CN114414483B - Experimental device for material with physical light function - Google Patents

Abstract

The invention discloses an experimental device for a physical light functional material, which is characterized in that a conversion adjusting component is arranged between brackets, a guide groove is arranged at the bottom end of a guide rail, a rotating ring is sleeved on the outer sides of a fixed frame and a sliding frame in a rotating way, a C-shaped clamp is welded at one end of a fixed length connecting rod, material clamping components are arranged in clamping grooves at the outer sides of a plurality of fixed frames, an auxiliary supporting component is arranged at one side of the guide rail, a sliding rod is fixedly arranged at the middle part of the fixed frame and is fixedly penetrated at the inner part of the supporting groove, and the bottom ends of adjacent supporting thin plates are connected through movable shafts.

Description

Experimental device for material with physical light function

Technical Field

The invention relates to the technical field of physical experiment devices, in particular to an experiment device for a physical light functional material.

Background

The optical functional material refers to an optical material which utilizes the principle that the optical property of the material changes under the action of external fields such as electricity, light, magnetism, heat, sound, force and the like to realize the detection, modulation and energy or frequency conversion of an incident optical signal. In order to determine the nature of a material, multiple experiments need to be performed to achieve accurate results.

However, in the current optical functional material, the material is usually directly placed in the experimental environment, and can only be singly realized at a time due to space limitation, and when the results under different conditions are required to be determined, the material needs to be taken out and placed in another detection device, so that the operation is complex and time-consuming, and the experimental efficiency is low.

Disclosure of Invention

The invention provides an experimental device for a physical light functional material, which can effectively solve the problems that materials are required to be taken out and put into another detection device when the results under different conditions are required to be determined, the operation is complex and time-consuming, and the experimental efficiency is low.

In order to achieve the above purpose, the present invention provides the following technical solutions: the testing and detecting device is respectively arranged at the top ends of fixed-length connecting rods at two ends of the guide rail, so that the testing device and the corresponding detecting device can be conveniently and rapidly switched.

And the auxiliary supporting component is used for placing materials and various tools without preventing the conversion adjusting component from being used.

The material clamping assembly clamps various materials to be detected in different shapes and sizes, and the material clamping assembly is matched with the conversion adjusting assembly to improve the experiment efficiency of the comparison of multiple groups of materials.

Preferably, a conversion adjusting component is arranged between the two brackets, and comprises a guide rail, a guide groove, a fixing frame, a sliding frame, an internal thread block, a screw rod, a driving motor, a rotating ring, a clamping groove, a limit baffle, an extrusion pipe, a spring, a steel ball, a ball groove, a fixed-length connecting rod, a C-shaped clamp, an extrusion screw rod and an anti-skid gasket;

the guide rail is characterized in that two ends of the guide rail are respectively connected with a bracket through screws, a guide groove is formed in the bottom end of the guide rail, a fixing frame is fixedly arranged in the middle of the guide rail, sliding frames are sleeved at two ends of the guide rail, an internal thread block is welded at the position, inside the guide groove, of the sliding frames, screw rods are arranged at two ends of the guide rail, one end of each screw rod is rotatably connected with a driving motor through a through bracket, rotating rings are rotatably sleeved at the outer sides of the fixing frame and the sliding frames, clamping grooves are uniformly formed in the outer sides of the rotating rings, limit baffles are fixedly arranged on two side surfaces of the rotating rings in a welded mode, an extrusion pipe is fixedly arranged in the middle of each limit baffle in a penetrating mode, steel balls are connected at one end inside the extrusion pipe through springs, and spherical grooves are uniformly formed in the positions, corresponding to the steel balls, of the fixing frame and the sliding frames;

the clamping groove inside joint in a plurality of the carriage outsides has the fixed length connecting rod, fixed length connecting rod one end welding has C type card, the extrusion screw rod is all installed through the screw hole penetration in C type card both sides, the extrusion screw rod is in the inside one end bonding of C type card has anti-skidding gasket, a plurality of the clamping groove internally mounted in the mount outside has material clamping assembly.

