CN112437525A - High-vision-safety plant growth illumination device based on server and control method thereof - Google Patents

Abstract

The invention discloses a high-vision safety plant growth illumination device based on a server and a control method thereof, wherein the high-vision safety plant growth illumination device based on the server comprises a control part, a light emitting part and the server, wherein the light emitting part comprises a first light source part and a second light source part, the first light source part emits red blue light, the second light source part emits white light, and the control part is connected with the server and used for receiving an instruction of the server and respectively controlling the first light source part and the second light source part. The invention can adjust the irradiation of blue light by the combination and control of the first light source part and the second light source part, thereby protecting the visual safety of personnel working in the plant lighting environment; meanwhile, the white light is used for supplementing components such as green light and the like, so that the spectrum is further enriched, and an environment which is more beneficial to plant growth is created.

Description

High-vision-safety plant growth illumination device based on server and control method thereof

Technical Field

The present invention relates to a plant growth illumination apparatus and a control method thereof, and more particularly, to a plant growth illumination apparatus providing high visual safety based on a server to a worker in a plant lighting environment and a control method thereof.

Background

In the natural environment, plants perform photosynthesis and development and growth by acquiring light components with effective wavelengths in sunlight. However, the natural environment is diverse and has risks of insect damage and the like. Therefore, plant production facilities for growing plants in closed spaces, such as indoors, and simulating natural light by artificial lighting lamps have been gradually raised in recent years, and various large enterprises including philips, osram, GE, siemens, and the like have entered this field.

Not all of the light of the various wavelengths contained in natural light can be utilized by plants, and essentially only blue and red light can be absorbed by plants. In particular, blue light B (e.g. 460nm) can help the growth of plant roots, with the most significant effect on early plant; the red light R (for example 660nm) is beneficial to the stem and leaf, flowering and fruit growth of plants; far-red FR (e.g. 730nm) is beneficial for controlling plant flowering and in vivo nutrient synthesis. According to the species and the growth stage of the plant, the optimal illumination environment for the plant can be obtained by setting the appropriate wavelengths of the red light and the blue light and the red-blue ratio (B/R) between the red light and the blue light; the ultimate goal is to obtain high and stable yield of plants and high and stable nutritional ingredients, while achieving insect control and other effects.

For example, the following are described in the literature "Lee-e.g.. different Red-blue LED combined light sources influence on watermelon seedling growth and physiological parameters [ J ]. Cucurbita pepo, 2015,28(3): 14-17": for watermelon planting, a fluorescent lamp is used as a reference (the illumination intensity is 150 mu mol. m-2s-1), and the influence of LED combined light sources (7:1, 7:2 and 7:3) with different red light and blue light ratios (R/B) on the growth and physiological parameters of watermelon seedlings under the same illumination intensity is discussed; the results show that the stem renting degree, the fresh quality, the dry quality and the strong seedling index of the watermelon seedlings under the red and blue LED combined light source are all increased, wherein the effects are particularly remarkable under the condition that RB is 7: 3.

Disclosure of Invention

(problem to be solved)

However, in the prior art, little attention has been paid to visual comfort and visual safety of workers working in plant lighting environments because the power of conventional LED lighting lamps is relatively low and the damage to the human vision is limited, and with the recent dramatic increase in power, the damage to the human vision from high-power LED lighting lamps has also increased.

For example, in a plant lighting environment, after workers leave the environment for twenty minutes in work for a long time, all things seen before the eyes are green, and various conditions such as dizziness, nausea and the like may occur.

Blue light among various light components has the greatest harm to the vision of people, macular degeneration caused by the blue light harm has become the most concerned problem for LED illumination, and blindness caused by macular degeneration is ranked first and exceeds cataract, which is the most main factor causing poor vision according to the report of the world health organization. Therefore, how to reduce the influence of blue light on workers is an urgent problem to be solved.

In addition, blue light and red light are the main light species absorbed by plants, and other wavelengths of light also have beneficial effects on plant growth, for example, a low proportion of green light can promote the growth of lettuce, and in particular, 24% of green light can be supplemented on the basis of red blue light to promote the growth of lettuce. Therefore, it is also necessary to supplement some other lights based on red and blue lights. Because the white light contains other components such as red and blue light, green light and the like, the white light is added on the basis of the red and blue light, the light quality proportion of the white light is adjusted, and the spectrum in the whole illumination environment can be adjusted with low cost and high efficiency.

