KR102209139B1 - Light for insect breeding - Google Patents

Abstract

The present invention relates to lighting for an insect breeding cage comprising: a natural light lighting unit (110) installed in the insect breeding cage (10) and realizing light of natural light; and a controller (120) controlling the color temperature, and turning on and off of the natural light lighting unit (110) based on sunlight data for each season and time, so that the natural light lighting unit (110) realizes light of natural light. The present invention improves the lighting environment of the insect breeding cage for breeding Ptecticus tenebrifer by realizing the color temperature which changes from sunrise to sunset according to the altitude of sun indoors, thereby increasing the productivity of Ptecticus tenebrifer.

Description

Light for insect breeding}

The present invention relates to lighting for insect breeding, and more particularly, to lighting for insect breeding used in insect breeders for breeding Dongae etc.

Dongae is a beneficial insect that has excellent environmental purification ability and does not harm crops and humans at all because it feeds on animal meal and residual food. In addition, fecal soil from Dongae et al. generated during the waste decomposition process can be used as a raw material for fertilizer, and processed larvae can be converted into feed material, which is a future resource with abundant utilization.

In addition, Dongae et al. are attracting attention as feed protein, and research on using oil as a by-product as feed is ongoing. Unlike other animal fats, Dongae et al. oil is rich in lauric acid, which is a medium-chain fatty acid. Medium-chain fatty acids do not accumulate as body fat but are consumed as an energy source, and lauric acid is known to have antibacterial effects against harmful bacteria and viruses.

For the above reasons, in recent years, the breeding industry has grown in Dongae, etc. However, as breeding is not easy, research to increase productivity in Dongae, etc. is continued.

Registered Patent Publication No. 2166308 (registered on Oct. 8, 2020)

The present invention was conceived to solve the above problems, and an object of the present invention is to provide lighting for insect breeding to increase productivity to Dongae etc. by improving the lighting environment of insect breeders who breed Dongae etc. will be.

The lighting for insect breeding according to an embodiment of the present invention for solving the above problems is installed in the insect breeding house, and a natural light lighting unit that embodies the light of natural light and the natural light lighting unit realizes the light of natural light. And a controller for controlling the color temperature of the natural light lighting unit and lighting and turning off the natural light based on the data.

The natural light lighting unit is formed by arranging a plurality of LEDs on a substrate, and the plurality of LEDs includes a first LED having a color temperature of 2800 to 3000K, a second LED having a color temperature of 4000K, and a third LED having a color temperature of 5700K and a color temperature of 6500K. It includes a fourth LED having a and a fifth LED having a color temperature of 8000K ~ 10000K.

The controller is driven by a converter that converts AC power into DC power, a storage unit storing solar altitude and color temperature data for each season and time, and DC power, and is stored in the storage unit, and solar altitude and color temperature for each season and time period. And a controller configured to determine a color temperature corresponding to a current date and time from the data and transmit a driving control signal, and a constant current circuit configured to control on/off of the LED by receiving a driving control signal from the controller.

The constant current circuit includes constant current circuits 1 to 5 for controlling the first to fifth LEDs, respectively, and the first to fifth LEDs are plural.

The control unit selectively turns on and off the first to fifth LEDs, sequentially increasing and lowering the color temperature in the range of 2800K to 10000K, controlling the current of the first to fifth LEDs, turning on and off, The control unit is connected to a smartphone app and can be manually adjusted or automatically adjusted by an operator, and information data in which the control unit turns on and off the first to fifth LEDs may be stored in the smartphone app.

Alternatively, the natural light lighting unit is formed by arranging a plurality of LEDs on a substrate, and the plurality of LEDs includes a first LED having a color temperature of 2800 ~ 3000K and a second LED having a color temperature of 8000K ~ 10000K, and the controller A converter that converts AC power to DC power, a storage unit storing solar altitude and color temperature data for each season and time, and a DC power supply are supplied to the drive, and the current And a controller configured to determine a color temperature corresponding to a date and time and transmit a driving control signal, and a constant current circuit configured to control on/off of the LED and illuminance of the LED by receiving a driving control signal from the controller.