Preferably, the driving motor input end is electrically connected with the external power supply output end, and the bottom surface of the guide rail is parallel to the horizontal plane.

Preferably, one end of the extrusion pipe is closed, and the inner diameter of the extrusion pipe, the diameter of the steel ball and the diameter of the spherical groove are all equal.

Preferably, the outer diameters of the sliding frame and the fixed frame are equal, the limit baffle is positioned at the gap position between the sliding frame and the rotating ring, and one side of the limit baffle, which is close to the sliding frame, is a smooth plane.

Preferably, an auxiliary supporting component is arranged on one side of the guide rail, and comprises a supporting groove, a sliding rod, a keel plate, a fixed shaft, a supporting thin plate, a movable shaft, an anti-slip film and a protective ball;

the support groove is formed in the front of the guide rail, a sliding rod is fixedly arranged in the middle of the fixing frame at the position of the inner part of the support groove in a penetrating mode, a plurality of keel plates are symmetrically sleeved on the two sides of the fixing frame in a sliding mode, fixing shafts are rotatably arranged on the two sides of the top end of each keel plate, a support thin plate is connected to the outer side of each fixing shaft, the bottom ends of the adjacent support thin plates are connected through movable shafts, an anti-slip film is adhered to the top surface of each support thin plate, and protective balls are evenly movably embedded on one side, close to the sliding frame, of each keel plate.

Preferably, the side surface of the keel plate is L-shaped, and the supporting groove and the keel plate are mutually matched.

Preferably, the material clamping assembly comprises an internal thread pipe, an adjusting screw, a sleeve, a sliding plate, a mounting frame, a flat plate, an iron sheet, a flat plate groove, an adhesive joint, an air bag, a separation sheet, a rubber strip, a magnetic attraction frame, a sliding frame and an aluminum iron boron magnet;

the utility model discloses a fixing frame, including fixing frame, internal thread pipe, mounting frame, iron sheet, air bag, spacer, magnetic attraction frame, sliding frame, iron sheet, air bag, spacer, air bag, magnetic attraction frame, iron sheet, air bag, spacer, magnetic attraction frame, sliding frame, aluminum iron boron magnet, iron sheet, air bag and spacer.

Preferably, the spacing between the side surfaces of the isolating sheet and the iron sheet is 0.5mm, and the side, away from the air bag, of the isolating sheet is a rough plane.

Preferably, the sliding frame both ends slip joint is in the magnetism and inhale the frame inboard, aluminium iron boron magnet is close to iron sheet one side and installing frame inner wall parallel and level.

Compared with the prior art, the invention has the beneficial effects that: the invention has scientific and reasonable structure and safe and convenient use;

1. the device is provided with a conversion adjusting component, the testing and detecting device is respectively arranged at the top ends of fixed-length connecting rods at two ends of the guide rail, the material is fixed at the position of the fixing frame, the screw rod drives the detecting device to be close to the material, the testing device and the corresponding detecting device can be conveniently and rapidly switched through the rotation of the rotating ring, multiple realization operations are rapidly carried out under the condition that the material to be detected is not taken out, the time of time operation is reduced, and the efficiency of experiments is improved.

2. Be provided with auxiliary stay assembly, through pulling fossil fragments board along the supporting groove, can expand and support the sheet metal to conveniently put material and various instrument, and this operation in-process, fossil fragments board position removes along with the conversion of conversion regulation subassembly, prevents to hinder the use of conversion regulation subassembly when conveniently taking the material instrument.

3. Be provided with material clamping assembly, the material is put between the iron sheet after the adjustment position, and the iron sheet position can change at will, is fit for the material of waiting to detect of centre gripping various different shapes and sizes, and the rotation ring of cooperation conversion adjustment assembly conveniently switches the material rapidly, conveniently carries out multiunit contrast experiment, and accommodation is wide, and through sliding the magnet inhale the interior aluminium iron boron magnet of frame can accomplish the operation of centre gripping and unclamping rapidly, easy operation is convenient, further improves the efficiency of experiment.

