KR101612392B1 - LED light source device and system for managing a standard cultivation facility using the same - Google Patents

Abstract

[0001] The present invention relates to an LED light source device for promoting the growth of crops, and a control system and a control system for a standard cultivation facility using the LED light source device. More particularly, the LED light source device includes a plurality of LED modules arranged in a bar shape Board; A base for receiving the circuit board; A cover for sealing the upper surface of the base; And an LED control unit having a communication interface and individually or integrally controlling the plurality of LED modules.

Description

Technical Field [0001] The present invention relates to an LED light source device and an integrated control and management system using the LED light source device,

The present invention relates to an LED light source apparatus for promoting the growth of crops, and a standard management system for integrated management and management of plant cultivation facilities.

Generally, crops grown in nurseries, such as nurseries, are influenced by the quality of crops growth rate, taste, etc. through the influence of temperature, humidity, irradiation amount, and carbon dioxide. Therefore, in this nursery, a system (apparatus) which makes the temperature, humidity, irradiation amount and the like constant is used is used. In case of such a device, I had no choice but to do it based on the record by hand.

That is, the user has to operate the system by judging the environmental condition necessary for the crop based on his / her experience. Since the operation depends on the experience side, the accuracy is poor and the crop growth efficiency is not good.

Korean Patent Registration No. 699162 discloses a ubiquitous farm management system and a method thereof. In this technology, environmental factors in a house to be managed using a communication network are detected, and temperature and humidity inside are controlled And comparing the environmental factors received from the management terminal with the farm management data required for cultivating or raising the crop or livestock managed in the house and transmitting the comparison result to the mobile terminal through the communication network And a farm management server for transmitting a control signal received from the mobile terminal to the management terminal.

However, in the above technique, the farm management data is compared with the measured data to take necessary measures. In the environment that is influenced by external factors, such as an open type nursery, And it is difficult to derive a standardized cultivation method or the like through this.

On the other hand, the light source, which is an environmental factor that greatly influences the growth of crops in the nursery, has been cultivated efficiently by applying artificial lighting so that the development is always constant regardless of the season, .

However, in this case, since the incandescent lamp used as the artificial light is irradiated with all the visible rays, the growth promoting effect is exhibited at different wavelengths for each plant, so that it is difficult to apply to all actual crops.

Korea Patent No. 699162

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide an LED light source device capable of arbitrarily controlling the irradiation amount and color of a light source according to the type of crop, And a management system.

Another object of the present invention is to provide an LED light source device capable of producing a high-quality product by standardization of cultivation based on the uniformity environment in crop cultivation, and a standard control facility management and management system using the same. have.

According to an aspect of the present invention, there is provided an LED light source device including: a circuit board having a plurality of LED modules arranged in a bar shape; A base for receiving the circuit board; A cover for sealing the upper surface of the base; And an LED control unit having a communication interface and individually or integrally controlling the plurality of LED modules.

As one example, the LED module may be configured as a 3: 2: 1 array of red, white, and blue LED elements.

As one example, the base is made of aluminum material, and a plurality of air-cooled grooves are formed along the outer surface thereof, and at least one water-cooled tube is formed therein so that the cooling can be structurally performed.

As one example, the base is composed of a fixing surface on which the circuit board is seated and a reflecting portion that forms an inclined gradient at both ends of the fixing surface, wherein epoxy resin 25 to 100 A reflective coating layer containing 2 to 10 parts by weight of a fluorescent dye, 2 to 10 parts by weight of a fluorescent dye, 2 to 10 parts by weight of a foaming inhibitor, 6 to 30 parts by weight of a photocatalyst and 6 to 30 parts by weight of strontium aluminate.

In addition, the reflective coating layer may further contain 0.5 to 2 parts by weight of propylene carbonate.

Meanwhile, the integrated control and management system for a standard cultivation facility using the LED light source apparatus of the present invention includes a cultivation facility for growing crops therein; A storage unit for storing growth model information, which is environment information according to a growth period of the crop; A measuring unit for sensing environmental information of the cultivation facility; An integrated controller for controlling the configuration of the cultivation facility using the LED light source device according to any one of claims 1 to 5 according to the growth model information; An analysis unit for comparing environmental information sensed by the measurement unit with growth model information stored in a storage unit; And a monitor unit for monitoring data from the analysis unit.

As one example, the cultivation facility is an enclosed nursery, and the LED light source device is disposed on the upper part, and the camera is further constructed.