(means for solving the problems)

In order to solve the above problems, the present invention adopts the following technical solutions.

A high-vision safety plant growth illumination device based on a server comprises a control part, a light emitting part and the server, wherein,

the light emitting part comprises a first light source part and a second light source part, the first light source part emits red blue light, and the second light source part emits white light;

the control part is connected with the server and used for receiving an instruction of the server and respectively controlling the first light source part and the second light source part.

Optionally, the server and the controller are connected by wired communication or wireless communication.

Optionally, the high-vision-security plant growth illumination device based on the server further includes a photosensitive sensor, a temperature sensor, an infrared biometric recognition device, an ultrasonic biometric recognition device, a voice biometric recognition device, an iris biometric recognition device and/or a face biometric recognition device, and the server sends an instruction to the control unit according to data detected by the photosensitive sensor, the temperature sensor, the infrared biometric recognition device, the ultrasonic biometric recognition device, the voice biometric recognition device, the iris biometric recognition device and/or the face biometric recognition device.

Optionally, the blue light component emitted by the first light source part has a light emission peak within a wavelength range of 380-480 nm, so as to correspond to a blue light domain absorption peak of chlorophyll,

the wavelength of the red light component emitted by the first light source part is in the range of 600-700 nm,

the effective light quantum flux density ratio (R/B) of the red light and the blue light emitted by the first light source part is in the range of 4: 1-10: 1.

Optionally, the first light source unit includes a solid light emitting chip and a coating layer disposed outside the solid light emitting chip, and the coating layer includes a red phosphor capable of absorbing excitation light emitted from the solid light emitting chip and converting the excitation light into red light, so that the solid light emitting chip is used to implement a light source whose dominant wavelength is red and blue light.

Optionally, the server-based plant growth illumination device with high visual safety further includes a timer, the timer sets a time period for the first light source unit and the second light source unit to perform an illumination operation, the server sends an instruction to a controller according to the time period set by the timer, and the controller controls the first light source unit and the second light source unit according to the instruction sent by the server, wherein the timer is set to: the first light source part and/or the second light source part are/is irradiated for the accumulative irradiation illumination intensity time of 10-16 h.

Optionally, the light quantity flux density of the first light source unit and the light intensity of the second light source unit are adjusted by adjusting the PWM waveform and duty ratio of the current.

Optionally, the light quantity flux density ratio of the red light and the blue light of the first light source part is fixed;

the number and the color temperature of the second light source parts are changed on the basis of the first light source parts, and the spectrum proportion of the illumination device suitable for plant growth is adjusted.

Optionally, the light flux density of the yellow-green light of the second light source unit is not more than 30% of the total effective light flux density of the first light source unit and the second light source unit of the illumination device.

Optionally, the color temperature of the second light source part is 2000-10000K, and the illumination intensity of the radiated plant canopy is above 100 lux;

and the proportion of the red light and the blue light of the plant growth illumination device in the whole effective light quantum flux density is adjusted by selecting the second light source parts with different color temperatures and numbers.

Optionally, the photosensitive sensor is configured to detect intensity of external light, and send detected external light intensity data to the server, the server sends an instruction to the controller when the intensity of the external light is greater than a preset upper threshold, and the controller controls the first light source unit and/or the second light source unit to turn off according to the instruction sent by the server; the server sends an instruction to the controller when the intensity of the external light is smaller than a preset lower limit threshold, and the controller controls the first light source part and/or the second light source part to be started according to the instruction sent by the server.

Optionally, the temperature sensor is configured to detect an internal temperature of the plant production facility, and send detected internal temperature data of the plant production facility to the server, the server sends a power-down instruction to the controller when the internal temperature of the plant production facility is greater than a preset upper limit value, and the controller reduces the transmission power of the first light source unit and/or the second light source unit according to the power-down instruction sent by the server; the server sends a power-increasing instruction to the controller when the internal temperature of the plant production facility is lower than a preset lower limit value, and the controller increases the emission power of the first light source part and/or the second light source part according to the power-increasing instruction sent by the server.

