CN114963065B - LED lamp for mouse phototactic experiment with heat insulation structure - Google Patents

Abstract

The invention discloses an LED lamp for a mouse phototactic experiment with a heat insulation structure, which comprises: the device comprises a workbench, wherein a hot temperature flowing mechanism and an information collecting mechanism are fixedly arranged at the top of the workbench respectively, the hot temperature flowing mechanism comprises a reinforcing plate A, a supporting plate is fixedly arranged at the top of the reinforcing plate A, a slide way A is arranged in the supporting plate, after an LDE lamp tube in a hollow casing is opened, energy consumption generated in the LDE lamp tube continuously diffuses towards the inside of the hollow casing in a heat dissipation mode along with the increase of opening time, a driving part in the mechanism is started at the moment and drives a fan to rotate, cold air is generated in an intersection box at the same time, the cold air is continuously blown into the hollow casing through a wind conveying pipeline A, at the moment, the cold air is also continuously conveyed into a reflux box while cooling the LDE lamp tube, and finally mixed air is discharged from an exhaust outlet.

Description

LED lamp for mouse phototactic experiment with heat insulation structure

Technical Field

The invention relates to the technical field of mouse experimental equipment, in particular to an LED lamp with a heat insulation structure for a mouse phototactic experiment.

Background

The LED bulb is a light emitting diode, is a solid semiconductor device capable of converting electric energy into visible light, and can directly convert electric energy into light to lift illumination, so people can immediately think of various lamps with five colors in a lamp shop, and the core part of the bulb for illumination has three main types: incandescent and fluorescent lamps, gas discharge lamps, however, will soon change in their design, as a new star LED bulb in the field of lighting is moving towards the practical stage, LED was invented in the 60 s of the 20 th century, and in the following decades, its basic use was as an indicator lamp for electronic devices such as radio cassette recorders, in order to fully distribute the lighting potential of volatile LEDs, scientists developed new LED bulbs for lighting, LED air vitamin clean bulbs. The bulb has the characteristics of high efficiency and long service life, can be continuously used for 10 ten thousand hours, is 100 times longer than a common incandescent bulb, and the current LED illuminating lamp of the energy-saving bulb is mainly a high-power white light LED single lamp. LED lighting lamps are a collective name of LED lamps, with further maturation of LED technology, LEDs will get more and better development in the field of design and development of room lighting lamps, and the design of room lighting lamps in the 21 st century will be mainstream by LED lighting lamp bubble design, and meanwhile, the LED lighting lamp has the advantages of fully showing the development trend of energy conservation, health, artistic and humanization, and becoming the leading of room lighting culture.

The mouse is long living in dark moist environment, and then the mouse belongs to anaerobism biology, when being to study the mouse to the range of light that the light source, generally need use the LED lamp to assist, at the adjustable light intensity of in-process of experiment, observes the state of mouse again, and the final use photometer ware obtains experimental data.

However, the existing experimental LED lamp has the following disadvantages:

when the LED lamp is electrified for use, certain energy consumption can be generated by the internal element of the LED lamp, the LED lamp is diffused to the outside through a heat dissipation mode, and in the experimental process, a mouse is in a constant-temperature environment, and because the area of an experimental container is smaller, the heat dissipated by the LED lamp can be continuously diffused to the experimental container, but the high temperature dissipated by a lamp tube cannot be isolated by the existing equipment, so that the temperature in the experimental container is increased, the state of the mouse is influenced, and later experimental data deviation is larger.

Therefore, we propose an LED lamp for a mouse phototactic experiment with a heat insulation structure, so as to solve the above-mentioned problems.

