and an internal temperature in the conventional floodlight circuit. FIG. 3B is a diagram showing a drive cycle and an internal temperature in the floodlight circuit according to the first embodiment. It is a figure which shows the structural example of the floodlight circuit which concerns on Embodiment 2 of this invention. It is a figure which shows the structural example of the floodlight circuit which concerns on Embodiment 3 of this invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
Embodiment 1.
FIG. 1 is a diagram showing a configuration example of a floodlight circuit according to a first embodiment of the present invention.
As shown in FIG. 1, the light projecting circuit includes an LED (light projecting unit) 1, a drive circuit 2, a temperature measuring unit 3, a judgment circuit 4, a boost signal supply source 5, an intermittent signal supply source 6, and a switch 7. ing. Further, the determination circuit 4 has a first determination unit 41, a second determination unit 42, and a control unit 43.

LED1 casts light.
The drive circuit 2 drives the LED 1.
The temperature measuring unit 3 is an analog circuit that measures the internal temperature. Since the LED 1 is the main heating element in the floodlight circuit, the temperature measuring unit 3 measures the ambient temperature of the LED 1 as the internal temperature. On the other hand, since the floodlight circuit is configured in a minute housing, the temperature measuring unit 3 may be provided in the housing. The temperature measured by the temperature measuring unit 3 may be a temperature at which the amount of change can be known, and does not have to be an absolute temperature.

The first determination unit 41 determines whether or not the specified time has elapsed.
The second determination unit 42 determines whether the change in the internal temperature measured by the temperature measurement unit 3 is within the specified temperature range.
The control unit 43 operates the first determination unit 41 when the power is turned on or when the second determination unit 42 determines that the change in the internal temperature is larger than the specified range, and the first determination unit 41 determines the specified time. The second determination unit 42 is operated when it is determined that the above has passed. Further, when the second determination unit 42 determines that the change in the internal temperature is larger than the specified range, the control unit 43 sets the specified time to be used by the first determination unit 41 according to the amount of change in the internal temperature. You may.

The boost signal supply source 5 outputs a boost signal which is the first intermittent cycle or a continuous boost signal. The first intermittent cycle is a shorter cycle than the second intermittent cycle described later.
The intermittent signal supply source 6 outputs an intermittent signal which is a second intermittent cycle. The intermittent signal is the same as the intermittent signal in the prior art.

The switch 7 switches the output to the drive circuit 2 to a boost signal from the boost signal supply source 5 or an intermittent signal from the intermittent signal supply source 6 based on the determination result by the determination circuit 4. Here, the switch 7 outputs a boost signal to the drive circuit 2 when the power supply is turned on or when the determination circuit 4 determines that the change in the internal temperature is larger than the specified temperature range. Further, the switch 7 outputs an intermittent signal to the drive circuit 2 when the determination circuit 4 determines that the specified time has elapsed.

The boost signal supply source 5, the intermittent signal supply source 6, and the switch 7 are described as "when the power is turned on or when the second determination unit 42 determines that the change in the internal temperature is larger than the specified temperature range. , A switching unit that operates the drive circuit 2 in the first intermittent cycle or continuously, and operates the drive circuit 2 in the second intermittent cycle when the first determination unit 41 determines that the specified time has elapsed. " To configure.

Next, an operation example of the floodlight circuit configured as described above will be described with reference to FIG.
In the floodlight circuit, when the power supply is turned on, the switch 7 outputs a boost signal to the drive circuit 2. Then, the drive circuit 2 operates in the first intermittent cycle or continuously according to the boost signal to drive the LED 1 (boost period).
In this way, when the power is turned on, the interval between intermittent operations is narrowed with respect to the normal cycle to promote a rapid temperature rise and shorten the warm-up operation time. The boost signal is appropriately designed so as to satisfy the allowable power value of the LED 1.

On the other hand, the determination circuit 4 determines whether a predetermined time (T in FIG. 2) has elapsed after the power supply is started. Then, when the determination circuit 4 determines that the predetermined time has elapsed, the switch 7 switches so as to output an intermittent signal to the drive circuit 2. Then, the drive circuit 2 operates in the second intermittent cycle in response to the intermittent signal to drive the LED 1 (normal cycle period).