In addition, the constant current circuit includes a constant current circuit 1 and a constant current circuit 2 for controlling the first LED and the second LED, respectively, and the constant current circuit 1 controls the amount of current output supplied to the first LED to control the first LED and the second LED. 1 controls the color temperature of the LED, the constant current circuit 2 controls the amount of current output supplied to the second LED to control the illuminance of the second LED, the first LED and the second LED are plural, and the controller Is selectively turning on and off the first LED and the second LED, controlling color temperature and illuminance, increasing and lowering the color temperature sequentially in the range of 2800K to 10000K, controlling currents of the first LED and the second LED, Turns on and off, and the control unit is connected to a smartphone app and can be manually adjusted or automatically adjusted by the operator, and the information data that the control unit turns on and off the first and second LEDs is stored in the smartphone app. do.

In addition, the control unit turns on and off at 6 o'clock and turns off at 19:00 so that the first LED and the second LED are turned on and off to correspond to the outdoor environment of the spring equinox season, and at the 6 o'clock, only the first LED is turned on and the The second LED is turned off, and at 12 o'clock to 13, the first LED turns off and only the second LED turns on, and at 18 o'clock, the first LED turns on and the second LED turns off. A drive control signal is output to the constant current circuit 2.

The present invention can provide a pleasant breeding environment by changing the color temperature of the natural light lighting unit, can be freely controlled according to the environment by season, lighting and turning off can be controlled using a remote control or a smartphone, and productivity to Dongae lamps There is an effect that can create an increasing environment.

In addition, the present invention can control the color temperature of the natural light lighting unit and the lighting and turning off based on the sunlight data for each season and time. Accordingly, the present invention has the effect of increasing the productivity of Dongae lanterns by realizing the same effect as the outdoor environment of the vernal equinox season where productivity is highest by matching the natural light lighting unit with the color temperature of the sun in real time.

1 is a block diagram showing an insect breeder to which lighting for insect breeding is applied according to an embodiment of the present invention.
Figure 2 is a perspective view showing the lighting for insect breeding according to an embodiment of the present invention.
3 and 4 are photographs showing the color wavelength (color temperature) of the sun changing from sunrise to sunset depending on the altitude of the sun in the equinox season.
5 is a block diagram showing the lighting for insect breeding according to an embodiment of the present invention.
6 is a flowchart showing an example of a method of controlling lighting for insect breeding according to an embodiment of the present invention.
7 is a block diagram showing the lighting for insect breeding according to another embodiment of the present invention.
8 is a flowchart showing an example of a method of controlling lighting for insect breeding according to another embodiment of the present invention.
9 is a photograph showing the results of the first and second general lighting tests in Table 1.
10 is a photograph showing the results of testing the lighting for insect breeding, which is the third natural light lighting in Table 1.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing an insect breeder to which lighting for insect breeding is applied according to an embodiment of the present invention.

As shown in FIG. 1, the lighting 100 for insect breeding is installed in the insect breeder 10 for breeding insects. Insect breeder 10 is a place for breeding Dongae, etc.

Dongae is an insect belonging to the family Flies in the order Dongae et al., and is an insect that looks like a fly but does not cause any damage to humans. The larvae of Dongae et al. eat organic waste (food waste) and decompose, and the adult larvae of Dongae et al. become excellent feed for livestock, and the excrement of the larvae of Dongae et al. can be recycled as compost. In addition, it can be used as pet food and fishing bait by utilizing larvae of Dongae, etc., and it can be used as a cosmetic or pharmaceutical material using specific animal oils and antibacterial substances emitted from the larvae.

The insect breeder 10 may use a container or the like, and may install an insect screen on the entrance door 11 to prevent dislocation to Dongae.

In the insect breeding house 10, a multi-stage frame may be installed, and a breeding box 30 containing Dongae et al. in the multi-stage frame may be stacked. The breeding box 30 has a slope of a specific angle by using larva habits in the Dongae, etc. in the yonghwa stage starting to climb a specific angle, and a concave groove is formed in the rim so that the larva can be contained, and the larvae contained in the concave groove are separately Can be transferred to a crafted breeding room.

Insect breeding use lighting 100 embodies the real-time light of natural light so as to increase the productivity of the Dongae lamp contained in the breeding box 30 of the insect breeder 10. The real-time natural light is designed to reproduce the color temperature that changes from sunrise to sunset depending on the altitude of the sun indoors. In addition, the insect breeding lighting 100 matches the color temperature of the sun in real time to have the same effect as the outdoor environment of the vernal equinox season where productivity is highest.