In conclusion, conversion adjusting part is used for fixed test and detection device, and convenient quick switch experiment item, and material clamping assembly is used for fixed detection material, and convenient cooperation conversion adjusting part is experimented, further improves the experimental efficiency of multiunit, and auxiliary stay subassembly is supplementary material and the experimental apparatus of placing to the conversion of cooperation conversion adjusting part changes deformation, and it is more convenient to use.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention.

In the drawings:

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic structural view of a switching regulator assembly of the present invention;

FIG. 3 is a schematic view of the mounting structure of the limit stop of the present invention;

fig. 4 is a schematic view of the mounting structure of the keel plate of the invention;

FIG. 5 is a schematic view of the structure of area A of FIG. 4 in accordance with the present invention;

FIG. 6 is a schematic view of the structure of the material clamping assembly of the present invention;

FIG. 7 is a schematic view of the mounting structure of the iron sheet of the present invention;

reference numerals in the drawings: 1. a bracket;

2. a switching adjustment assembly; 201. a guide rail; 202. a guide groove; 203. a fixing frame; 204. a carriage; 205. an internal thread block; 206. a screw rod; 207. a driving motor; 208. a rotating ring; 209. a clamping groove; 210. a limit baffle; 211. extruding the tube; 212. a spring; 213. steel balls; 214. a spherical groove; 215. a fixed-length connecting rod; 216. a C-type card; 217. extruding a screw; 218. an anti-slip gasket;

3. an auxiliary support assembly; 301. a support groove; 302. a slide bar; 303. a keel plate; 304. a fixed shaft; 305. a support sheet; 306. a movable shaft; 307. an anti-slip film; 308. a protective ball;

4. a material clamping assembly; 401. an internally threaded tube; 402. adjusting a screw; 403. a sleeve; 404. a slide plate; 405. a mounting frame; 406. a flat plate; 407. iron sheet; 408. a flat plate groove; 409. an adhesive interface; 410. an air bag; 411. a separator sheet; 412. a rubber strip; 413. a magnetic attraction frame; 414. a sliding frame; 415. an aluminum iron boron magnet.

Detailed Description

The preferred embodiments of the present invention will be described below with reference to the accompanying drawings, it being understood that the preferred embodiments described herein are for illustration and explanation of the present invention only, and are not intended to limit the present invention.

Examples: as shown in fig. 1, the invention provides a technical scheme for a physical optical functional material experimental device, which comprises a conversion adjusting component 2, wherein a testing device and a detecting device are respectively arranged at the top ends of fixed-length connecting rods 215 at two ends of a guide rail 201, so that the testing device and the corresponding detecting device can be conveniently and rapidly switched.

The auxiliary support assembly 3 places materials and various tools without interfering with the use of the conversion adjustment assembly 2.

And the material clamping assembly 4 clamps various materials to be detected in different shapes and sizes, and is matched with the conversion adjusting assembly 2, so that the experimental efficiency of comparison of multiple groups of materials is improved.

As shown in fig. 2-3, a conversion adjusting component 2 is arranged between two brackets 1, and the conversion adjusting component 2 comprises a guide rail 201, a guide groove 202, a fixing frame 203, a sliding frame 204, an internal thread block 205, a screw rod 206, a driving motor 207, a rotating ring 208, a clamping groove 209, a limit baffle 210, an extrusion pipe 211, a spring 212, a steel ball 213, a ball groove 214, a fixed-length connecting rod 215, a C-shaped clamp 216, an extrusion screw 217 and an anti-skid gasket 218;