Then, the determination circuit 4 determines whether the change in the internal temperature measured by the temperature measuring unit 3 is within the specified temperature range. At this time, the determination circuit 4 determines, for example, whether the change in the internal temperature within a predetermined period is within the range of ± 1 ° C.

Here, when the determination circuit 4 determines that the change in the internal temperature is larger than the specified temperature range, the switch 7 switches to output the boost signal to the drive circuit 2 again. Then, the drive circuit 2 operates in the first intermittent cycle or continuously according to the boost signal to drive the LED 1 (boost period).
That is, when the change in the internal temperature is larger than the specified temperature range, the internal temperature is not stable, so the warm-up operation is performed again by narrowing the interval of the intermittent operation with respect to the normal cycle. Further, in FIG. 2, the control unit 43 shortens the specified time used by the first determination unit 41 by t1 from T according to the amount of change in the internal temperature. After that, the above operation is repeated.

On the other hand, when the determination circuit 4 determines that the change in the internal temperature is within the specified temperature range, the switch 7 continues to output the intermittent signal to the drive circuit 2. That is, when the change in the internal temperature is within the specified temperature range, the internal temperature is stable, so that the normal cycle is maintained.

In this way, in the floodlight circuit that originally performs intermittent operation to ensure reliability, by narrowing the interval of intermittent operation when the power is turned on, as shown in FIG. 3, the intermittent cycle is constant as compared with the conventional configuration. It is possible to promote a rapid temperature rise, and as a result, the warm-up operation time can be shortened. FIG. 3B shows a case where LED1 is continuously operated at startup. As a result, even when the photoelectric sensor provided with the floodlight circuit is used in the production line, the down time of the production line can be shortened. The photoelectric sensor may be a reflective type or a transmissive type.
Also, the length of warm-up time is proportional to the length of the intermittent cycle of the boost signal. For example, when a photoelectric sensor is used in a production line for flowing frozen foods, it is difficult to warm up because the surroundings are cold. Therefore, in this case, the intermittent cycle is shortened.

Further, in the floodlight circuit according to the first embodiment, after the lapse of the specified time, if the change in the internal temperature is large, the boost period and the normal cycle period are repeated, so that even if the temperature at which the internal temperature becomes stable is unknown. , Becomes applicable.

As described above, according to the first embodiment, the LED 1 that emits light, the drive circuit 2 that drives the LED 1, the temperature measuring unit 3 that measures the internal temperature, and the determination time have passed. The change in the internal temperature is defined by the first judgment unit 41, the second judgment unit 42 that determines whether the change in the internal temperature measured by the temperature measurement unit 3 is within the specified temperature range, and the second judgment unit 42. When the control unit 43 that operates the first determination unit 41 when it is determined to be larger than the range and the second determination unit 42 determine that the change in the internal temperature is larger than the specified range, the drive circuit 2 is first. The first intermittent cycle is provided with a switching unit for operating the drive circuit 2 in the second intermittent cycle when the first determination unit 41 determines that the specified time has elapsed. Since the cycle is configured to be shorter than the second intermittent cycle, the time required for the floodlight circuit to become usable after the power is turned on can be shortened. As a result, when the photoelectric sensor provided with the floodlight circuit is used in the production line, the start-up time of the production line can be shortened, so that the productivity can be expected to be improved.

Embodiment 2.
In the first embodiment, the configuration when the temperature at which the internal temperature stabilizes is not known is shown. On the other hand, the second embodiment shows a configuration in which the time from the start-up until the internal temperature stabilizes is known.
FIG. 4 is a diagram showing a configuration example of a floodlight circuit according to a second embodiment of the present invention. The floodlight circuit according to the second embodiment shown in FIG. 4 removes the temperature measuring unit 3 from the floodlight circuit according to the first embodiment shown in FIG. 1, and determines the determination circuit 4 and the switch 7. It has been changed to 4b and switch 7b. Other configurations are the same, and the same reference numerals are given and the description thereof will be omitted.