Insect breeding lighting 100 may be installed in a plurality of the ceiling of the insect breeder 10, the angle can be adjusted. In the embodiment, the insect breeding lighting 100 is shown to use four, but the number is adjustable.

Figure 2 is a perspective view showing the lighting for insect breeding according to an embodiment of the present invention.

As shown in FIG. 2, the lighting 100 for insect breeding applies LED lighting capable of real-time color temperature control. In addition, the insect breeding lighting 100 may apply an LED lighting capable of real-time color temperature control and brightness control for each color temperature.

In the embodiment, an LED lighting capable of real-time color temperature control is applied as an example. The color temperature is adjusted in the natural light range of 2800K to 10000K. Since the illuminance of nature is for expressing cloudy days, and the embodiment is for increasing productivity, it is preferable to express clear days. Therefore, although it is possible to implement the illuminance control for each color temperature, it is preferable not to consider it. However, the illumination gradually decreases from 30 minutes before the sunset time and turns off, and the illumination gradually increases for 30 minutes even at the sunrise time, and the maximum brightness is maintained after 30 minutes. This is to minimize the impact caused by sudden flashes and lights, so as not to distort the biorhythm of Dongae, etc.

Productivity to Dongae lamps is affected by color temperature, lighting and extinguishing methods, and season. As a result of the experiment, the productivity to Dongae lanterns is the best in the equinox season, and in particular, the lighting for insect breeding (100) gradually turns off at 19:00 and gradually turns on at 6 o'clock the next day, like the natural environment realized by the sun in the vernal equinox season. It has a good effect on biorhythm.

3 and 4 are photographs showing the color wavelength (color temperature) of the sun changing from sunrise to sunset depending on the altitude of the sun in the equinox season.

3 and 4, the sun of the vernal equinox season rises at 6 o'clock and sets at around 18 o'clock, and the sun's altitude is highest around 13 o'clock. The color temperature of the sun at the time the sun rises is 2800K (warm orange), similar to a candle. About 40 minutes after the sun rises, the color temperature of the sun becomes about 3000K (bright orange). Two hours after the sun rises, the color temperature of the sun becomes about 4000K (pale white), and after one more hour, the color temperature of the sun becomes about 5700K (white), and at noon (12 o'clock), the color temperature of the sun is 6500K. It is about (bright white), and in the afternoon (13:00), the color temperature of the sun becomes more than 7000K (blue white). In general, the color temperature of the sun is 7000K on a cloudy afternoon, 8000K on a clear afternoon, and over 10,000K on an exceptionally sunny afternoon.

Thereafter, at around 14 o'clock, as the sun's altitude decreases, the color temperature of the sun becomes about 6500K, around 15:00, the color temperature of the sun becomes 5700K, and around 17:00, the color temperature of the sun becomes 4000K, and at 18:00, the sun's color temperature becomes about 6500K. The color temperature of is in the range of 2800~3000K.

The amount of melatonin hormone secretion that activates the brain is affected by the color wavelength (color temperature) of the sun. When the secretion of melatonin hormone, including poultry, is improved, growth hormone is well secreted and productivity is improved.

Accordingly, it provides the lighting 100 for insect breeding that can reproduce the color temperature that changes from sunrise to sunset according to the altitude of the sun indoors.

The insect breeding lighting 100 provides a pleasant breeding environment according to the color temperature change, can be freely adjusted according to the environment for each season (spring, summer, autumn and winter), and the color temperature and lighting and turning off can be adjusted using a remote control or a smartphone. In addition, continuous experiments are possible for each test bed, and an environment for increasing productivity in Donge etc. can be created.

Again, as shown in FIG. 2, the lighting 100 for insect breeding is formed by arranging and installing a plurality of LEDs 112 on a circular substrate. Insect breeding lighting 100 is installed on the ceiling of the insect breeder 10, the angle can be adjusted. In the embodiment, the shape of the lighting 100 for insect breeding is formed in a circular shape to resemble the sun, but may be formed in a rectangular shape instead of a circular shape.

The plurality of LEDs 112 of the insect breeding lighting 100 implement a color temperature in the range of 2800K to 10000K, and the lighting and lighting times may be based on the spring equinox.

5 is a block diagram showing the lighting for insect breeding according to an embodiment of the present invention.

As shown in FIGS. 2 and 5, the insect breeding lighting 100 includes a natural light lighting unit 110 and a controller 120.