Disclosure of Invention

The invention aims to provide an LED lamp for a mouse phototactic experiment with a heat insulation structure, which is characterized in that a fan is driven by a driving part in a hot-temperature flowing mechanism connected with a workbench to rotate at a high speed, cold air generated by the mechanism is conveyed through a pipeline, so that the cold air continuously enters a hollow shell and is blown on the surface of a lamp tube to cool the lamp tube, and meanwhile, the cold air can carry heat generated on the surface of the lamp tube to be discharged out of equipment, so that the purpose of heat insulation of the lamp tube is achieved, and the problems of the patent are solved.

In order to achieve the above purpose, the present invention provides the following technical solutions: LED lamp for mouse phototactic experiments with thermal-insulated structure includes: the top of the workbench is fixedly provided with a hot temperature flowing mechanism and an information collecting mechanism respectively;

the hot temperature flow mechanism comprises a reinforcing plate A, a supporting plate is fixedly arranged at the top of the reinforcing plate A, a slide way A is arranged in the supporting plate A, a grafting plate is movably arranged in the slide way A, an extension plate is welded on the outer surface wall of the grafting plate, a hollow casing is fixedly arranged on the outer surface wall of the extension plate, a plurality of LDE (light-emitting diode) lamp tubes are fixedly arranged in the hollow casing, an assembly plate is fixedly arranged at the bottom of the inner wall of the workbench, two mounting holes are formed in the assembly plate, a servo motor is fixedly inserted into the inner surface wall of each mounting hole, a limit sleeve is fixedly arranged on the outer surface wall of each servo motor, a transmission rod is fixedly sleeved on the output end of each servo motor, a transmission rod is fixedly sleeved on the outer surface wall of each transmission rod, two air gathering cylinders are fixedly arranged on the outer surface wall of each assembly plate, the two fans are respectively arranged in the air gathering barrel, the bottom of the inner wall of the workbench is fixedly provided with an intersection box and a backflow box respectively, the top of the intersection box is fixedly communicated with a group of air conveying pipelines A, the exhaust ends of the group of air conveying pipelines A penetrate through one side of the outer wall of the hollow casing and are communicated with the inside of the hollow casing, one side of the outer wall of the hollow casing is fixedly communicated with a group of air conveying pipelines B, the exhaust ends of the group of air conveying pipelines B penetrate through the top of the backflow box and are communicated with the inside of the backflow box, one side of the outer wall of the backflow box is provided with an exhaust outlet, the inside of the exhaust outlet is fixedly provided with a slotted baffle plate, the fan is driven by a driving part in the mechanism to rotate at high speed, cold air generated by the fan can be conveyed through the pipelines, so that the cold air continuously enters the hollow casing and is blown on the surface of a lamp tube, the lamp tube is cooled, and meanwhile, cold air can carry heat generated on the surface of the lamp tube to be discharged out of the equipment, so that the aim of heat insulation of the lamp tube is fulfilled.

Preferably, the top of backup pad has seted up inscription hole, the fixed plug in top of backup pad has a set of metal pole, a set of fixed cover is equipped with the connection lantern ring between the outward appearance wall of metal pole, sets up inscription hole, can effectively restrict the vertical swing that the electric telescopic handle produced when doing work.

Preferably, an electric telescopic rod is fixedly inserted between the inscription hole and the inner surface wall of the connecting lantern ring, the output end of the electric telescopic rod is fixedly inserted in the grafting plate, and the electric telescopic rod is arranged, so that the shooting height of the LDE lamp tube can be quickly adjusted.

Preferably, the slide way B has all been seted up to the outer wall both sides of backup pad, the outer wall both sides of grafting board are all fixed mounting has U type gag lever post, two the exterior wall of U type gag lever post is arranged in slide way B's inside respectively, utilizes the relation of connection between U type gag lever post and the slide way B, can effectively restrict the horizontal hunting that the grafting board produced when the grafting board removes, improves the stability when electric telescopic handle is done.