Optionally, the infrared biometric device emits infrared rays and receives an infrared signal reflected by a human body, and transmits the infrared signal reflected by the human body to the server, the server judges whether an operator is present in the plant production facility according to a signal detected by the infrared biometric device, and sends an instruction to the controller according to a judgment result, and the controller controls the first light source unit and/or the second light source unit to be turned on and/or off according to the instruction;

the ultrasonic biological recognition device detects the position of an operator in real time and transmits the position information of the operator to the server, the server sends an instruction to the controller according to the position information of the operator detected by the ultrasonic biological recognition device, and the controller controls the first light source part and/or the second light source part near the operator to be turned off according to the instruction sent by the server;

the voice biological recognition device is used for receiving voice in the plant production facility and transmitting a voice signal detected by the voice biological recognition device to the server, the server judges whether an operator exists in the plant production facility according to a decibel value in the plant production facility and sends an instruction to the controller according to a judgment result, the controller controls the first light source part and/or the second light source part to be turned on and/or off according to the instruction sent by the server;

the iris biological recognition device detects iris information of human eyes and transmits acquired iris signals to the server, the server sends instructions to the controller according to the iris information of the human eyes detected by the iris biological recognition device, and the controller controls the first light source part and/or the second light source part to be turned on and/or turned off according to the instructions sent by the server;

the human face biological recognition device detects image information of an operator in a plant production facility and transmits the acquired image information to the server, the server sends an instruction to the controller according to the image information of the operator detected by the human face biological recognition device, and the controller controls the first light source part and/or the second light source part to be turned on and/or turned off according to the instruction sent by the server.

Optionally, photosensitive sensor, temperature sensor, infrared biological recognition device, ultrasonic biological recognition device, voice biological recognition device, iris biological recognition device and/or human face biological recognition device all connect in through the AD converter the server, voice biological recognition device direct connection in the IO port of server.

Optionally, the controller is connected to the control device through a GPIO interface, and the control device is connected to the first light source unit and the second light source unit.

A control method of a high-vision safety plant growth illumination device based on a server comprises the following steps:

setting the time and working period for starting illumination, and controlling the first light source part and the second light source part to be started by the control part after the illumination starting time is reached;

judging the irradiated plants, and determining illumination parameters according to the types of the irradiated plants;

the control part controls the first light source part and the second light source part to work according to the illumination parameters;

and judging whether the working time of the first light source part and the second light source part reaches the working time interval or not, and if the working time reaches the working time interval, controlling the first light source part and the second light source part to be closed by the control part.

Optionally, during the working period of the first light source portion and the second light source portion, whether the human body enters the illumination environment is judged, after the human body enters the illumination environment, the control portion controls the first light source portion to be turned off, and after the human body enters the illumination environment and leaves from the illumination environment, the control portion controls the first light source portion to be turned on.

A high-vision safety plant growth illumination device based on a server comprises a control part, a light emitting part and the server, wherein,

the light emitting part includes a first light source part emitting red blue light and a second light source part emitting white light,

wherein the first light source part and the second light source part are electrically connected in parallel and/or in series,

the control part controls the first light source part and the second light source part in such a manner that the control part regulates the entire spectrum by controlling the color temperature and the number of turns on of the second light source part according to an instruction of the server.

Optionally, the server-based plant growth lighting device with high visual safety further comprises a driving element and a heat dissipation element.

Optionally, the server-based high visual security plant growth illumination apparatus may be used in a facility agriculture, a phytotron or an illumination incubator.

(technical Effect)

The invention can adjust the irradiation of blue light by the combination and control of the first light source part and the second light source part, thereby protecting the visual safety of personnel working in the plant lighting environment; meanwhile, the white light is used for supplementing components such as green light and the like, so that the spectrum is further enriched, and an environment which is more beneficial to plant growth is created.

Drawings

FIG. 1 is a block diagram of the architecture of a server-based high visual security vegetation illumination apparatus of the present invention;

FIG. 2 is a schematic structural diagram of a server-based high visual security plant growth illumination apparatus of the present invention;

FIG. 3 is a flow chart of a control method of the server-based high visual security vegetation illumination apparatus of the present invention;

fig. 4 is a flowchart of a control method of the server-based high visual security plant growth illumination apparatus of the present invention.

Detailed Description

The technical solution of the present invention is further described below with reference to the following embodiments and the accompanying drawings.