As an example, under the control of the integrated control unit, the LED light source device may divide the sections and alternately turn on the lights to adjust the illuminance of the nursery.

As one example, the nursery is provided with at least one underground pipe connected to the blower at one end thereof, embedded in the ground, and connected at the other end to the nursery, and having a plurality of inflow holes.

As an example, the analysis unit analyzes environmental information sensed by the measurement unit, growth model information stored in the storage unit, and real-time image information by a camera to output a control signal to the nursery or to output new growth model information And stores it in the storage unit.

As described above, in the LED light source device of the present invention, in forming the base, it is possible to prevent a shadow from being generated by forming a reflection coating layer as well as a cooling structure capable of performing water cooling and air- It is possible to shorten the life of the apparatus due to heat and to prevent malfunction of the apparatus.

In addition, the LED light source device can arbitrarily control the irradiation amount and color of the light source according to the type of the crop, thereby improving the productivity of cultivated crops. In addition, the integrated control and management system of the standard cultivation facility using the LED light source device, The control of the cultivation facility based on the information of the growth model of the cultivated plant, and the standardization of the cultivation, there is an advantage that the high quality product can be produced.

1A and 1B are sectional views showing a configuration of an LED light source device of the present invention.
2 is a plan view showing an arrangement structure of an LED module as an embodiment of the present invention.
3 is a cross-sectional view illustrating a base according to one embodiment of the present invention.
4 is a cross-sectional view showing an operating state of the embodiment of Fig. 3;
FIG. 5 is a block diagram showing a standard control facility management and management system using the LED light source device of the present invention. FIG.
FIG. 6 is a block diagram showing an operating relationship of an analyzing part, which is a constitution of the present invention; FIG.
FIG. 7 is a conceptual diagram showing an embodiment of a cultivation facility which is an embodiment of the present invention. FIG.
8 is a conceptual diagram showing an operating state of an LED light source device which is a constitution of the present invention.
9 is a block diagram for explaining an integrated control and management method of a standard cultivation facility using the LED light source device of the present invention.

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

FIGS. 1A and 1B are views showing a configuration of an LED light source device according to the present invention, and FIG. 2 is a plan view showing an arrangement structure of an LED module as a constitution of the present invention. 3 is a cross-sectional view illustrating a base according to an embodiment of the present invention, and FIG. 4 is a cross-sectional view illustrating an operation state of the embodiment of FIG.

The LED light source device 100 of the present invention includes a circuit board 120 in which a plurality of LED modules 110 are arranged in a bar shape as shown in FIG. A cover 140 for sealing the upper surface of the base, and an LED controller 150 having a communication interface and separately or integrally controlling the plurality of LED modules 110.

The circuit board 120 is a conventional PCB (Printed Circuit Board), and a plurality of LED (Light Emitting Diode) modules 110 are arranged and electrically connected to the circuit. The LED module 110 is configured such that a plurality of LED elements 111 are combined in a serial or parallel structure to form one module.

Here, the LED element 111 can realize a visible light ray having a wavelength of 400 to 700 nm, an ultraviolet ray of 400 nm or less and an infrared ray wavelength of 700 nm or more that can be recognized by a human eye according to a semiconductor material, And is widely used in industry.

The light source using the LED element 111 functions as a major environmental factor together with temperature, humidity, carbon dioxide and the like in a growing environment. As described above, since a light source of various colors can be irradiated, .

For example, when sunlight melts near the infrared light with an LED light source, the yield increased by 25%, tomatoes and ginseng showed good effects in infrared, and perilla and strawberry increased in red light The results are presented.

In addition, the use of LED light source also showed the effect of pest control. It is known that insects like light in the ultraviolet ray region having a short wavelength and dislike light in the yellow and red region having a comparatively long wavelength. It is preferable to apply the LED light source in the cultivation facility as a pest control for the pest control.

According to an embodiment of the present invention, the LED module 110 arranges the red LEDs 111a, which have a relatively large number of crops to promote growth, ), And blue (111c) LED elements can be arranged in a 3: 2: 1 array.

The base 130 is made of an aluminum material to provide a heat radiation effect.

As shown in FIG. 1, the base 130 has a plurality of air-cooled grooves 131 formed along its outer surface to allow natural cooling by external air as the cross-sectional area is expanded. In addition, The cooling water circulation line is connected to the water-cooling pipe 132 so that the cooling water is introduced and circulated so that the cooling of the base 130 by the cooling water can be performed.