The determination circuit 4b has a determination unit 41b and a control unit 43b.
The determination unit 41b determines whether the predetermined time has elapsed.
The control unit 43b operates the determination unit 41b when the power supply is turned on.

When the power supply is turned on, the switch 7b outputs an intermittent signal to the drive circuit 2 to operate the drive circuit 2 in the first intermittent cycle or continuously. Further, when the determination unit 41b determines that the specified time has elapsed, the switch 7b outputs a boost signal to the drive circuit 2 and operates the drive circuit 2 in the second intermittent cycle.
The specified time used by the determination unit 41b is the time from the start to the time when the internal temperature reaches a stable temperature by outputting the boost signal to the drive circuit 2 by the switch 7b.

The boost signal supply source 5, the intermittent signal supply source 6, and the switch 7 "operate the drive circuit 2 in the first intermittent cycle or continuously when the power supply is started, and the determination unit 41b determines the specified time. A switching unit for operating the drive circuit 2 in the second intermittent cycle when it is determined that the above has passed is configured.

Next, an operation example of the floodlight circuit configured as described above will be described.
In the floodlight circuit, when the power supply is turned on, the switch 7b outputs a boost signal to the drive circuit 2. Then, the drive circuit 2 operates in the first intermittent cycle or continuously in response to the boost signal to drive the LED 1. In this way, when the power is turned on, the interval between intermittent operations is narrowed with respect to the normal cycle to promote a rapid temperature rise and shorten the warm-up operation time (boost period).

In the determination circuit 4b, it is determined whether or not a predetermined time has elapsed after the power supply is started. Then, when the determination circuit 4b determines that the predetermined time has elapsed, the switch 7b switches so as to output an intermittent signal to the drive circuit 2. Then, the drive circuit 2 operates in the second intermittent cycle in response to the intermittent signal to drive the LED 1 (normal cycle period).

As described above, in the floodlight circuit that originally performs the intermittent operation for ensuring reliability, the same effect as that of the first embodiment can be obtained by narrowing the interval of the intermittent operation when the power supply is started. Further, in the floodlight circuit according to the second embodiment, after the lapse of the specified time, it is determined that the internal temperature is stable, and the normal intermittent cycle period is entered. Therefore, the floodlight circuit according to the first embodiment can be simply configured.

Embodiment 3.
In the first embodiment, the configuration when the temperature at which the internal temperature stabilizes is not known is shown. On the other hand, in the third embodiment, the configuration when the temperature at which the internal temperature is stable is known is shown.
FIG. 5 is a diagram showing a configuration example of a floodlight circuit according to a third embodiment of the present invention. In the floodlight circuit according to the third embodiment shown in FIG. 5, the determination circuit 4 and the switch 7 are changed to the determination circuit 4c and the switch 7c with respect to the floodlight circuit according to the first embodiment shown in FIG. ing. Other configurations are the same, and the same reference numerals are given and the description thereof will be omitted.

The determination circuit 4c has a determination unit 42c and a control unit 43c.
The determination unit 42c determines whether the internal temperature measured by the temperature measurement unit 3 has reached the specified temperature. The specified temperature is a temperature at which the internal temperature becomes stable.
The control unit 43c operates the determination unit 42c when the power supply is turned on.

The switch 7c switches the output to the drive circuit 2 to a boost signal from the boost signal supply source 5 or an intermittent signal from the intermittent signal supply source 6 based on the determination result by the determination circuit 4c. Here, the switch 7c outputs a boost signal to the drive circuit 2 when the power supply is turned on. Further, the switch 7c outputs an intermittent signal to the drive circuit 2 when the determination unit 42c determines that the internal temperature has reached the specified temperature.

The boost signal supply source 5, the intermittent signal supply source 6, and the switch 7c "operate the drive circuit 2 in the first intermittent cycle or continuously when the power supply is started, and the determination unit 42c determines the temperature. When it is determined that the temperature has reached the limit, a switching unit for operating the drive circuit 2 in the second intermittent cycle is configured.