Example 1

The embodiment provides a high visual security vegetation lighting device based on server, and it includes control part and luminescent part, wherein, the luminescent part includes first light source portion and second light source portion, first light source portion sends red blue light, second light source portion sends white light, wherein, the control part with the server is connected for receive server's instruction, it is right first light source portion with second light source portion controls respectively.

The server is connected with the controller in a wired communication or wireless communication mode; the server can adopt a cloud server mode and a local server mode, and the communication device which realizes a wired communication mode or a wireless communication mode can realize signal transmission (communication) between the cloud server and the controller or realize signal transmission (communication) between the local server and the controller.

The high-vision-safety plant growth illumination device based on the server further comprises a photosensitive sensor, a temperature sensor, an infrared biological recognition device, an ultrasonic biological recognition device, a voice biological recognition device, an iris biological recognition device and/or a human face biological recognition device which are in signal connection with the server, the server sends an instruction to the controller according to data detected by the photosensitive sensor, the temperature sensor, the infrared biological recognition device, the ultrasonic biological recognition device, the voice biological recognition device, the iris biological recognition device and/or the human face biological recognition device, and the controller controls the first light source part and the second light source part respectively according to the instruction sent by the server to the controller.

In this embodiment, the first light source unit and the second light source unit are electrically connected in parallel and/or in series, and the control unit controls the first light source unit and the second light source unit in such a manner that the control unit controls the color temperature and the number of turns on of the second light source unit to control the entire spectrum.

It is well known that blue light is most harmful to humans than other components of light, which is a common blue light hazard. In particular, the blue light hazard refers to damage to the retina caused by photochemical events upon irradiation with radiation having a wavelength predominantly between 400nm and 500 nm. This damage is exacerbated if the irradiation time exceeds 10 seconds. Therefore, in the actual production, the blue light hazard is paid full attention.

Therefore, in this embodiment, the first light source unit and the second light source unit are arranged, so that on one hand, the requirement of the plant on the light component in the growth process can be met, and on the other hand, the damage of the blue light emitted by the first light source unit to the human body can be reduced to within the design value by controlling the first light source unit and the second light source unit.

More preferably, the blue light component emitted by the first light source part has a light emission peak in a wavelength range of 380-480 nm, so as to correspond to a blue light domain absorption peak of chlorophyll; the wavelength of the red light component emitted by the first light source part is in the range of 600-700 nm, and the effective quantum flux density ratio of the red light and the blue light emitted by the first light source part, namely R/B, is in the range of 4: 1-10: 1.

Taking the planting of strawberries by plant production facilities as an example, when the effective light quantum flux density ratio of red light and blue light emitted by the first light source part, namely R/B, is in the range of 4: 1-10: 1, the single fruit quality and the fruit quality of strawberries can be greatly improved, and the single fruit quality and the fruit quality are improved by about 40% at most compared with the conventional sunlight irradiation in terms of average single fruit quality according to experimental data; the soluble solid content of the mature strawberry fruit is increased by 15% to the maximum extent; the vitamin C content of the mature strawberry fruits is increased by 10 percent to the maximum extent; the soluble sugar content of the mature strawberry fruits is maximally improved by 4.5 percent.

In one implementation form, the first light source unit includes a solid-state light emitting chip, and a coating layer disposed outside the solid-state light emitting chip, the coating layer includes a red phosphor capable of absorbing excitation light emitted by the solid-state light emitting chip and converting the excitation light into red light, so that the solid-state light emitting chip realizes a photosynthetic solid-state light emitting chip with a dominant wavelength of red light and blue light; preferably, the solid light-emitting chip can adopt a blue light LED chip, so that blue light and red light can be generated through the blue light chip with lower cost, and the expenditure of the LED chip is saved.

The second light source part is a solid light emitting chip and a coating layer arranged on the outer side of the solid light emitting chip, and the coating layer contains yellow-green fluorescent powder which can absorb exciting light emitted by the solid light emitting chip and convert the exciting light into white light.

The server-based plant growth illumination device with high visual safety further comprises a timer, wherein the timer sets a time period for enabling the first light source part and the second light source part to perform illumination operation, the server sends an instruction to a controller according to the time period set by the timer, and the controller controls the first light source part and the second light source part according to the instruction sent by the server, wherein the timer is set as follows: the first light source part and/or the second light source part are/is irradiated at the accumulated radiation illumination time of 10-16 h/day or according to the preset time, so that the power supply of the first light source part and the second light source part can be turned off when the sunlight is sufficient in the daytime, and the energy is saved.