As a result, the base 130 is cooled and cooled by the air-cooled type and the water-cooled type in accordance with the structural characteristics of the air-cooled groove 131 and the water-cooled tube 132. As a result, So that problems such as errors can be solved.

3, the base 130 according to another embodiment of the present invention includes a fixing surface 133 and a reflecting portion 134 that forms an oblique gradient at both ends of the fixing surface 133 And the receiving space of the base 130 has a shape of an inverted trapezoid with its top face opened.

The fixing surface 133 forms a bottom surface and the circuit board 120 described above is installed on the top surface and the reflective coating 134 is provided with a reflection coating layer 135 so that light is transmitted to the entire area of the cover 140, thereby detecting surface emission without shading.

For this, the reflective coating layer 135 is applied to the reflective portion 134 according to the present embodiment. The reflective coating layer 135 may include 25 to 100 parts by weight of an epoxy resin, 2 to 10 parts by weight of a blending additive, 2 to 10 parts by weight of an antifoaming agent, 6 to 30 parts by weight of a photocatalyst and 6 to 30 parts by weight of strontium aluminate.

The polyester resin is added as a binder for enhancing the reflectance and mechanical strength of visible light, and the epoxy resin is added as a curing agent for improving the mechanical properties of the applied reflective coating layer 135. The reason why the content of the epoxy resin is limited as described above is to control the hardness to prevent the brittle tendency.

On the other hand, in the case of powder paints, it is difficult to maintain the smoothness because the particles are uneven. Such uneven surface causes diffuse reflection. In order to prevent diffused reflection and increase the reflectance, various reflection additives are added to the reflection coating layer 135. For example, an acrylic reflection enhancing additive may be included.

The antifoaming agent may include various antifoaming agents, for example, benzoin may be added.

It is appropriate that the photocatalyst is added with one or a mixture of titanium dioxide, a sulfate and barium sulfate as a composition to which the reflective coating layer is added to improve the reflectance.

The titanium dioxide prevents the occurrence of pinholes or the like formed on the surface of the coating film, thereby improving the reflectance. Titanium dioxide particles generate active oxygen by ultraviolet rays contained in light emitted through the LED element 111, And exhibits an oxidation-reduction action, so that degradation of reflectance due to generation of gas can be prevented by organic substance decomposition, sterilization, and the like.

Also, in the case of sulfate and barium sulfate, a high reflectance is exhibited with respect to wavelength light in the 250 nm to 2500 nm band, and one or a mixture thereof is selectively added to such a composition to improve the reflectance.

In particular, strontium aluminate is added to the reflective coating layer 135, which converts heat generated by the operation of the LED element 111 into light so as to perform a heat radiation function. By projecting the converted light, So that the function of removal is additionally provided.

The heat generated by the operation of the LED element 111 may be transferred to another place by heat transfer or may be converted into another energy to be removed. Heat transfer may be affected by the latent heat of the heat transfer medium and the heat transfer rate. Therefore, in the present invention, thermal energy is converted into light energy by the strontium aluminate contained in the reflective coating layer 135 So that the heat radiation function is performed.

When strontium aluminate is exposed to thermal energy, electrons around the nucleus are excited by thermal energy, absorbing heat energy, and emit as light energy according to the stabilization tendency of electrons and return to the original state. That is, the strontium aluminate converts heat energy into light energy and radiates it to perform a heat radiation function.

The operation of the reflective coating layer 135 will be described with reference to FIG. 4. The reflective coating layer 135 reflects the light E1 emitted from the LED element 111 and removes the shadow. At the same time, The heat energy E2 is converted into the light energy E2-1 so that the heat radiation function is performed and the function of removing the shade is also performed by irradiating the converted light energy E2-1 to the outside will be.

The reflective coating layer 135 is formed to have a reflective function and a heat dissipating function at the same time so as to form one route for reducing thermal energy E2 accumulated between the base 130 and the cover 140. [

The reason why the strontium aluminate is limited to the above-mentioned limited range is that the effect of the heat radiation and reflection function mentioned above is fully manifested, so that the durability and the like are not lowered and the cost part is satisfied.

On the other hand, when the photocatalyst and strontium aluminate are not uniformly dispersed in the composition of the reflective coating layer 135, shading may occur due to non-uniform reflection, and thermal deformation may occur due to partial heat dissipation In addition, 0.5 to 2 parts by weight of propylene carbonate is further added to the reflective coating layer 135 in addition to the above composition.