Next, an operation example of the floodlight circuit configured as described above will be described.
In the floodlight circuit, when the power supply is turned on, the switch 7c outputs a boost signal to the drive circuit 2. Then, the drive circuit 2 operates in the first intermittent cycle or continuously according to the boost signal to drive the LED 1 (boost period). In this way, when the power is started, the interval between intermittent operations is narrowed with respect to the normal cycle to promote a rapid temperature rise and shorten the warm-up operation time.

The determination circuit 4c determines whether the internal temperature measured by the temperature measuring unit 3 has reached the specified temperature after the power supply is started. Then, when the determination circuit 4c determines that the internal temperature has reached the specified temperature, the switch 7c switches so as to output an intermittent signal to the drive circuit 2. Then, the drive circuit 2 operates in the second intermittent cycle in response to the intermittent signal to drive the LED 1 (normal cycle period).

As described above, in the floodlight circuit that originally performs the intermittent operation for ensuring reliability, the same effect as that of the first embodiment can be obtained by narrowing the interval of the intermittent operation when the power supply is started.
Further, in the floodlight circuit according to the third embodiment, after reaching the specified temperature, it is determined that the internal temperature is stable, and the cycle shifts to the normal intermittent cycle period. Therefore, the floodlight circuit according to the first embodiment can be simply configured.

It should be noted that, within the scope of the invention, the present invention can be freely combined with each embodiment, modified from any component of each embodiment, or omitted from any component in each embodiment. ..

1 LED (light projector)
2 Drive circuit 3 Temperature measurement unit 4, 4b, 4c Judgment circuit 5 Boost signal supply source 6 Intermittent signal supply source 7, 7b, 7c Switcher 41 First judgment unit 41b Judgment unit 42 Second judgment unit 42c Judgment unit 43, 43b , 43c Control unit

Claims (4)

A light projecting unit that emits light,
The drive circuit that drives the light projecting unit and
A temperature measuring unit that measures the internal temperature and
The first judgment unit that judges whether the specified time has passed and
A second determination unit that determines whether the change in internal temperature measured by the temperature measurement unit is within the specified temperature range, and
A control unit that operates the first determination unit when the second determination unit determines that the change in internal temperature is larger than the specified range.
When the the second determination unit changes in the internal temperature is determined to be larger than the specified range, to project a light to the light projecting unit in Rukoto operates the drive circuit first discontinuous cycle or continuously When it is determined by the first determination unit that the specified time has elapsed, the drive circuit is operated in the second intermittent cycle to provide a switching unit for projecting light to the projection unit.
A floodlight circuit, wherein the first intermittent cycle is a shorter cycle than the second intermittent cycle. The claim is characterized in that the control unit sets the specified time according to the amount of change in the internal temperature when the second determination unit determines that the change in the internal temperature is larger than the specified range. 1. The floodlight circuit according to 1. A light projecting unit that emits light,
The drive circuit that drives the light projecting unit and
A judgment unit that determines whether the specified time has passed, and
A control unit that operates the judgment unit when the power is turned on,
When the power supply is activated, the drive circuit was projected light to the light projecting unit in the first discontinuous cycle or Rukoto is continuously operating, it is determined that the specified time by the determining unit has passed In this case, the drive circuit is provided with a switching unit that causes the light projecting unit to emit light by operating the drive circuit in the second intermittent cycle.
A floodlight circuit, wherein the first intermittent cycle is a shorter cycle than the second intermittent cycle. A light projecting unit that emits light,
The drive circuit that drives the light projecting unit and
A temperature measuring unit that measures the internal temperature and
A judgment unit that determines whether the temperature measured by the temperature measurement unit has reached the specified temperature, and
When the power supply is activated, the drive circuit is projecting a first light to the light projecting unit in Rukoto is operated intermittently cycle or continuously, is determined to have reached the specified temperature by the determination unit case, and a switching unit for projecting light to the light projecting unit by operating the light projecting said drive circuit in the second intermittent cycle,
A floodlight circuit, wherein the first intermittent cycle is a shorter cycle than the second intermittent cycle.

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