As one implementation form, in this embodiment, the light quantity flux density of the first light source section and the light intensity of the second light source section may be adjusted by adjusting the PWM waveform and the duty ratio of the current; when the first light source section is determined, the light quantity flux density ratio of red light and blue light is fixed. When the first light source part and the second light source part are selected, the light quantity flux density ratio of red light and blue light can be adjusted by adjusting the quality of the red light fluorescent powder, and the second light source part comprising white light LED light sources with different numbers and color temperatures is added on the basis of the first light source part, so that white light is included in light irradiated to plants, and the spectral ratio of the illumination device suitable for plant growth can be adjusted more conveniently; and more preferably, the light quantity sub-flow density of the yellowish green light of the second light source section is not more than 30% of the total effective light quantity sub-flow density of the first light source section and the second light source section of the illumination device.

Preferably, the color temperature of the second light source part is 10000K, preferably 3000K, 5000K or 7000K, that is, the control part can adjust the color temperature of the second light source part and also control the access number of the second light source part to regulate the whole spectrum. The light intensity of the plant canopy is above 100lux, and the ratio of red light and blue light of the plant growth lighting device in the whole effective light flux density is adjusted by selecting different color temperatures and numbers of the second light source parts.

In this embodiment, in order to enable the control unit to more accurately control the first light source unit and the second light source unit, the photosensor is configured to detect intensity of external light and send detected external light intensity data to the server, the server sends an instruction to the controller when the intensity of the external light is greater than a preset upper threshold, and the controller controls the first light source unit and the second light source unit to turn off according to the instruction sent by the server; the server sends an instruction to the controller when the intensity of the external light is smaller than a preset lower limit threshold, and the controller controls the first light source part and the second light source part to be started according to the instruction sent by the server.

The temperature sensor is used for detecting the internal temperature of the plant production facility and sending the detected internal temperature data of the plant production facility to the server, the server sends a power-adjusting instruction to the controller when the internal temperature of the plant production facility is greater than a preset upper limit value, and the controller adjusts the emission power of the first light source part and/or the second light source part according to the power-adjusting instruction sent by the server; the server sends a power-increasing instruction to the controller when the internal temperature of the plant production facility is lower than a preset lower limit value, and the controller increases the emission power of the first light source part and/or the second light source part according to the power-increasing instruction sent by the server.

In particular, when a person enters the plant production facility including the server-based plant growth illumination device with high visual safety of the present embodiment, the first light source part needs to be turned off at this time in consideration of the influence of blue light on the human body, so that the blue light in the plant production facility is reduced to a reasonable level; therefore, the infrared biological recognition device emits infrared rays, receives infrared signals reflected by a human body, and transmits the infrared signals reflected by the human body to the server, the server judges whether an operator exists in the plant production facility according to the signals detected by the infrared biological recognition device and sends an instruction to the controller according to a judgment result, and the controller controls the first light source part and/or the second light source part to be turned on and/or turned off according to the instruction; that is, when there is an operator inside the plant production facility, the controller controls the first light source unit to be turned off, or controls the first light source unit and the second light source unit to be turned off; when no operator exists in the plant production facility, the controller controls the first light source part to be turned on, or controls the first light source part and the second light source part to be turned on.

The ultrasonic biological recognition device detects the position of an operator in real time and transmits the position information of the operator to the server, the server sends an instruction to the controller according to the position information of the operator detected by the ultrasonic biological recognition device, and the controller controls the first light source part and/or the second light source part near the operator to be turned on and/or turned off according to the instruction sent by the server; that is, when an operator exists inside the plant production facility, the controller controls the first light source part, the second light source part and/or the third light source part near the operator to be turned off; when no operator is present in the plant production facility, the controller controls the first light source part, the second light source part and/or the third light source part to be turned on.

