CN217930785U - Plant growth lamp comprehensive test system - Google Patents

Abstract

The utility model relates to a plant growth lamp comprehensive test system, which comprises a frame main body, a first electric cylinder, a second electric cylinder and a soil layer, wherein the frame main body is covered with a shading material, and the frame main body is provided with a bottom base and a top base; the first electric cylinder is arranged on the bottom base in an array mode, the end part of the first electric cylinder is detachably connected with a simulation plant or a test module, and the test of a sheltered scene is realized through the simulation plant; the soil layer is arranged on the bottom base; the second electric cylinder is arranged on the top base in an array mode, and the end part of the second electric cylinder is detachably connected with a light assembly; the lighting angle of the light component is adjustable, and the light component is of a quick detachable and replaceable structure. Compared with the prior art, the utility model discloses can simulate the lighting scene of true LED plant lamp, can carry out the illumination effect test under the multi-factor influences such as accurate light source irradiation angle, shelter from, diffuse reflection, avoid systematic error and human error.

Description

Plant growth lamp comprehensive test system

Technical Field

The utility model belongs to the technical field of the lighting test and specifically relates to a vegetation lamp integrated test system is related to.

Background

The emergence of artificial light sources brings new opportunities for the development of plant lighting, and compared with the traditional agriculture, the plant lighting is not limited by climate and region in four seasons. Under global climate change, market demands such as delicate crop planting, food storage and preservation, food safety and the like promote the rapid development of the plant illumination market. At present, LED plant lighting is increasingly widely applied in the fields of plant factories, greenhouses, gardening design, water culture and the like.

The LED plant lamp has rich wavelength types and is just matched with the spectral range of plant photosynthesis and photomorphogenesis; the half width of the wave width of the frequency spectrum is narrow, and pure monochromatic light and a composite spectrum can be obtained by combination according to needs; the light with specific wavelength can be concentrated to uniformly irradiate crops; not only can adjust flowering and fructification of crops, but also can control plant height and nutrient components of the plants; the system has less heat generation and small occupied space, can be used for a multilayer cultivation three-dimensional combined system, and realizes low heat load and production space miniaturization.

However, the existing test of the LED plant lighting lamp has no unified test condition, mainly depends on a tester to hold or manually put equipment such as a luminance meter, a color rendering index tester, a color temperature tester, a brightness tester and the like for measurement, and cannot realize unified test of fixed conditions, and the existing system error and human error are large, so that the integrated test system of the plant growth lamp with low system error and human error needs to be researched and developed urgently.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a plant growth lamp integrated test system in order to overcome the defect that above-mentioned prior art exists, can simulate the illumination scene of true LED plant lamp, can carry out the illumination effect test that accurate light source shines the angle, shelters from, the diffuse reflection etc. multifactor under influences, has avoided systematic error and human error.

The purpose of the utility model can be realized through the following technical scheme:

the utility model aims at protecting a vegetation lamp integrated test system, including frame main part, first electric jar, second electric jar, soil horizon, wherein specifically:

the light shielding material is covered on the frame main body, and a bottom base and a top base are arranged in the frame main body;

the first electric cylinder is arranged on the bottom base in an array mode, the end part of the first electric cylinder is detachably connected with a simulation plant or a test module, and the test of a sheltered scene is realized through the simulation plant;

the soil layer is arranged on the bottom base;

the second electric cylinder array is arranged on the top base, and the end part of the second electric cylinder is detachably connected with a light assembly.

The lighting assembly in the technical scheme has adjustable irradiation angle and can be quickly disassembled and replaced.

Furthermore, at least one test module is arranged to test a single site, and a plurality of test modules are arranged to realize multi-site test.

Further, the output end of the first electric cylinder is of an opening pipe body structure, the opening pipe body structure forms an expandable structure which is convenient to insert and connect, and the electric cylinder can be conveniently connected with simulation plants with different sizes.

Further, the rod part of the simulation plant and the lower end of the test module are rod body structures which can be inserted into the output end of the first electric cylinder.

Further, the first electric cylinder and the second electric cylinder are both vertically arranged.

Further, the first electric cylinder and the second electric cylinder are uniformly arranged on the bottom base and the top base respectively.

Further, the height of the soil layer is lower than that of the output end of the first electric cylinder.

Further, light subassembly includes female end of connector, public end of connector and LED plant lamp, female end of connector with the end connection of second electric jar, public end of connector and LED plant lamp are connected.

Further, the female end of the connector is connected with the end of the second electric cylinder through a spherical hinge.