The natural light illumination unit 110 embodies natural light. The natural light illumination unit 110 has a shape in which a plurality of LEDs 112 are arranged and installed on a substrate 111. The plurality of LEDs 112 include a first LED 112a having a color temperature of 2800 to 3000K, a second LED 112b having a color temperature of 4000K, a third LED 112c having a color temperature of 5700K, and a fourth LED 112d having a color temperature of 6500K. It includes a fifth LED 112e with a color temperature of 8000K.

A plurality of the first LEDs 112a, the second LEDs 112b, the third LEDs 112c, the fourth LEDs 112d, and the fifth LEDs 112e are each provided, and may be mixed with each other. Alternatively, the first LED 112a, the second LED 112b, the third LED 112c, the fourth LED 112d, and the fifth LED 112e may be regularly arranged in a straight or circular shape on a circular substrate.

The first LED 112a, the second LED 112b, the third LED 112c, the fourth LED 112d, and the fifth LED 112e may be composed of a single color or a mixed color light emitting diode, and may emit a single color or a mixed color light emitting diode. The diode may be an RGB light emitting diode.

The controller 120 may control the color temperature of the natural light lighting unit 110 and lighting and turning off in real time based on solar data for each season and time so that the natural light lighting unit 110 implements natural light.

The controller 120 includes a converter 121, a storage unit 122, a control unit 123, and a constant current circuit 124.

The converter 121 converts AC power into DC power. The converter 121 receives AC power supplied from the outside, converts it into DC power, and supplies it to the controller 123. For example, the converter 121 may receive AC 220V power input from the outside, convert it to a constant DC voltage, and then supply the DC voltage to the controller 123.

The storage unit 122 stores solar data for each season and time. The data stored in the storage unit 122 can be modified and reset.

The controller 123 is driven by receiving DC power, and transmits a driving control signal by determining a color temperature corresponding to the current date and time from the solar data stored in the storage unit 122 for each season and time. Specifically, the control unit 123 is driven by receiving a DC voltage, and controlling the driving to the constant current circuit 124 by determining a color temperature corresponding to the current date and time from the seasonal and time-wise solar data stored in the storage unit 122 Can transmit signals. The controller 123 may be connected to the storage unit 122 to receive solar data for each season and time in real time.

The controller 123 may sequentially increase and decrease the color temperature in the range of 2800K to 10000K by selectively turning on and off any one of the first LEDs 112a to the fifth LEDs 112e. In addition, the control unit 123 may turn on and off the first to fifth LEDs 112a to 112e.

For example, the control unit 123 turns on the first LED (112a) at 06:00, turns off the first LED (112a) at 08:00 and turns on the second LED (112b), and at 09:00, the third LED ( 112c) is turned on and the second LED (112b) is turned off, and at 12 o'clock, the fourth LED (112d) is turned on and the third LED (112c) is turned off, and at 13:00, the fifth LED (112e) is turned on and 4 Turn off the LED 112d. In addition, the control unit 123 turns off the fifth LED (112e) at 14 o'clock and turns on the fourth LED (112d), at 15 o’clock, turns off the fourth LED (112d) and turns on the third LED (112c), At 17 o'clock, the third LED 112c is turned off and the second LED 112b is turned on. At 18 o'clock, the second LED 112b is turned off and the first LED 112a is turned on. In addition, the controller 123 turns off the first LED 112a at 19:00.

The constant current circuit 124 controls on/off of the LED 112 by receiving a driving control signal from the controller 123. Specifically, the constant current circuit 124 receives a driving control signal from the control unit 123 and controls the on-off of the first LEDs 112a to the fifth LEDs 112e. The constant current circuit 124 includes a constant current circuit 1 (124a) to a constant current circuit 5 (124e) for controlling the first LED (112a) to the fifth LED (112e), respectively.

The constant current circuit 124 can always keep the brightness of the natural light lighting unit 110 constant and stable with a stable power supply. The constant current circuit 124 may control on/off of the LED by controlling the amount of output current. The constant current circuit 124 may turn on the LED 112 by increasing the amount of output current and turn off the LED 112 by decreasing the amount of output current.

The control unit 123 is connected to the operator's smartphone app and can be manually adjusted by the operator. Information data in which the control unit 123 turns on and off the first to fifth LEDs 112a to 112e is stored in a smartphone app.