The voice biological recognition device is used for receiving voice in the plant production facility and transmitting a voice signal detected by the voice biological recognition device to the server, the server judges whether an operator exists in the plant production facility according to a decibel value in the plant production facility and sends an instruction to the controller according to a judgment result, the controller controls the first light source part and/or the second light source part to be turned on and/or off according to the instruction sent by the server; that is, when there is an operator inside the plant production facility, the controller controls the first light source part and/or the second light source part to be turned off; when no operator is present in the plant production facility, the controller controls the first light source unit and/or the second light source unit to be turned on.

The iris biological recognition device detects iris information of human eyes and transmits acquired iris signals to the server, the server sends instructions to the controller according to the iris information of the human eyes detected by the iris biological recognition device, and the controller controls the first light source part and/or the second light source part to be turned on and/or turned off according to the instructions sent by the server; that is, when there is an operator inside the plant production facility, the controller controls the first light source part and/or the second light source part to be turned off; when no operator is present in the plant production facility, the controller controls the first light source unit and/or the second light source unit to be turned on.

The human face biological recognition device detects image information of an operator in a plant production facility and transmits the acquired image information to the server, the server sends an instruction to the controller according to the image information of the operator detected by the human face biological recognition device, and the controller controls the first light source part and/or the second light source part to be turned on and/or turned off according to the instruction sent by the server. That is, when there is an operator inside the plant production facility, the controller controls the first light source part and/or the second light source part to be turned off; when no operator is present in the plant production facility, the controller controls the first light source unit and/or the second light source unit to be turned on.

Photosensitive sensor, temperature sensor, infrared biological recognition device, ultrasonic wave biological recognition device, sound biological recognition device, iris biological recognition device and/or people's face biological recognition device all connect in through the AD converter the server, sound biological recognition device lug connection in the IO port of server.

The controller is connected to a control device through a GPIO interface, and the control device is connected to the first light source part and the second light source part.

Furthermore, to prevent the strong light from damaging the human body, such as human eyes, the control portion adjusts the illumination intensity of the second light source portion to be less than 1000lux (or between 200 lux and 800 lux).

The high-vision safety plant growth illumination device based on the server further comprises a driving element and a heat dissipation element, wherein the driving element is used for driving the first light source part and the second light source part, and the heat dissipation element is used for dissipating heat of the first light source part and the second light source part.

The first light emitting part and the second light emitting part comprise solid light emitting chips and circuit boards electrically connected with the solid light emitting chips, and preferably, the solid light emitting element comprises at least one of a light emitting diode, an organic light emitting diode, a vertical cavity surface emitting laser and a laser diode.

The term "LED" in this embodiment should be understood to include any electroluminescent diode or other type of carrier injection based system capable of generating radiation in response to an electrical signal. Thus, the term LED includes, but is not limited to, various semiconductor-based structures that emit light in response to current, light-emitting polymers, organic light-emitting diodes (OLEDs), electroluminescent strips, and the like.

The term LED does not limit the type of physical and/or electrical packaging of the LED. For example, as discussed above, an LED may refer to a single light emitting device having multiple dies (e.g., which may or may not be individually controllable) configured to emit different spectra of radiation, respectively. Also, the LED may be associated with a phosphor that is considered an integral part of the LED (e.g., some types of white LEDs). In general, the term LED may refer to packaged LEDs, non-packaged LEDs, surface mount LEDs, chip-on-board LEDs, T-package mounted LEDs, radial package LEDs, power package LEDs, LEDs that include some type of packaging and/or optical element (e.g., a diffusing lens), and so forth.

In an embodiment of the present invention, the circuit board includes a PCB, a substrate, a flexible board, or a rigid-flex board.

The server-based high-vision-safety plant growth illumination device can be used for facility agriculture, artificial climate rooms or illumination incubators.

Example 2

The present embodiment provides a method for controlling a server-based high-visual-security plant growth illumination device, where the server-based high-visual-security plant growth illumination device may adopt the server-based high-visual-security plant growth illumination device disclosed in embodiment 1, and the method includes:

setting the time and working period for starting illumination, and controlling the first light source part and the second light source part to be started by the control part after the illumination starting time is reached;

judging the irradiated plants, and determining illumination parameters according to the types of the irradiated plants;

the control part controls the first light source part and the second light source part to work according to the illumination parameters;

and judging whether the working time of the first light source part and the second light source part reaches the working time interval or not, and if the working time reaches the working time interval, controlling the first light source part and the second light source part to be closed by the control part.