The photocatalyst and the strontium aluminate are uniformly dispersed throughout the reflective coating layer 135 as the propylene carbonate is further mixed so that the light energy E1 and the thermal energy E2 due to the LED element 111 are uniformly reflected And it is possible to control the problem of partial thermal deformation of the reflective coating layer 135 by switching the thermal energy E2 to the light energy E2-1 over the entire area.

The cover 140 is configured to cover the opened upper end of the base 130. The cover 140 is formed of a light-transmitting material, and more preferably, the outer frame is formed without the reference numeral, and the diffusion of the light- Plate. The diffusion plate uniformly diffuses the light projected by the LED element 111, and it is preferable that the diffusion plate is preferably formed in an embossed shape. The emboss shape is a random uneven shape formed on the surface of the diffusion plate.

The base 130 and the cover 140 may be formed in various shapes. For example, as shown in FIG. 1 and the like, The cover 140 is formed to have a sliding protrusion 141 corresponding to the slide groove 136 at both ends of the cover 140 so that the cover 140 can be engaged with the slide groove 136 .

The LED control unit 150 individually or integrally controls the LED modules 110 according to a control signal transmitted from the outside. It is not shown in the figure, but a communication interface that provides transmission and reception of data including control signals And controls the voltage value and current value of each LED module 110 according to the control signal to control ON / OFF and control amount of each LED element 111 according to color.

The LED light source apparatus 100 installed in the cultivation facility under the control of the LED control unit 150 selectively operates the color and illumination amount of the LED element 111 from the database control signal according to the crop to be cultivated So that it is possible to generate optimum environmental conditions for each crop.

FIG. 5 is a block diagram showing a standard management system for a standard cultivation facility using the LED light source apparatus of the present invention, and FIG. 6 is a block diagram showing an operation relationship of the analysis unit, which is a constitution of the present invention. FIG. 7 is a conceptual diagram showing an embodiment of a cultivating facility which is a constitution of the present invention, and FIG. 8 is a conceptual diagram showing an operating state of the LED light source device which is a constitution of the present invention.

As shown in FIG. 5, the LED light source apparatus 100 of the present invention includes a cultivation facility 10 for cultivating crops therein, a cultivation facility 10 for cultivating crops, (50) for sensing the environmental information of the cultivation facility (10), and a controller (50) for sensing the environmental information of the cultivation facility (10) by using the above LED light source device An analysis unit 40 for comparing and analyzing the environmental information sensed by the measurement unit 50 and the growth model information stored in the storage unit, And a monitor unit 60 for monitoring data.

The cultivation facility 10 is not limited in its kind and refers to a space where various crops are grown, and may be a nursery as described below. Hereinafter, the cultivation facility 10 is referred to as a nursery. Here, the nursery area (10) may be a foot garden, a seedling room.

The nursery field 10 is characterized by an enclosed structure as shown in FIG. This is due to the difficulty in controlling and controlling various kinds of pests and diseases by using the open type in the existing nursery, and in order to provide a uniform environment to the crop, in the present invention, the closed nursery (10 ).

The above-described LED light source device 100 is constructed above the nursery 10 so that a uniform irradiation amount replacing the amount of sunlight is projected onto the crop.

In particular, in the present invention, the integrated control unit 30 generates a control signal for the LED light source device 100, and the LED modules constituting the LED light source device 100, under the control of the integrated control unit 30, So that the temperature and the illuminance of the hair-growing room 10 are controlled.

That is, as shown in FIG. 8, the LED light source device 100 is configured such that a plurality of LED modules are configured to alternate between the lighting section 81 and the non-lighting section 82. This is because the operation of the LED light source device 100 The integrated control unit 30 controls the integrated control unit 30 so that the number of the lighting periods 81 is kept constant so that the illuminance is uniform and the lighting period of the lighting period 81 becomes long, The temperature of the chamber 10 is increased.

Therefore, in the present invention, the lighting section 81 having a longer lighting time is switched to the light-off section 82, and the light-off section 82 is switched to the lighting section 81 to maintain the constant illuminance and temperature. In addition, the present invention uses energy of the LED light source device 100 as temperature regulating means of the seedlings room 10, and saves energy by using other means only for insufficient portions.

7 shows an example in which a temperature and carbon dioxide regulating device 90 is added to the nursery 10 as an embodiment of the present invention.

