CN219068293U - Static anti-algae ability evaluation device of material - Google Patents

Abstract

The utility model relates to the technical field of material detection, and provides a static algae resistance capability assessment device of a material, which comprises the following components: the sampling assembly comprises a placing platform, a sliding block is slidably arranged at the bottom of the placing platform, a first rectangular groove is formed in the top of the placing platform, first rotating holes are formed in two ends of the first rectangular groove, a first single threaded rod is installed in the two first rotating holes in a rotating mode, a first moving block is connected to the first single threaded rod through threads, the first moving block is in contact with the inner wall of the rectangular groove, and a time delay camera is installed at the top of the first moving block; the sample is placed the subassembly, the subassembly is placed to the sample is located the camera end front side of delay camera, the subassembly is placed to the sample includes the workstation, sets up small-size cultivation room on the workstation. The utility model can realize that a plurality of sample tests can be realized at one time, and meanwhile, the detection conditions can be changed.

Description

Static anti-algae ability evaluation device of material

Technical Field

The utility model relates to the technical field of material detection, in particular to a static algae resistance capability assessment device of a material.

Background

A hydroelectric power station is a power station that generates electricity by utilizing kinetic energy of strong water flow generated by a water head, and is referred to as a "hydroelectric power station" for short. The water energy of the river is utilized to push the water turbine to drive the generator set to generate electricity. The advantages are that: no fuel consumption, low cost, no environmental pollution, simple manufacture of electromechanical equipment, flexible operation, etc. Meanwhile, the power generation hydraulic building can be combined with the industries of flood control, irrigation, water supply, shipping, cultivation and the like to realize comprehensive utilization of water resources. Disadvantages: large capital investment, long construction period, limitation by natural conditions, etc.

The pipelines of hydroelectric power stations and municipal water are easy to have a large amount of algae residues harmful to human health, an anti-algae material is needed to be designed to protect the human health, but the existing detection and evaluation equipment can only perform single detection, and meanwhile, the detection and adjustment are not easy to change.

Disclosure of Invention

The utility model provides a static algae resistance capability assessment device of a material, which aims to solve the problem that the existing detection assessment equipment can only carry out single detection and is not good for changing detection adjustment.

The utility model is realized in such a way that a material static anti-algae ability evaluation device comprises:

the sampling assembly comprises a placing platform, a sliding block is slidably arranged at the bottom of the placing platform, a first rectangular groove is formed in the top of the placing platform, first rotating holes are formed in two ends of the first rectangular groove, a first single threaded rod is installed in the two first rotating holes in a rotating mode, a first moving block is connected to the first single threaded rod through threads, the first moving block is in contact with the inner wall of the rectangular groove, and a time delay camera is installed at the top of the first moving block;

the sample placement component is positioned at the front side of the shooting end of the delay camera and comprises a workbench, a small cultivation room arranged on the workbench, a hygrothermograph arranged on the small cultivation room and an LED lamp panel arranged in the small cultivation room, wherein a luminosity intensity adjusting knob electrically connected with the LED lamp panel is arranged on the small cultivation room;

a plurality of conical flasks with scales on the surfaces are distributed linearly at equal distances and are arranged in a small-sized culture room.

Further, a first supporting component is arranged at the bottom of the small-sized culture room;

the first supporting component comprises a middle rod and a universal joint, the universal joint comprises a locking sleeve, a first ball joint and a first locking stud, the first ball joint is matched with the locking sleeve, the locking sleeve is rotatably arranged at one end of the middle rod, the universal joint is fixed with the sliding block, the locking sleeve is sleeved on the first ball joint, a notch is formed in one side of the locking sleeve, a first through hole and a first threaded hole are respectively formed in the outer walls of two opposite sides of the notch of the locking sleeve, the first locking stud penetrates through the first through hole and is in threaded connection with the first threaded hole, and a knob is fixed at one end of the first locking stud.

Still further, first supporting component still includes a plurality of first supporting legs, the one end of first supporting leg forms normal running fit with the intermediate lever, rotate on the first supporting leg and install the connecting plate, the second through-hole has been seted up to the one end that first supporting leg was kept away from to the connecting plate, the second screw hole has been seted up to the bottom of intermediate lever, the second screw hole has hexagonal fixing bolt through threaded connection, and a plurality of the connecting plate passes through the second through-hole cover and establishes on hexagonal fixing bolt.