Further, during the operation of the first light source unit and the second light source unit, it is determined whether the human body enters the lighting environment, the control unit controls the first light source unit to be turned off after the human body enters the lighting environment, and controls the first light source unit to be turned on after the human body enters the lighting environment and leaves the lighting environment.

The sequence of the above embodiments is only for convenience of description and does not represent the advantages and disadvantages of the embodiments.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (20)

1. A high-vision safety plant growth illumination device based on a server is characterized in that,

comprises a control part, a light emitting part and a server, wherein,

the light emitting part comprises a first light source part and a second light source part, the first light source part emits red blue light, and the second light source part emits white light;

the control part is connected with the server and used for receiving an instruction of the server and respectively controlling the first light source part and the second light source part.

2. The server-based plant growth illumination device with high visual safety as claimed in claim 1, wherein the server is connected with the controller by means of wired communication or wireless communication.

3. The server-based plant growth illumination device with high visual safety as claimed in claim 2, further comprising a photosensitive sensor, a temperature sensor, an infrared biometric device, an ultrasonic biometric device, a voice biometric device, an iris biometric device and/or a human face biometric device, wherein the server sends an instruction to the control part according to the data detected by the photosensitive sensor, the temperature sensor, the infrared biometric device, the ultrasonic biometric device, the voice biometric device, the iris biometric device and/or the human face biometric device.

4. The server-based high visual security plant growing illumination device of claim 3,

the blue light component emitted by the first light source part has a light emitting peak in the wavelength range of 380-480 nm so as to correspond to the absorption peak of the blue light domain of chlorophyll,

the wavelength of the red light component emitted by the first light source part is in the range of 600-700 nm,

the effective light quantum flux density ratio (R/B) of the red light and the blue light emitted by the first light source part is in the range of 4: 1-10: 1.

5. The server-based high visual security plant growing illumination device of claim 1,

the first light source part comprises a solid light emitting chip and a coating layer arranged on the outer side of the solid light emitting chip, wherein the coating layer contains red fluorescent powder capable of absorbing exciting light emitted by the solid light emitting chip and converting the exciting light to emit red light, so that the light source with the main wavelength of red and blue light is realized through the solid light emitting chip.

6. The server-based high visual security plant growing illumination device of claim 1,

the illumination device further includes a timer that sets a time period for causing the first light source unit and the second light source unit to perform an illumination operation, the server sends a command to a controller according to the time period set by the timer, and the controller controls the first light source unit and the second light source unit according to the command sent by the server, wherein the timer is set to: the first light source part and/or the second light source part are/is irradiated for the accumulative irradiation illumination intensity time of 10-16 h.

7. The server-based high visual security plant growing illumination device of claim 1,

the light flux density of the first light source unit and the light intensity of the second light source unit are adjusted by adjusting the PWM waveform and duty ratio of the current.

8. The server-based high visual security plant growing illumination device of claim 1,

the light quantity flux density ratio of the red light and the blue light of the first light source part is fixed;

the number and the color temperature of the second light source parts are changed on the basis of the first light source parts, and the spectrum proportion of the illumination device suitable for plant growth is adjusted.

9. The server-based high visual security plant growing illumination device of claim 1,

the light flux density of the yellow-green light of the second light source section is not more than 30% of the total effective light flux density of the first light source section and the second light source section of the illumination device.

10. The server-based high visual security plant growing illumination device of claim 1,

the color temperature of the second light source part is 2000-10000K, and the illumination intensity of the radiated plant canopy is more than 100 lux;

and the proportion of the red light and the blue light of the plant growth illumination device in the whole effective light quantum flux density is adjusted by selecting the second light source parts with different color temperatures and numbers.

11. The server-based plant growth illumination device with high visual safety as claimed in claim 3, wherein the photosensor is used for detecting the intensity of external light and sending the detected external light intensity data to the server, the server sends an instruction to the controller when the intensity of external light is greater than a preset upper threshold, and the controller controls the first light source part and/or the second light source part to be turned off according to the instruction sent by the server; the server sends an instruction to the controller when the intensity of the external light is smaller than a preset lower limit threshold, and the controller controls the first light source part and/or the second light source part to be started according to the instruction sent by the server.