The temperature and carbon dioxide regulating device 90 is composed of a blower 91 and at least one underground pipe 92. The underground pipe 92 is embedded in the ground and one end is connected to the blower 91 , And the other end communicates with the seedlings room (10), and a plurality of inflow holes (93) are formed.

 The operation of the temperature and carbon dioxide regulating device 90 is such that the flow of air to the underground pipe 92 is generated by the operation of the blower 91. The flow of the air is transmitted to the underground pipe The geothermal energy absorbed air is supplied to the seedling seedling room 10 to heat the seedling seedling room 10, .

In addition to the LED light source device 100, the present invention enables heating of the seedlings room 10 by means of the geothermal energy, which is natural energy, using the temperature and carbon dioxide regulating device 90, . The blower 91 is not shown in the drawing, but is operated under the control of the integrated control unit 30.

As a result, the temperature can be controlled by the heat generated by the LED light source device 100 and the geothermal energy of the temperature and carbon dioxide regulating device 90 for maintaining the constant illuminance. In the temperature and carbon dioxide regulating device 90, The temperature can be controlled and the fertilization can be made at the same time, thereby enabling eco-friendly and economical seedlings.

In addition, when air flows into the underground pipe (92) by the operation of the blower (91), natural carbon dioxide in the ground flows through the through hole (93) 10) is supplied with natural carbon dioxide. In other words, it is possible to utilize carbon dioxide in the ground without a device such as a separate combustor, thereby enabling environmentally friendly fertilization.

5, the camera 70 is a device for obtaining image information inside the nursery 10, and includes a CCTV (Closed) system having an infrared function Circuit System).

The camera 70 acquires image information for each crop 1 in the nursery 10 and transmits the acquired image information to the analysis unit 40. By having the infrared function, it is easy to acquire images in the nighttime as well as in the daytime. By converting the analog image acquired including the DVR (Digital Video Recorder) into a digital image, To control the growth state of the plants.

The storage unit 20 stores the growth model information, which is environmental information according to a crop growth cycle. Here, the growth period is defined as a time-divided segment according to crops such as germination, growth, and the like.

The growth model information may be growth model information corrected by predetermined growth model information, predetermined growth model information, and environment information measured from the growth cycle, and the information on the growth model to which the correction is applied is a standard growth model It is information.

The measurement unit 50 is configured to sense environmental information of the cultivation facility 10 and is a combination of sensors for temperature, humidity, illumination, carbon dioxide, etc., which are functions affecting the growth of crops. These sensors measure the corresponding information at predetermined intervals, and the corresponding information, that is, the environmental information, is transmitted to the analyzer 40.

The integrated control unit 30 controls the configuration of the nursery 10 to generate a control signal based on a control command according to the growth model information output from the analysis unit 40, (Not shown) that can control the LED light source device 100, the blower 91, and other temperature, humidity, carbon dioxide, etc., as the configuration of the LED 10, 10) to regulate the growth environment.

The analysis unit 40 compares and analyzes the environment information sensed by the measurement unit 50 and the growth model information stored in the storage unit 20. [

6, the environment information sensed by the measuring unit 50, the growth model information stored in the storage unit 20, the photographs by the camera 70, Information is analyzed and a control command is output in the structure of the nursery field 10 or new growth model information is output and stored in the storage unit 20. [

As an example of the analysis performed by the analysis unit 40, a tool using a function based only on the amount of carbon dioxide and the growth length will be described.

The amount of carbon dioxide required in the specific growth cycle and the appropriate growth length are determined in the growth model information input in the storage unit 20 at a specific growth period, and the sensed environment information is the actual carbon dioxide amount in the corresponding growth cycle , The image information by the camera 70 will be the actual growth length in the corresponding growth period.

Based on this data, the analysis unit 40 compares the amount of carbon dioxide required, the appropriate growth length, the actual carbon dioxide amount, and the actual growth length in the predetermined specific growth period to determine the actual growth amount, If the length and the actual growth length are the same within the error range, the analyzer 40 corrects the required carbon dioxide amount to the actual measured carbon dioxide amount, and corrects the growth model information in the specific growth cycle of the storage unit 20. [ The growth model information finally finalized by the analysis unit 40 becomes standard growth model information for the crop.

If the actual carbon dioxide amount is measured to be smaller than the required amount of carbon dioxide and the actual growth length is shorter than the optimum growth length, the analysis unit 40 outputs a control command to the integrated control unit 30, The temperature and the blower 91 of the carbon dioxide regulating device 90 are operated to generate a control signal for increasing the amount of carbon dioxide in the nursery 10.