Further, external wiring passes through the top base and connects with the connector female terminal.

Compared with the prior art, the utility model has the following technical advantages.

1) Through shading material or partial printing opacity material among this technical scheme, can simulate the illumination scene of true LED plant lamp, specific printing opacity degree can be according to the corresponding adjustment of test standard, only need change the shading material that covers in the frame main part can, comparatively convenient high efficiency.

2) Even array design is also carried out with the second electric jar among this technical scheme, with this LED plant lamp lighting scene that can simulate the scale, the form of arranging of specific LED plant lamp designs according to relevant standard and specific test condition, especially important, but set up LED plant lamp for quick plug structure into the quick grafting that can quick plug structure only need pass through female end of connector and the public end of connector, can realize the quick replacement of different specifications and model LED plant lamp, this wiring again to loaded down with trivial details in the prior art, the winding displacement realizes that the change flow of LED plant lamp has apparent progress.

3) The female end of connector and the tip ball pivot of second electric jar are connected in the new ground in this technical scheme, set up through the articulated fastening degree of ball pivot, can realize the multi-angle slope setting of LED plant lamp, and this has compensatied the vacancy that can't realize the test of scale inclination among the prior art, provides great facility for illumination angle to the illumination effect influence.

4) Soil diffuse reflection effect under the real LED plant lamp can be simulated through laying of the soil layer in the technical scheme, so that an illumination meter, a color rendering index tester, a color temperature tester and a brightness meter in the test module can obtain an illumination test result after diffuse reflection and direct irradiation light superposition.

5) According to the technical scheme, the shielding test of the real plant planting process is realized by simulating the density degree and the height of branches and leaves of the plants, and the illumination effect test under the shielding condition can be obtained.

Drawings

Fig. 1 is a schematic view of the internal structure of the integrated test system for plant growth lamps in the present technical solution;

fig. 2 is a schematic distribution structure diagram of the first electric cylinder in the present technical solution.

In the figure: 1. frame main part, 2, first electric jar, 3, soil horizon, 4, test module, 5, simulation plant, 6, top base, 7, bottom base, 8, second electric jar, 9, ball pivot, 10, LED plant lamp, 11, the female end of connector.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings and specific embodiments. In the technical scheme, the features such as component model, material name, connection structure, control method, algorithm and the like which are not explicitly described are all regarded as common technical features disclosed in the prior art.

The utility model provides a vegetation lamp integrated test system, including frame main part 1, first electric jar 2, soil horizon 3, wherein specifically refer to figure 1 and figure 2.

During specific implementation, frame main part 1 coats and is stamped the shading material, be equipped with bottom base 7 and top base 6 in the frame main part 1, through shading material or partial printing opacity material among this technical scheme, can simulate the illumination scene of real LED plant lamp, specific printing opacity degree can be according to the corresponding adjustment of test standard, only need change frame main part 1 go up the shading material that covers can, comparatively convenient high efficiency.

During specific implementation, first electric jar 2 array is located on the base 7 of bottom, the tip detachably of first electric jar 2 is connected with simulation plant 5 or test module 4, realizes sheltering from the test of scene through simulation plant 5. According to the technical scheme, the shielding test in the real plant planting process is realized by simulating the density degree and height of branches and leaves of the plant 5, and the illumination effect test under the shielding condition can be obtained. The simulated plant 5 is made of high molecular material, and the shape structure and the volume are designed in a simulation way with the real plant 1.

During specific implementation, the soil layer 3 is arranged on the bottom base 7, and the height of the soil layer 3 is lower than that of the output end of the first electric cylinder 2. Soil diffuse reflection effect under the real LED plant lamp can be simulated through laying of the soil layer 3 in the technical scheme, so that an illumination meter, a color rendering index tester, a color temperature tester and a brightness meter in the test module can obtain an illumination test result after diffuse reflection and direct irradiation light superposition.

When the lamp is specifically implemented, the second electric cylinders 8 are arranged on the top base 6 in an array mode, and the end parts of the second electric cylinders 8 are detachably connected with the lamp components. The lighting assembly in the technical scheme has adjustable irradiation angle and can be quickly disassembled and replaced.

During concrete implementation, the output end of the first electric cylinder 2 is an opening pipe body structure, the opening pipe body structure forms an expandable structure convenient to insert and connect, and the expandable structure can be conveniently connected with simulation plants 5 with different sizes. The rod part of the simulation plant 5 and the lower end of the test module 4 are rod body structures which can be inserted into the output end of the first electric cylinder 2. The first electric cylinder 2 and the second electric cylinder 8 are both vertically arranged. The first electric cylinder 2 and the second electric cylinder 8 are uniformly arranged on the bottom base 7 and the top base 6, respectively.