Preferably, the information collecting mechanism comprises a reinforcing plate B, the bottom of the reinforcing plate B is fixedly arranged at the top of the workbench through a set of screws A, four mounting connectors are fixedly arranged at the top of the reinforcing plate B, the reinforcing plate B is arranged, the connection strength between the mounting connectors and the workbench is increased, and meanwhile the size of the experimental container is determined by utilizing the area of the reinforcing plate B.

Preferably, the top fixed mounting of workstation has the external connection board, the top activity of external connection board is inserted and is equipped with two stretching rods, two the equal fixed cover of the outer surface wall of stretching rod is equipped with the protection urceolus, two the inside of protecting the urceolus all is provided with the macro camera, sets up the macro camera, can shoot the state of experiment mouse in real time, provides image reference for the operator when statistics data.

Preferably, the outer surface wall of the workbench is fixedly provided with a reinforcing plate C through a group of screws B, the outer surface wall of the reinforcing plate C is welded with two L-shaped frames, the reinforcing plate C is arranged, and the connection strength between the L-shaped frames and the workbench is increased.

Preferably, the outer surface walls of the two L-shaped frames are fixedly inserted with an inner connecting rod A, a receiver is fixedly sleeved between the outer surface walls of the two inner connecting rods A, a touchable screen is arranged in the receiver, the touchable screen is arranged, and when an operator invokes data, an interface displayed in the touchable screen can be pressed and operated according to the steps displayed in the touchable screen.

Preferably, an output connector is arranged in the external connection board, a group of information wires are fixedly connected in the output connector, the output ends of the information wires are connected with the input end of the receiver, the information wires are arranged, data shot in the macro camera can be quickly transmitted into the receiver, and finally the data are stored in the receiver for later operators to call the image data.

Preferably, the bottom of reinforcing plate A passes through a set of screw fixed mounting at the top of workstation, four round holes have been seted up to the bottom of workstation, and the inside of four round holes is all fixed to be inserted and is connected pole B in the interior, four the outward appearance wall of every in the pole B all movable sleeve is equipped with the universal wheel, confirms the relation of connection between reinforcing plate A and the whole equipment, utilizes the swing joint between pole B and the universal wheel for the equipment possesses flexible removal's ability.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the invention, the heat temperature flow mechanism is arranged, after the LDE lamp tube in the hollow shell is opened, the energy consumption generated in the LDE lamp tube continuously diffuses towards the inside of the hollow shell in a heat dissipation mode along with the increase of the opening time, at the moment, the driving part in the mechanism is started to drive the fan to rotate, meanwhile, cold air is generated in the junction box, and then the cold air is continuously blown into the hollow shell through the conveying pipeline A, at the moment, the cold air cools the LDE lamp tube and simultaneously, the heat in the hollow shell is continuously conveyed into the reflux box, and finally, mixed air is discharged from the air outlet, so that the problem that the heat generated by the lamp tube cannot be isolated by the conventional equipment is effectively solved, the heat generated by the lamp tube is prevented from continuously diffusing into the experimental container, the temperature in the experimental container is continuously increased, the influence on the state of a mouse is caused, and the accuracy of later experimental data is improved.

2. According to the invention, by arranging the information collection mechanism, the image in the experiment container is shot in real time by utilizing the micro-distance camera in the protective outer barrel, the acquired data in the micro-distance camera is rapidly transmitted into the receiver through the information wire in the output connector, when an experimenter counts data in the later period, the experimenter can operate the touch screen and retrieve the data in the receiver for checking, and the light intensity of the LDE lamp tube is usually required to be repeatedly adjusted in order to ensure the accuracy of the data because the experiment process of the mice is higher, visual fatigue can be generated when the experimenter looks at the mice for a long time, the state of the mice is shot in real time by utilizing a plurality of parts in the mechanism, the acquired data is stored, and the experimenter can finish the calibration of the experimental data by retrieving the images recorded in the mechanism in the later period.