The monitoring unit 60 corresponds to a configuration that allows the user to monitor data from the analyzing unit 40. [ Although not shown in the figure, an SMS (Short Message Service) may be transmitted to a user's terminal using an Internet or a CDMA communication network connected through a communication unit, thereby allowing the user to monitor the state of the seedlings. In this case, the monitor unit 60 may be a user terminal.

In addition, the monitor unit 60 may be provided with a web server, and may monitor the user of the net planting status through the Internet. That is, the user can monitor the state of the seedlings by accessing the web server unit through the Internet using the terminal at a long distance regardless of time or place.

FIG. 9 is a block diagram for explaining an integrated control and management method of a standard cultivation facility using the LED light source device of the present invention.

In the present invention, as shown in FIG. 9, integrated management and management methods of standard cultivation facilities are also presented.

The method of the present invention includes a step S10 of setting seedling-specific growth model information, a step S20 of measuring environmental information in a cultivation facility, a step S30 of analyzing the set growth model information and the measured environment information, And controlling the cultivation facility based on the analyzed data (S40).

In addition, the step of analyzing the set growth model information and the measured environmental information includes deriving the standard growth model information using the growth model information corrected by the measured environmental information , The control unit controls the cultivation facility in accordance with the set growth model information in a certain period in the growth cycle, corrects the error to the growth model information set in another specific period, and corrects the measured environment information to the growth model information, The growth model information is derived.

That is, the standard growth model information includes a section in which predetermined growth model information is maintained for each section, and environmental information measured in the corresponding section is replaced with growth model information in the section.

Although the present invention has been fully described by way of example with reference to the accompanying drawings, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Accordingly, the technical scope of the present invention should not be limited to the details described in the specification, but should be defined by the claims.

10: Cultivation facility 20: Storage section
30: integrated control unit 40:
50: measuring section 60: monitor section
70: camera 90: temperature and carbon dioxide control device
100: LED light source device 110: LED module
111: LED element 120: circuit board
130: Base 140: Cover

Claims (10)

A circuit board having a plurality of LED modules arranged in a bar shape;
A base which accommodates the circuit board with an aluminum material and has a plurality of air-cooled grooves formed along the outer surface thereof and one or more water-cooled tubes formed therein;
A cover for sealing the upper surface of the base; And
And an LED control unit having a communication interface and individually or integrally controlling the plurality of LED modules,
Wherein the base is composed of a fixing surface on which the circuit board is mounted and a reflecting portion which forms an inclination gradient at both ends of the fixing surface,
The reflector is provided with 25 to 100 parts by weight of an epoxy resin, 2 to 10 parts by weight of a coating additive, 2 to 10 parts by weight of a foam inhibitor, 6 to 30 parts by weight of a photocatalyst, 6 to 30 parts by weight of a strontium aluminate And 0.5 to 2 parts by weight of propylene carbonate is applied to the LED light source device.
The method according to claim 1,
The LED module
Red, white, and blue LED elements are arranged in a 3: 2: 1 arrangement.
delete delete delete A growing facility that grows crops inside;
A storage unit for storing growth model information, which is environment information according to a growth period of the crop;
A measuring unit for sensing environmental information of the cultivation facility;
An integrated controller for controlling the configuration of the cultivation facility using the LED light source device according to any one of claims 1 and 2 according to the growth model information;
An analysis unit for comparing environmental information sensed by the measurement unit with growth model information stored in a storage unit; And
And a monitor unit for monitoring data from the analysis unit. The integrated control and management system of a standard cultivation facility using the LED light source apparatus.
The method according to claim 6,
The cultivation facility
Wherein the LED light source device is disposed on an upper part of the closed type nursery and the camera is further configured.
8. The method of claim 7,
Wherein the LED light source device controls the illuminance of the nursery under the control of the integrated controller so that the sections are divided and turned on alternately.
8. The method of claim 7,
In the nursery,
Wherein the at least one underground pipe is connected to the blower and is embedded in the ground and the other end is connected to the nursery, and a plurality of inflow holes are formed.
8. The method of claim 7,
The analyzing unit analyzes the environment information sensed by the measuring unit, the growth model information stored in the storage unit, and the real-time image information by the camera to output a control signal to the nursery, or output new growth model information to the storage unit And a control unit for controlling the integrated cultivation facility using the LED light source device.

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