In specific implementation, at least one test module 4 is arranged to test a single locus, or a plurality of test modules 4 are arranged to test multiple loci, as shown in fig. 2, in the technical scheme, the first electric cylinders 2 arranged in an array manner can be used for realizing the large-scale arrangement of the simulated plants 5, and the test modules 4 can be arranged at multiple positions according to requirements, so that detailed locus illumination information in the simulated planting space can be obtained.

During the specific implementation, light components includes female end 11 of connector, public end of connector and LED plant lamp 10, female end 11 of connector with the end connection of second jar 8, public end of connector and LED plant lamp 10 are connected. The female end 11 of the connector is connected with the end of the second electric cylinder 8 through a spherical hinge 9. External wiring passes through the top base 6 and connects with the connector female end 11.

Even array design is also carried out with second electric jar 8 in this technical scheme to this can simulate the LED plant lamp lighting scene of scale, specific LED plant lamp 10 arrange the form and design according to relevant standard and specific test condition, it is especially important, but this technical scheme sets up LED plant lamp 10 into the quick grafting that can quick plug structure only need pass through connector female end 11 and connector public end, can realize the quick replacement of different specifications and model LED plant lamp 10, this rewiring to loaded down with trivial details among the prior art, the winding displacement realizes that the change flow of LED plant lamp 10 has apparent progress.

In addition, the female end 11 of the connector and the end part of the second electric cylinder 8 are connected in a spherical hinge mode innovatively in the technical scheme, the LED plant lamp 10 can be arranged in a multi-angle inclined mode through the hinged fastening degree of the spherical hinge, the vacancy that large-scale inclination angle testing cannot be achieved in the prior art is made up, and great convenience is provided for the influence of the irradiation angle on the illumination effect.

The embodiments described above are intended to facilitate the understanding and use of the invention by those skilled in the art. It will be readily apparent to those skilled in the art that various modifications to these embodiments may be made, and the generic principles described herein may be applied to other embodiments without the use of the inventive faculty. Therefore, the present invention is not limited to the above embodiments, and those skilled in the art should make improvements and modifications within the scope of the present invention according to the disclosure of the present invention.

Claims (10)

1. A plant growth lamp integrated test system, characterized in that includes:

the light shading frame comprises a frame main body (1), wherein a light shading material covers the frame main body (1), and a bottom base (7) and a top base (6) are arranged in the frame main body (1);

the first electric cylinder (2) is arranged on the bottom base (7) in an array manner, and the end part of the first electric cylinder (2) is detachably connected with a simulated plant (5) or a test module (4);

the soil layer (3) is arranged on the bottom base (7);

the second electric cylinder (8) is arranged on the top base (6) in an array mode, and the end portion of the second electric cylinder (8) is detachably connected with a light assembly.

2. A plant growth lamp integrated test system according to claim 1, characterized in that at least one of said test modules (4) is provided.

3. The integrated test system for the plant growth lamp according to claim 1, wherein the output end of the first electric cylinder (2) is an open tube structure.

4. A plant growth lamp integrated test system according to claim 3, characterized in that the rod part of the simulated plant (5) and the lower end of the test module (4) are both rod structures which can be inserted on the output end of the first electric cylinder (2).

5. The integrated test system for plant growth lamps according to claim 1, characterized in that said first electric cylinder (2) and said second electric cylinder (8) are both arranged vertically.

6. A plant growth lamp integrated test system according to claim 1, characterized in that said first electric cylinder (2) and said second electric cylinder (8) are uniformly arranged on the bottom base (7) and the top base (6), respectively.

7. A plant growth lamp integrated test system according to claim 1, characterized in that the height of said soil layer (3) is lower than the height of the output of said first electric cylinder (2).

8. A plant growth lamp integrated test system according to claim 1, characterized in that the light assembly comprises a female connector end (11), a male connector end and a LED plant lamp (10), the female connector end (11) is connected with the end of the second electric cylinder (8), and the male connector end is connected with the LED plant lamp (10).

9. A plant growth lamp integrated test system according to claim 8, characterized in that said female connector end (11) is connected to the end of said second electric cylinder (8) by means of a ball joint (9).

10. A plant growth lamp integrated test system according to claim 8, characterized in that external wiring passes through the top base (6) and connects with the female connector end (11).

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