the two ends of the guide rail 201 are respectively connected with the support 1 through screws, the bottom end of the guide rail 201 is provided with a guide groove 202, the middle part of the guide rail 201 is fixedly provided with a fixing frame 203, the two ends of the guide rail 201 are sleeved with a sliding frame 204, the sliding frame 204 is positioned at the position of a gap between the sliding frame 204 and the rotating ring 208, one side of the limiting baffle 210 close to the sliding frame 204 is a smooth plane, the rotating ring 208 is conveniently blocked by the limiting baffle 210, the rotating ring 208 is prevented from being separated from the sliding frame 204, the middle part of the limiting baffle 210 is fixedly penetrated and is provided with an extrusion tube 211, one end inside the extrusion tube 211 is connected with a 213 through a spring 212, the bottom surface of the guide rail 201 is parallel to the horizontal plane, the experiment is convenient to carry out, the outer sides of the fixing frame 203 and the sliding frame 204 are both rotationally sleeved with a rotating ring 208, the outer sides of the rotating ring 208 are uniformly provided with clamping grooves 209, the outer diameters of the sliding frame 204 and the fixing frame 203 are equal, the limiting baffle 210 is positioned at the gap between the sliding frame 204 and the rotating ring 208, the side of the limiting baffle 210 is close to the sliding frame 204, the side of the sliding frame 204 is a smooth plane, the limiting baffle 208 is conveniently blocked by the sliding frame 204, the limiting baffle 208 is fixedly penetrated by an extrusion tube 211, the middle part of the limiting baffle 211 is fixedly arranged, the inner end of the fixing frame 211 is connected with the spring 212, the inside end of the guide rail is connected with 213, the steel balls 213, the inside diameter of the steel balls is equal to the steel balls 213, the diameter of the steel balls are equal to the diameter of the steel balls 213, and the steel balls are equal to the diameter of the steel balls, and the steel balls are 213 and the diameter of the steel balls are equal to the diameter of the steel balls and the inside 213 and the diameter of the extrusion tube 211 and the steel balls and the 213 and the diameter of the 213 and the equal to be sealed;

the inside joint of the clamping groove 209 in the outside of a plurality of carriage 204 has fixed length connecting rod 215, and fixed length connecting rod 215 one end welding has C type card 216, and the extrusion screw 217 is all installed through the screw hole penetration in C type card 216 both sides, and extrusion screw 217 is in the inside one end bonding of C type card 216 to have anti-skidding gasket 218, and the inside installation of clamping groove 209 in the outside of a plurality of holders 203 has material clamping assembly 4.

As shown in fig. 4 to 5, an auxiliary supporting assembly 3 is installed at one side of the guide rail 201, and the auxiliary supporting assembly 3 includes a supporting groove 301, a sliding rod 302, a keel plate 303, a fixed shaft 304, a supporting thin plate 305, a movable shaft 306, an anti-slip film 307 and a protective ball 308;

the supporting groove 301 is formed in the front face of the guide rail 201, the sliding rods 302 are fixedly arranged at the inner part of the supporting groove 301 in a penetrating mode in the middle of the fixing frame 203, the sliding rods 302 are symmetrically sleeved with a plurality of keel plates 303 in a sliding mode at two sides of the fixing frame 203, the side faces of the keel plates 303 are L-shaped, the supporting groove 301 and the keel plates 303 are mutually matched, the keel plates 303 slide in the supporting groove 301 conveniently, fixing shafts 304 are rotatably arranged on two sides of the top end of the keel plates 303 respectively, a supporting thin plate 305 is connected to the outer side of each fixing shaft 304, the bottom ends of adjacent supporting thin plates 305 are connected through movable shafts 306, anti-slip films 307 are adhered to the top faces of the supporting thin plates 305, and protective balls 308 are evenly movably embedded on one side, close to the sliding frames 204, of the keel plates 303.