6 is a flowchart showing an example of a method of controlling lighting for insect breeding according to an embodiment of the present invention.

As shown in FIGS. 5 and 6, in the method of controlling the lighting for insect breeding, the lighting for insect breeding may be automatically turned on and off under the control of a controller. The control unit can create a comfortable environment for breeding in Dongae lamps by matching the color temperature according to the altitude of the sun and the color temperature of the natural light lighting unit.

The color temperature according to the altitude of the sun was set based on the sunny days of the equinox season.

When power is supplied to the insect breeding lighting by turning on the switch of the insect breeding lighting, the control unit can adjust the color temperature in five stages. The color temperature in step 5 may be adjusted by the first LEDs 112a to the fifth LEDs 112e.

In one example, the first step is implemented with a color temperature of 2800 to 3000K and the first LED is turned on. The second stage is implemented with a color temperature of 4000K and the second LED is turned on. The third stage is implemented with a color temperature of 5700K and the third LED is turned on. The fourth stage is 6500K, and the fourth LED is turned on and implemented. The 5th stage is 8000K~10000K, and the 5th LED is turned on and implemented.

When the power of the insect breeding lighting is turned on, the control unit checks the current time, and if the checked current time is between 06:00 and less than 08:00 or between 18:00 and less than 19:00, the first LED is turned on and the color temperature is 2800~3000K. Make it possible.

During this process, the control unit checks the current time in real time, and if the checked current time falls between 08:00 and less than 09:00 or between 17:00 and less than 18:00, the second LED is turned on so that the color temperature becomes 4000K.

In addition, the control unit turns on the third LED so that the color temperature becomes 5700K when the current time checked in real time falls between 09:00 and more than 12 hours or between 15:00 and less than 17:00. In addition, the controller turns on the fourth LED so that the color temperature becomes 6500K when the current time checked in real time falls between 12 o'clock and less than 13:00 or 14 o'clock and less than 15:00. In addition, the control unit turns on the 5th LED when the current time checked in real time is between 13:00 and less than 14:00 so that the color temperature is between 8000K and 10000K. Also, if the current time checked in real time is less than 06:00 or more than 19:00, the entire LED is turned off.

The above-described control method of lighting for insect breeding uses indoors to reproduce the color temperature that changes from sunrise to sunset depending on the altitude of the sun, and matches the color temperature of the real-time sun to create the same environment as the outdoor environment of the vernal equinox season, where productivity is highest. I can.

In another embodiment, the insect breeding lighting may be configured such that the color temperature changes naturally in response to the color temperature of sunlight according to the change of time.

7 is a block diagram showing the lighting for insect breeding according to another embodiment of the present invention.

As shown in FIG. 7, the lighting 100 ′ for insect breeding according to another embodiment includes a natural light lighting unit 110 ′ and a controller 120.

The natural light illumination unit 110' is composed of two types of LEDs. The natural light illumination unit 120 ′ includes a first LED 112a having a color temperature of 2800 to 3000K and a second LED 112b having a color temperature of 8000K to 10000K. The first LED 112a having a color temperature of 2800 to 3000K band represents orange, and the second LED 112b having a color temperature of 8000K to 10000K exhibits blue light.

A plurality of first and second LEDs 112a and 112b may be provided and may be mixed with each other.

The controller 120 may control the color temperature of the natural light lighting unit 110 ′, turning on and off, based on solar data for each season and time, so that the natural light lighting unit 110 ′ implements natural light. The controller 120 includes a converter 121, a storage unit 122, a control unit 123, and a constant current circuit 124'.

The converter 121 converts AC power into DC power. The storage unit 122 stores solar altitude and color temperature data for each season and time. The controller 123 is driven by receiving DC power, and transmits a driving control signal based on the solar altitude and color temperature data for each season and time period stored in the storage unit 122.

The constant current circuit 124 receives a driving control signal from the controller 123 and controls the LED on and off and the illumination of the LED. The constant current circuit 124' includes a constant current circuit 1 (124a) and a constant current circuit 2 (124b) for controlling the first LED (112a) and the second LED (112b), respectively.

The constant current circuit 1 (124a) may control the color temperature of the first LED (112a) by controlling the amount of current output supplied to the first LED (112a). The constant current circuit 2 (124b) may control the illuminance of the second LED (112b) by controlling the amount of current output supplied to the second LED (112b).