Drawings

FIG. 1 is a perspective view of a front view structure of an LED lamp for a mouse phototactic experiment provided with a heat insulation structure;

FIG. 2 is a perspective view of a side view of an LED lamp for a mouse phototactic experiment provided with a heat insulation structure;

FIG. 3 is a perspective view of the middle bottom side structure of the LED lamp for a mouse phototactic experiment provided with a heat insulation structure;

FIG. 4 is an enlarged perspective view of a thermal flow mechanism in a mouse phototactic experiment LED lamp with a heat insulation structure;

FIG. 5 is an enlarged perspective view of the information collecting mechanism in the LED lamp for the mouse phototactic experiment provided with the heat insulation structure;

FIG. 6 is an enlarged perspective view of the top view of the information collecting mechanism in the LED lamp for the mouse phototactic experiment provided with the heat insulation structure;

FIG. 7 is an enlarged perspective view of a part of a structure of an LED lamp for a mouse phototactic experiment provided with a heat insulation structure;

fig. 8 is an enlarged perspective view of a structure a in fig. 7 of an LED lamp for a mouse phototactic experiment provided with a heat insulation structure according to the present invention.

In the figure: 1. a work table; 2. a hot temperature flow mechanism; 201. a reinforcing plate A; 202. a support plate; 203. a slideway A; 204. grafting plate; 205. an extension plate; 206. a hollow jacket; 207. LDE lamp tube; 208. an assembly plate; 209. a servo motor; 210. a limit sleeve; 211. a transmission rod; 212. a fan; 213. a wind gathering barrel; 214. a junction box; 215. a reflow box; 216. a wind conveying pipeline A; 217. a wind conveying pipeline B; 218. inscribing the hole; 219. a metal rod; 220. a connecting collar; 221. an electric telescopic rod; 222. a slideway B; 223. a U-shaped limit rod; 224. an air outlet; 225. a slotted baffle; 3. an information collection mechanism; 301. a reinforcing plate B; 302. installing a joint; 303. an outer connecting plate; 304. a stretching rod; 305. a protective outer cylinder; 306. a macro camera; 307. a reinforcing plate C; 308. an L-shaped frame; 309. an inner connecting rod A; 310. a receiver; 311. a touchable screen; 312. an output joint; 313. an information line; 4. an inner connecting rod B; 5. and a universal wheel.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-8, the present invention provides a technical solution: LED lamp for mouse phototactic experiments with thermal-insulated structure includes: the workbench 1, the top of the workbench 1 is fixedly provided with a hot temperature flow mechanism 2 and an information collection mechanism 3 respectively.

According to the figures 4-7, the thermal flow mechanism 2 comprises a reinforcing plate A201, a supporting plate 202 is fixedly arranged at the top of the reinforcing plate A201, a slide way A203 is arranged in the supporting plate 202, a grafting plate 204 is movably arranged in the slide way A203, an extension plate 205 is welded on the outer surface wall of the grafting plate 204, a hollow casing 206 is fixedly arranged on the outer surface wall of the extension plate 205, a plurality of LDE (light-emitting diode) lamp tubes 207 are fixedly arranged in the hollow casing 206, an assembly plate 208 is fixedly arranged at the bottom of the inner wall of the workbench 1, two mounting holes are formed in the assembly plate 208, a servo motor 209 is fixedly inserted into the inner surface wall of each mounting hole, a limit sleeve 210 is fixedly arranged on the outer surface wall of each servo motor 209, a transmission rod 211 is fixedly sleeved at the output ends of each servo motor 209, a transmission rod 211 is fixedly sleeved on the outer surface wall of each transmission rod 211, two air gathering cylinders 213 are fixedly arranged on the outer surface wall of the assembly plate 208, two fans 212 are respectively arranged in the air gathering barrel 213, an intersection box 214 and a backflow box 215 are respectively and fixedly arranged at the bottom of the inner wall of the workbench 1, a group of air conveying pipelines A216 are fixedly communicated with the top of the intersection box 214, the exhaust ends of the group of air conveying pipelines A216 penetrate through one side of the outer wall of the hollow casing 206 and are communicated with the inside of the hollow casing 206, a group of air conveying pipelines B217 are fixedly communicated with one side of the outer wall of the hollow casing 206, the exhaust ends of the group of air conveying pipelines B217 penetrate through the top of the backflow box 215 and are communicated with the inside of the backflow box 215, an exhaust outlet 224 is formed in one side of the outer wall of the backflow box 215, a slotted baffle 225 is fixedly arranged in the air outlet 224, the fan 212 is driven to rotate at a high speed by a driving component in the mechanism, and cold air generated by the driving component can be conveyed through the pipeline so that the cold air continuously enters the hollow casing 206, and blowing the cold air on the surface of the lamp tube to cool the lamp tube, and meanwhile, the cold air can carry heat generated on the surface of the lamp tube to be discharged out of the device, so that the aim of heat insulation of the lamp tube is fulfilled.