12. The server-based plant growth illumination device with high visual safety as claimed in claim 11, wherein the temperature sensor is configured to detect an internal temperature of the plant production facility and transmit the detected internal temperature data of the plant production facility to the server, the server transmits a power-down command to the controller when the internal temperature of the plant production facility is greater than a preset upper limit value, and the controller reduces the emission power of the first light source unit and/or the second light source unit according to the power-down command transmitted by the server; the server sends a power-increasing instruction to the controller when the internal temperature of the plant production facility is lower than a preset lower limit value, and the controller increases the emission power of the first light source part and/or the second light source part according to the power-increasing instruction sent by the server.

13. The server-based high visual security plant growing illumination device of claim 12,

the infrared biological recognition device emits infrared rays and receives infrared signals reflected by a human body, the infrared signals reflected by the human body are transmitted to the server, the server judges whether an operator exists in the plant production facility or not according to the signals detected by the infrared biological recognition device and sends an instruction to the controller according to a judgment result, and the controller controls the first light source part and/or the second light source part to be turned on and/or turned off according to the instruction;

the ultrasonic biological recognition device detects the position of an operator in real time and transmits the position information of the operator to the server, the server sends an instruction to the controller according to the position information of the operator detected by the ultrasonic biological recognition device, and the controller controls the first light source part and/or the second light source part near the operator to be turned off according to the instruction sent by the server;

the voice biological recognition device is used for receiving voice in the plant production facility and transmitting a voice signal detected by the voice biological recognition device to the server, the server judges whether an operator exists in the plant production facility according to a decibel value in the plant production facility and sends an instruction to the controller according to a judgment result, the controller controls the first light source part and/or the second light source part to be turned on and/or off according to the instruction sent by the server;

the iris biological recognition device detects iris information of human eyes and transmits acquired iris signals to the server, the server sends instructions to the controller according to the iris information of the human eyes detected by the iris biological recognition device, and the controller controls the first light source part and/or the second light source part to be turned on and/or turned off according to the instructions sent by the server;

the human face biological recognition device detects image information of an operator in a plant production facility and transmits the acquired image information to the server, the server sends an instruction to the controller according to the image information of the operator detected by the human face biological recognition device, and the controller controls the first light source part and/or the second light source part to be turned on and/or turned off according to the instruction sent by the server.

14. The server-based plant growth illumination device with high visual safety as claimed in claim 3, wherein the photosensitive sensor, the temperature sensor, the infrared biometric device, the ultrasonic biometric device, the voice biometric device, the iris biometric device and/or the face biometric device are all connected to the server through AD converters, and the voice biometric device is directly connected to the IO port of the server.

15. The server-based high visual security plant growth illumination device of claim 14, wherein the controller is connected to a control device through a GPIO interface, the control device being connected to the first and second light source sections.

16. A control method of a high-vision-safety plant growth illumination device based on a server is characterized by comprising the following steps:

setting the time and working period for starting illumination, and controlling the first light source part and the second light source part to be started by the control part after the illumination starting time is reached;

judging the irradiated plants, and determining illumination parameters according to the types of the irradiated plants;

the control part controls the first light source part and the second light source part to work according to the illumination parameters;

and judging whether the working time of the first light source part and the second light source part reaches the working time interval or not, and if the working time reaches the working time interval, controlling the first light source part and the second light source part to be closed by the control part.

17. The control method for server-based high visual security plant growth lighting fixture of claim 16,

the control part controls the first light source part to be turned off after the human body enters the illumination environment, and controls the first light source part to be turned on after the human body enters the illumination environment and leaves from the illumination environment.

18. A high-vision safety plant growth illumination device based on a server is characterized by comprising a control part, a light emitting part and the server, wherein,

the light emitting part includes a first light source part emitting red blue light and a second light source part emitting white light,

wherein the first light source part and the second light source part are electrically connected in parallel and/or in series,

the control part controls the first light source part and the second light source part in such a manner that the control part regulates the entire spectrum by controlling the color temperature and the number of turns on of the second light source part according to an instruction of the server.

19. The server-based high visual security plant growth illumination apparatus of claim 18, further comprising a driving element and a heat dissipating element.

20. The server-based high visual safety plant growth illumination apparatus of claim 18, wherein the server-based high visual safety plant growth illumination apparatus is usable in a facility agriculture, a phytotron, or an illumination incubator.

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