There may be a plurality of first and second LEDs 112a and 112b. The control unit 123 can selectively turn on and off the first LED 112a and the second LED 112b and control the color temperature and illuminance to increase and decrease the color temperature of the natural light 110' in the range of 2800K to 10000K in sequence. have. In addition, the controller 123 turns on and turns off the first LED 112a and the second LED 112b to turn on and off the natural light 110'.

The control unit 123 is connected to a smartphone app and can be manually adjusted or automatically adjusted by an operator.

The controller 123 may light up at 6 o'clock and turn off at 19:00 so that the first LED 112a and the second LED 112b are turned on and off to correspond to the outdoor environment of the spring equinox season. In addition, the control unit 123 may turn on only the first LED 112a and turn off the second LED 112b at 6 o'clock to implement a solar color temperature condition corresponding to the morning. In addition, the controller 123 may realize a solar color temperature condition corresponding to noon by turning off the first LED 112a and turning on only the second LED 112b from 12 o'clock to 13 o'clock.

In addition, the controller 123 may turn on the first LED 112a and turn off the second LED 112b at 18:00 to implement a solar color temperature condition corresponding to the evening.

The first LED 112a and the second LED 112b are turned on and off, and the color temperature and illuminance can be implemented by outputting a driving control signal to the constant current circuit 1 (124a) and the constant current circuit 2 (124b). .

8 is a flowchart showing an example of a method of controlling lighting for insect breeding according to another embodiment of the present invention.

7 and 8, in the control method of lighting for insect breeding according to another embodiment, the amount of current output is controlled by the constant current circuit 1 and the constant current circuit 2 receiving the driving control signal of the control unit. The operation to increase and decrease the color temperature sequentially in the range of 2800K to 10000K is performed.

In the process, the first LED 112a is turned on at 6 o'clock to show a color temperature of 2800K, and as time passes, the color temperature rises, such as 2801K, 2802K, and 2803K. This may be implemented by gradually increasing the amount of current supplied to the first LED 112a by the constant current circuit 1 124a receiving the driving control signal from the controller 123.

At about 08:00, when the first LED 112a reaches a color temperature of 2900K, the second LED 112b turns on and a color temperature of 10000K with a low illuminance appears. A color temperature of 10000K with low illuminance and a color temperature of 2900K are mixed to achieve a color temperature corresponding to the color temperature of the sun around 08:00.

Thereafter, the color temperature of the first LED 112a gradually increases to 3000K, and the illuminance of the color temperature of the second LED 112b gradually increases. This may be implemented by gradually increasing the amount of current supplied by the constant current circuit 1 (124a) and the constant current circuit 2 (124b) to the first LED (112a) and the second LED (112b).

When the color temperature of the first LED 112a reaches 3000K around 10 o'clock, the illuminance of the color temperature of the second LED 112b is also higher than before. At noon, the first LED 112a is turned off, and the amount of current supplied to the second LED 112b is maximized. Thereafter, until 13:00, the first LED 112a is turned off, and the amount of current supplied to the second LED 112b is maximized to maintain a color temperature of 10000K.

After 13 o'clock, the first LED 112a is turned on and the amount of current supplied to the first LED 112a is gradually lowered so that the color temperature of the first LED 112a is gradually lowered. In this process, the amount of current supplied to the second LED 112b is also gradually lowered so that the illuminance of the color temperature of the second LED 112b is lowered.

Specifically, the constant current circuit 1 gradually lowers the amount of current supplied to the first LED 112a so that the first LED 112a has a color temperature of 2800K at around 18:00. In addition, the constant current circuit 2 gradually lowers the amount of current supplied to the second LED 112b to lower the illuminance, and stops supplying current to the second LED 112b at around 18 o'clock and turns off the second LED 112b.

And, at 19:00, the first LED 112a is turned off, so that both the first LED 112a and the second LED 112b remain turned off. The above-described process is repeated every 24 hours to form a cycle of color temperature indicated by the movement of the sun.

Other embodiments may have a more positive effect on the breeding of insects because the color temperature of natural light lighting changes naturally similar to the sun when compared to the above-described embodiments.

Hereinafter, the operation of the present invention will be described through an experiment.