According to fig. 4, an inscription hole 218 is formed on the top of the supporting plate 202, a group of metal rods 219 are fixedly inserted into the top of the supporting plate 202, a connecting collar 220 is fixedly sleeved between the outer surface walls of the group of metal rods 219, and the inscription hole 218 is arranged to effectively limit the longitudinal swing generated when the electric telescopic rod 221 works.

According to fig. 4, an electric telescopic rod 221 is fixedly inserted between the inner hole 218 and the inner surface wall of the connecting collar 220, and the output end of the electric telescopic rod 221 is fixedly inserted in the grafting plate 204, so that the photographing height of the LDE tube 207 can be quickly adjusted by arranging the electric telescopic rod 221.

According to the embodiment shown in fig. 4, the two sides of the outer wall of the supporting plate 202 are provided with the slide ways B222, the two sides of the outer wall of the grafting plate 204 are fixedly provided with the U-shaped limiting rods 223, the outer surface walls of the two U-shaped limiting rods 223 are respectively arranged in the slide ways B222, and the connection relationship between the U-shaped limiting rods 223 and the slide ways B222 is utilized to effectively limit the left-right swing generated by the grafting plate 204 when the grafting plate 204 moves, so that the stability of the electric telescopic rod 221 during the working is improved.

According to fig. 5, the information collecting mechanism 3 comprises a reinforcing plate B301, wherein the bottom of the reinforcing plate B301 is fixedly mounted on the top of the workbench 1 through a set of screws a, four mounting joints 302 are fixedly mounted on the top of the reinforcing plate B301, the strength of connection between the mounting joints 302 and the workbench 1 is increased through the arrangement of the reinforcing plate B301, and meanwhile, the size of the experimental container is determined by utilizing the area of the reinforcing plate B301.

According to the figure 5, the top of the workbench 1 is fixedly provided with an external connection plate 303, the top of the external connection plate 303 is movably inserted with two stretching rods 304, the outer surface walls of the two stretching rods 304 are fixedly sleeved with protective outer cylinders 305, the interiors of the two protective outer cylinders 305 are respectively provided with a macro camera 306, and the states of experimental mice can be photographed in real time by arranging the macro cameras 306, so that image references are provided for operators in statistics.

According to fig. 6, the outer surface wall of the workbench 1 is fixedly provided with a reinforcing plate C307 by a set of screws B, two L-shaped frames 308 are welded on the outer surface wall of the reinforcing plate C307, and the strength of connection between the L-shaped frames 308 and the workbench 1 is increased by arranging the reinforcing plate C307.

According to fig. 6, the outer walls of the two L-shaped frames 308 are fixedly inserted with inner connecting rods a309, a receiver 310 is fixedly sleeved between the outer walls of the two inner connecting rods a309, a touch screen 311 is arranged inside the receiver 310, and when an operator calls data, the operator can press the interface displayed in the touch screen 311 and operate according to the steps displayed in the touch screen 311 by arranging the touch screen 311.