As shown in fig. 6 to 7, the material holding assembly 4 includes an internally threaded tube 401, an adjusting screw 402, a sleeve 403, a slide plate 404, a mounting frame 405, a flat plate 406, an iron piece 407, a flat plate groove 408, an adhesive port 409, an air bag 410, a spacer sheet 411, a rubber strip 412, a magnet frame 413, a slide frame 414, and an alfeborium magnet 415;

the internal thread pipe 401 is installed in the joint groove 209 in the mount 203 outside, there is adjusting screw 402 at the internal thread pipe 401 top through threaded connection, adjusting screw 402 one end welding has sleeve 403, sleeve 403 both ends all slide and cup joint slide 404, slide 404 side both ends welding has installing frame 405, installing frame 405 middle part welding has dull and stereotyped 406, dull and stereotyped 406 middle part sliding cup joint iron sheet 407 has been seted up to the dull and stereotyped 406 department that corresponds to dull and stereotyped 407, the bonding interface 409 has been seted up to iron sheet 407 side, bonding interface 409 inside bonds has gasbag 410, gasbag 410 both sides all bond and have spacer 411, spacer 411 and iron sheet 407 side interval is 0.5mm, spacer 411 is the rough plane on one side away from gasbag 410, prevent iron sheet 407 bond each other before the fixed material, the one end edge that iron sheet 407 is close to each other has all bonded rubber strip 412, installing frame 405 one side welding has magnet frame 413, inside slidable mounting frame 414 has, the fixed aluminium iron boron magnet 415 of inlaying of sliding frame 414 both ends sliding joint in magnet frame 413 inboard, aluminium boron magnet 415 is close to one side of 407 and is close to magnet 415 to the parallel and level of installation.

The optical functional material refers to an optical material which utilizes the principle that the optical property of the material changes under the action of external fields such as electricity, light, magnetism, heat, sound, force and the like to realize the detection, modulation and energy or frequency conversion of an incident optical signal. In order to determine the nature of a material, multiple experiments need to be performed to achieve accurate results.

The working principle and the using flow of the invention are as follows: the guide rail 201 is placed at the experimental position, the support 1 supports, devices generating external fields such as electricity, light, magnetism, heat, sound, force and the like are respectively clamped in the C-shaped clamp 216, the extrusion screw 217 is rotated, the extrusion screw 217 is extruded and fixed through the anti-slip gasket 218, then the fixed-length connecting rod 215 is sequentially clamped in the clamping groove 209 of the rotating ring 208 at one end of the guide rail 201, in the same way, a device for detecting optical signals is placed at the other end of the guide rail 201, the testing device and the corresponding detection device can be conveniently and rapidly switched through the rotation of the rotating ring 208 outside the sliding frame 204, in the rotation process, the steel balls 213 in the extrusion pipe 211 are sequentially clamped in the spherical groove 214 through the springs 212 to be fixed, the stability of the rotating ring 208 in the detection process is ensured, then, the material is placed between the iron sheets 407 after the adjustment position, the sliding plate 404 slides along the sleeve 403, the flat plate groove 408 of the iron sheets 407 slides along the flat plate 406, the position of the iron sheets 407 can be changed at will until the space between the iron sheets 407 is matched with the bottom end of the material, which is suitable for clamping various materials to be detected with different shapes and sizes, then the sliding frame 414 in the magnetic frame 413 is pulled to enable the aluminum iron boron magnet 415 to adsorb the iron sheets 407, the iron sheets 407 are magnetized and are mutually adsorbed and close, at the moment, the air bags 410 are extruded and deformed, the air bags 410 close to the detection materials can clamp the material, the rough separation sheet 411 is used for preventing the material from sliding and falling off, the bottom end of the internal thread tube 401 is clamped in the clamping groove 209 of the fixing frame 203, the adjusting screw 402 is rotated to enable the material to be aligned with the detection equipment, the installation is simple and convenient, the rotating ring 208 of the switching adjusting assembly 2 is matched to conveniently and rapidly switch the material, the driving motor 207 is started again, the driving motor 207 drives the screw 206 to rotate, the sliding frame 204 is driven to be close to the detection materials, and the light irradiates the material to perform experiments, the experiment device has the advantages that a plurality of groups of comparison experiments are convenient to carry out, the application range is wide, the installation and the operation are simple and convenient, and the experiment efficiency is further improved;