Table 1 is a result of testing the lighting for insect breeding, which is a natural light lighting according to another embodiment of the present invention, FIG. 9 is a photograph showing the results of the first and second general lighting tests of Table 1, and FIG. 10 is This is a picture showing the results of testing the 3rd natural light lighting for insect breeding.

Test schedule Lighting type Color temperature How to turn on and turn off Primary
20/05 150W/2 lights 6500K 19 o'clock lights 06 o'clock lights
(Manual turn on and off) Secondary
20/06 150W/3 lights 5700K Turns off at 19:00 and turns on at 6:00
(Manual turn on and off) 3rd
20/08 150W/2 lights Natural light
2800~10000K Turns off at 19:00 and turns on at 6:00
(Automatic turn on/off)

According to Table 1 and FIG. 9, as a result of the first and second tests, it was confirmed that the shock caused by a sudden change in illuminance during manual switching on and off had an effect on the biorhythm of Dongae, etc., and the productivity to Dongae was not good.

According to Table 1 and FIG. 10, as a result of the third test, it was confirmed that productivity was improved because the sun in the spring equinox season was gradually turned off at 19:00 and gradually turned on at 06:00 the next day, which had a good effect on the biorhythm. do.

From the above test results, it is confirmed that the productivity of Dongae lamps is affected by color temperature, lighting and lighting methods.

Therefore, it controls the color temperature of the natural light lighting unit and the lighting and turns off based on the sunlight data for each season and time period. It can be seen that the back can be mass-proliferated indoors.

The above-described lighting for insect breeding can be applied not only to breeding in Dongae, but also to breeding other insects to increase productivity.

In the above, preferred embodiments of the present invention have been illustrated and described, but the present invention is not limited to the specific embodiments described above, and is generally used in the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the claims. Of course, various modifications may be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or prospect of the present invention.

10: Insect breeder 11: Entrance door
20: multistage frame 30: breeding box
100: insect breeding lighting 110: natural light lighting unit
111: substrate 112: LED
112a: first LED 112b: second LED
112c: 3rd LED 112d: 4th LED
112e: fifth LED 120: controller
121: converter 122: storage unit
123: control unit 124: constant current circuit
124a: constant current circuit 1 124b: constant current circuit 2
124c: constant current circuit 3 124d: constant current circuit 4
124e: constant current circuit 5

Claims (2)

A natural light lighting unit installed in an insect breeding house and implementing natural light; And
A controller for controlling the color temperature of the natural light lighting unit and lighting and turning off the natural light based on solar data for each season and time, so that the natural light lighting unit implements natural light;
Including,
The natural light lighting unit
It is formed by arranging and installing a plurality of LEDs on the substrate,
The plurality of LEDs
A first LED having a color temperature of 2800 to 3000K; And
A second LED having a color temperature of 8000K to 10000K;
Including,
The controller is
A converter that converts AC power into DC power;
A storage unit storing solar altitude and color temperature data for each season and time period;
A control unit for receiving and driving DC power, determining a color temperature corresponding to a current date and time from the solar altitude and color temperature data stored in the storage unit for each season and time, and transmitting a driving control signal; And
A constant current circuit for receiving a driving control signal from the controller and controlling the LED on and off and the illumination of the LED;
Including,
The constant current circuit is
Including a constant current circuit 1 and a constant current circuit 2 for respectively controlling the first LED and the second LED,
The constant current circuit 1 controls a color temperature of the first LED by controlling an amount of current output supplied to the first LED,
The constant current circuit 2 controls the illuminance of the second LED by controlling the amount of current output supplied to the second LED,
The first LED and the second LED are plural,
The control unit
By selectively turning on and off the first LED and the second LED, and controlling color temperature and illuminance,
The color temperature is sequentially raised and lowered in the range of 2800K to 10000K, and the first LED and the second LED are turned on and off,
The control unit is connected to a smartphone app so that the operator can manually or automatically adjust,
Information data in which the control unit turns on and off the first and second LEDs is stored in the smartphone app,
The control unit
The first LED and the second LED are turned on and off at 6 o'clock to correspond to the outdoor environment of the spring equinox season and turned off at 19 o'clock,
At 06:00, only the first LED is turned on and the second LED is turned off,
From 12 o'clock to 13, the first LED turns off and only the second LED turns on,
At 18:00, outputting a driving control signal to the constant current circuit 1 and the constant current circuit 2 so that the first LED turns on and the second LED turns off,
Lighting for insect breeding. delete

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