According to fig. 5-6, an output connector 312 is disposed in the external board 303, a group of information lines 313 are fixedly connected in the output connector 312, the output ends of the group of information lines 313 are connected with the input end of the receiver 310, and by setting the information lines 313, the data shot in the macro camera 306 can be quickly transmitted into the receiver 310, and finally the data can be stored in the receiver 310 for later operators to call the image data.

According to the illustration shown in fig. 1-3, the bottom of reinforcing plate A201 is fixed at the top of workstation 1 through a set of screw, four round holes have been seted up to the bottom of workstation 1, and the inside of four round holes is all fixed to be inserted and is equipped with the internal connection pole B4, and the outward appearance wall of each in four internal connection poles B4 all movable sleeve is equipped with universal wheel 5, confirms the relation of connection between reinforcing plate A201 and the whole equipment, utilizes the swing joint between internal connection pole B4 and the universal wheel 5 for the equipment possesses flexible removal's ability.

The whole mechanism achieves the following effects: firstly, the whole equipment is moved to a designated working area by utilizing the movable connectivity between an inner connecting rod B4 and a universal wheel 5, then the equipment is electrified, a designated number of transparent glass is installed according to the quantity of slots in an installation joint 302, then a mouse is put into an assembled experimental container, an LDE lamp tube 207 in a hollow sleeve shell 206 is started, an electric telescopic rod 221 in a connecting lantern ring 220 is utilized and acts on a grafting plate 204 in a slideway A203, the LDE lamp tube 207 is regulated to a designated irradiation height, a servo motor 209 in an assembly plate 208 is started at the moment along with the increase of the irradiation time of the LDE lamp tube 207, a fan 212 on a transmission rod 211 is driven to rotate at a high speed, cold air generated by the high speed rotation is conveyed through a wind gathering barrel 213 and enters a junction box 214, and then, by utilizing connectivity between the junction box 214 and the air conveying pipeline A216, cold air in the junction box 214 continuously enters the hollow casing 206, mixed air further doped with heat continuously enters the backflow box 215 through conveying of the air conveying pipeline B217, and finally is discharged out of the equipment from the air outlet 224, when the equipment is in an experiment process, images in an experiment container are shot in real time by utilizing the macro camera 306 in the protective outer barrel 305, data acquired in the macro camera 306 are quickly transmitted into the receiver 310 through the information line 313 in the output connector 312, and when an experimenter performs later statistics, the experimenter operates the touchable screen 311 and invokes the data in the receiver 310 to check.

Although the present invention has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present invention.

Claims (7)

1. LED lamp for mouse phototactic experiments with heat insulation structure, its characterized in that: comprising the following steps: the device comprises a workbench (1) and a fan (212), wherein a hot temperature flow mechanism (2) and an information collection mechanism (3) are respectively and fixedly arranged at the top of the workbench (1);

the hot temperature flow mechanism (2) comprises a reinforcing plate A (201), a supporting plate (202) is fixedly arranged at the top of the reinforcing plate A (201), a slide A (203) is arranged in the supporting plate (202), a grafting plate (204) is movably arranged in the slide A (203), an extension plate (205) is welded on the outer surface wall of the grafting plate (204), a hollow casing (206) is fixedly arranged on the outer surface wall of the extension plate (205), a plurality of LDE lamp tubes (207) are fixedly arranged in the hollow casing (206), an assembly plate (208) is fixedly arranged at the bottom of the inner wall of the workbench (1), two mounting holes are formed in the assembly plate (208), a servo motor (209) is fixedly inserted into the inner surface wall of each mounting hole, a limit sleeve (210) is fixedly arranged on the outer surface wall of each servo motor (209), a transmission rod (211) is fixedly sleeved on the output end of each servo motor, a transmission rod (208) is fixedly sleeved on the outer surface wall of each transmission rod (211), a plurality of LDE lamp tubes (207) are fixedly arranged on the inner surface wall of each transmission rod (208), two air cylinders (213) are fixedly arranged on the inner surfaces of the two air cylinders (213) and the inner surfaces (213) of the two air cylinders (213) are fixedly arranged on the inner surfaces of the two air cylinders (213), the top of the junction box (214) is fixedly communicated with a group of air conveying pipelines A (216), the exhaust ends of the group of air conveying pipelines A (216) penetrate through one side of the outer wall of the hollow casing (206) and are communicated with the inside of the hollow casing (206), one side of the outer wall of the hollow casing (206) is fixedly communicated with a group of air conveying pipelines B (217), the exhaust ends of the group of air conveying pipelines B (217) penetrate through the top of the backflow box (215) and are communicated with the inside of the backflow box (215), an exhaust outlet (224) is formed in one side of the outer wall of the backflow box (215), and a slotted baffle (225) is fixedly arranged in the exhaust outlet (224);