by pulling the keel plate 303 along the support slot 301, the support sheet 305 can be unfolded to facilitate placement of materials and various tools, and during this operation, the position of the keel plate 303 moves with the conversion of the conversion regulating assembly 2, and when the rotating ring 208 rotates, the fixed length connecting rod 215 will strike the protective balls 308 of the keel plate 303, so that the position of the keel plate 303 changes, thereby facilitating the use of the materials and tools while preventing the blockage of the use of the conversion regulating assembly 2;

in conclusion, conversion adjusting part 2 is used for fixed test and detection device, conveniently switches experimental project rapidly, and material clamping part 4 is used for fixed detection material, conveniently cooperates conversion adjusting part 2 to experiment, further improves the experimental efficiency of multiunit, and auxiliary stay subassembly 3 is supplementary material and the experimental apparatus of placing to cooperate conversion adjusting part 2's conversion and change deformation, it is more convenient to use.

Finally, it should be noted that: the foregoing is merely a preferred example of the present invention, and the present invention is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present invention has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (9)

1. The experimental device for the physical light functional material is characterized in that: comprising the following steps:

the conversion adjusting component (2) is used for respectively installing the testing and detecting devices at the top ends of fixed-length connecting rods (215) at the two ends of the guide rail (201) so as to conveniently and rapidly switch the testing devices and the corresponding detecting devices;

an auxiliary support assembly (3) for placing materials and various tools without interfering with the use of the conversion adjustment assembly (2);

the material clamping assembly (4) clamps various materials to be detected in different shapes and sizes, and the material clamping assembly is matched with the conversion adjusting assembly (2) to improve the experiment efficiency of comparison of multiple groups of materials;

a conversion adjusting component (2) is arranged between the two brackets (1), and the conversion adjusting component (2) comprises a guide rail (201), a guide groove (202), a fixing frame (203), a sliding frame (204), an internal thread block (205), a screw rod (206), a driving motor (207), a rotating ring (208), a clamping groove (209), a limit baffle (210), an extrusion pipe (211), a spring (212), a steel ball (213), a spherical groove (214), a fixed-length connecting rod (215), a C-shaped clamp (216), an extrusion screw (217) and an anti-slip gasket (218);

guide slots (202) are formed in the two ends of the guide rail (201) through screw connecting supports (1), fixing frames (203) are fixedly mounted in the middle of the guide rail (201), sliding frames (204) are fixedly sleeved at the two ends of the guide rail (201), inner thread blocks (205) are welded at the inner parts of the guide slots (202) in a penetrating mode, screw rods (206) are mounted at the two ends of the guide rail (201), one ends of the screw rods (206) are rotatably connected with driving motors (207) through the supports (1), rotating rings (208) are rotatably sleeved at the outer sides of the fixing frames (203) and the sliding frames (204), clamping grooves (209) are uniformly formed in the outer sides of the rotating rings (208), limit baffles (210) are fixedly arranged at the two sides of the rotating rings (208) in a penetrating mode, extrusion pipes (211) are fixedly mounted at the middle of the limiting baffles, steel balls (213) are connected at one ends of the inner parts of the extrusion pipes (211) through springs (212), and the positions, corresponding to the steel balls (213) of the fixing frames (203) and the sliding frames (204) are uniformly provided with balls (214);

a plurality of clamping grooves (209) in the outer side of the sliding frame (204) are internally clamped with fixed-length connecting rods (215), C-shaped clamps (216) are welded at one ends of the fixed-length connecting rods (215), extrusion screws (217) are installed on two sides of each C-shaped clamp (216) in a penetrating mode through threaded holes, anti-slip gaskets (218) are adhered to one end of each extrusion screw (217) in the inner side of each C-shaped clamp (216), and a plurality of clamping grooves (209) in the outer side of the fixing frame (203) are internally provided with material clamping assemblies (4).