the information collection mechanism (3) comprises a reinforcing plate B (301), wherein the bottom of the reinforcing plate B (301) is fixedly arranged at the top of the workbench (1) through a group of screws A, and four mounting joints (302) are fixedly arranged at the top of the reinforcing plate B (301);

an outer connecting plate (303) is fixedly arranged at the top of the workbench (1), two stretching rods (304) are movably inserted into the top of the outer connecting plate (303), protective outer cylinders (305) are fixedly sleeved on the outer surface walls of the two stretching rods (304), and micro-distance cameras (306) are arranged in the two protective outer cylinders (305);

the inside of external board (303) is provided with output joint (312), the inside fixedly connected with of output joint (312) is a set of information line (313), and a set of the output of information line (313) all is connected with the input of receiver (310).

2. The LED lamp for mouse phototactic experiment provided with a heat insulation structure according to claim 1, wherein: an inscription hole (218) is formed in the top of the supporting plate (202), a group of metal rods (219) are fixedly inserted into the top of the supporting plate (202), and a connecting sleeve ring (220) is fixedly sleeved between the outer surface walls of the group of metal rods (219).

3. The LED lamp for mouse phototactic experiment provided with a heat insulation structure according to claim 2, wherein: an electric telescopic rod (221) is fixedly inserted between the inner surface wall of the inner connecting hole (218) and the inner surface wall of the connecting lantern ring (220), and the output end of the electric telescopic rod (221) is fixedly inserted in the grafting plate (204).

4. The LED lamp for mouse phototactic experiment provided with a heat insulation structure according to claim 1, wherein: slide B (222) have all been seted up to the outer wall both sides of backup pad (202), the outer wall both sides of grafting board (204) are all fixed mounting has U type gag lever post (223), and two the exterior wall of U type gag lever post (223) is arranged in the inside of slide B (222) respectively.

5. The LED lamp for mouse phototactic experiment provided with a heat insulation structure according to claim 1, wherein: the outer surface wall of the workbench (1) is fixedly provided with a reinforcing plate C (307) through a set of screws B, and two L-shaped frames (308) are welded on the outer surface wall of the reinforcing plate C (307).

6. The LED lamp for mouse phototactic experiments with heat insulation structure according to claim 5, wherein: the outer surface walls of the two L-shaped frames (308) are fixedly inserted with inner connecting rods A (309), a receiver (310) is fixedly sleeved between the outer surface walls of the two inner connecting rods A (309), and a touchable screen (311) is arranged in the receiver (310).

7. The LED lamp for mouse phototactic experiment provided with a heat insulation structure according to claim 1, wherein: the bottom of reinforcing plate A (201) is through the top of a set of screw fixed mounting at workstation (1), four round holes have been seted up to the bottom of workstation (1), and the inside of four round holes is all fixed to insert and is equipped with interconnect pole B (4), four the outward appearance wall of every in interconnect pole B (4) all movable sleeve is equipped with universal wheel (5).