2. The experimental device for a physical light functional material according to claim 1, wherein the input end of the driving motor (207) is electrically connected to the output end of the external power supply, and the bottom surface of the guide rail (201) is parallel to the horizontal plane.

3. The experimental device for a physical light functional material according to claim 1, wherein one end of the extrusion tube (211) is closed, and the inner diameter of the extrusion tube (211), the diameter of the steel ball (213) and the diameter of the spherical groove (214) are all equal.

4. The experimental device for a physical light functional material according to claim 1, wherein the outer diameters of the sliding frame (204) and the fixed frame (203) are equal, the limit baffle (210) is positioned at a gap position between the sliding frame (204) and the rotating ring (208), and one side of the limit baffle (210) close to the sliding frame (204) is a smooth plane.

5. An experimental device for a physical light functional material according to claim 1, wherein an auxiliary supporting component (3) is installed on one side of the guide rail (201), and the auxiliary supporting component (3) comprises a supporting groove (301), a sliding rod (302), a keel plate (303), a fixed shaft (304), a supporting thin plate (305), a movable shaft (306), an anti-slip film (307) and a protective ball (308);

the utility model discloses a support sheet (305) is connected with support sheet (305), support sheet (305) bottom is connected through loose axle (306), support sheet (305) top surface bonds and has anti-skidding film (307), even movable inlay in keel sheet (303) side near carriage (204) has protection ball (308) in the symmetry sliding sleeve of slide bar (302) department in mount (203) both sides have been put in, fixed axle (304) are all installed in rotation on keel sheet (303) top both sides, the fixed axle (304) outside is connected with support sheet (305).

6. The experimental device for a physical light functional material according to claim 5, wherein the side surface of the keel plate (303) is L-shaped, and the supporting groove (301) and the keel plate (303) are engaged with each other.

7. The experimental device for a physical light functional material according to claim 1, wherein the material clamping assembly (4) comprises an internally threaded tube (401), an adjusting screw (402), a sleeve (403), a slide plate (404), a mounting frame (405), a flat plate (406), an iron sheet (407), a flat plate groove (408), an adhesive port (409), an air bag (410), a separation sheet (411), a rubber strip (412), a magnetic attraction frame (413), a sliding frame (414) and an aluminum iron boron magnet (415);

the utility model discloses a magnet, including fixing frame (203) and iron sheet (407), internal thread pipe (401) is installed in joint groove (209) in the mount (203) outside, there is adjusting screw (402) in internal thread pipe (401) top through threaded connection, adjusting screw (402) one end welding has sleeve pipe (403), slide (404) have all been cup jointed in the sliding of sleeve pipe (403) both ends, slide (404) side both ends welding has installing frame (405), installing frame (405) middle part welding has dull and stereotyped (406), dull and stereotyped groove (408) have been cup jointed in dull and stereotyped (406) middle part slip, dull and stereotyped groove (408) have been seted up in iron sheet (407) corresponding dull and stereotyped (406), bonding mouth (409) have been seted up to iron sheet (407) side, bonding mouth (409) inside bonding has gasbag (410), gasbag (410) both sides all bond spacer sheet (411), the one end edge that iron sheet (407) are close to each other has bonded rubber strip (412), installing frame (405) one side welding has magnet frame (413), magnet frame (414) inside sliding frame (414), magnet frame (415) sliding inside the magnet (415).

8. An experimental device for a physical light functional material according to claim 7, wherein the distance between the side surfaces of the isolating sheet (411) and the iron sheet (407) is 0.5mm, and the side of the isolating sheet (411) away from the air bag (410) is a rough plane.

9. The experimental device for the physical light functional material according to claim 7, wherein two ends of the sliding frame (414) are slidably clamped inside the magnetic attraction frame (413), and one side of the aluminum iron boron magnet (415) close to the iron sheet (407) is flush with the inner wall of the mounting frame (405).