Further, the bottom ends of the first supporting legs are spherical.

Further, the first moving block is replaced with a clamping assembly;

the clamping assembly comprises a first clamping mechanism, the first clamping mechanism comprises a second moving block, the second moving block is connected with a first single threaded rod through threads, the second moving block is in contact with a first rectangular inner wall groove, a second rectangular groove is formed in the top of the second moving block, a centering assembly is arranged in the second rectangular groove, two third moving blocks are connected to the centering assembly, and the centering assembly enables the two third moving blocks to perform synchronous and opposite linear motions;

the centering assembly comprises a middle post, a gear ring, a coil spring and two toothed plates, wherein the middle post is fixed at the middle position of the bottom of the second rectangular groove, the gear ring is rotatably arranged in the second rectangular groove and is coaxially arranged with the middle post, two ends of the coil spring are respectively fixed with the gear ring and the middle post, square holes are formed in the toothed plates, square rods are slidably arranged in the square holes, two ends of each square rod are respectively fixed at two ends of the second rectangular groove, two third moving blocks are respectively fixed on the toothed plates, and the toothed plates are meshed with the gear ring.

Still further, the third rectangular channel has all been seted up to the top both sides of third movable block, one side of third movable block has been seted up and has been linked together the second rotation hole with two third rectangles, the second rotates downthehole rotation of installing the double-threaded pole, left-handed screw and right-handed screw on the double-threaded pole all are connected with L shape splint, L shape splint and the contact of its third rectangular channel that locates.

Still further, the one end in second rectangular channel has seted up the third through-hole, the third through-hole slides and is provided with the single threaded rod of second, the one end of single threaded rod of second with one of them the pinion rack is fixed, the single threaded rod of second has lock nut through threaded connection.

Further, a rubber pad is sleeved on the second single threaded rod, and the rubber pad is located between the lock nut and the second moving block.

Further, replacing the universal joint with a leveling mechanism; the leveling mechanism comprises a circular plate and a second ball joint, the second ball joint is sleeved in the circular plate, a connecting column is fixed on the second ball joint, the connecting column is fixed with a sliding block, a circular plate is fixed on the second ball joint, three threaded holes are formed in the top of the circular plate, the threaded holes are connected with adjusting studs through threads, and a bubble level is fixed on the circular plate.

Still further, the first support assembly is replaced with a second support assembly;

the second supporting component comprises a plurality of sections of telescopic barrels, a movable ring and a plurality of second supporting legs, the movable ring is arranged on the plurality of sections of telescopic barrels in a sliding mode, each sleeve of the plurality of sections of telescopic barrels and the movable ring are connected with a second locking stud through threads, one end of each second supporting leg is rotatably arranged on the plurality of sections of telescopic barrels, and a connecting rod is rotatably arranged between each second supporting leg and the movable ring.

After adopting the structure, compared with the prior art, the utility model has the following advantages:

in the utility model, the device is a static algae resistance evaluation device of a material, algae stock solution is filled in conical flasks, algae harmful to human health or fish health are contained in the algae stock solution, and six different samples are filled in six conical flasks.

The illumination intensity required by the experiment can be adjusted through the light intensity adjusting knob of the small cell culture room so as to accelerate the culture of algae and further accelerate the evaluation speed. The hygrothermograph is arranged above the light intensity adjusting knob, so that the temperature and humidity in the environment can be observed for recording.

All conical flasks in the small cell culture room are continuously photographed by an erected time-lapse photographic camera, and the anti-algae capability of the material is evaluated on line according to the recorded change speed of the color of the algae liquid in the conical flasks (the speed of the algae liquid changing from clear) by analysis software built in the time-lapse photographic camera.

Meanwhile, the illuminometer is arranged at the lens of the time-delay camera, the change of illumination intensity can be monitored in real time, the illuminometer is connected to the illumination adjusting knob, and a user can adjust illumination through the app while adjusting the illumination through the knob so as to accelerate the speed of algae cultivation, so that a plurality of sample tests can be realized at one time, and meanwhile, the detection condition can be changed.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the utility model and together with the description, serve to explain the principles of the utility model.

In order to more clearly illustrate the embodiments of the utility model or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, and it will be obvious to a person skilled in the art that other drawings can be obtained from these drawings without inventive effort.

Fig. 1 is a schematic diagram of the overall structure of the present utility model.

Fig. 2 is a schematic structural view of the placement platform according to the present utility model.

FIG. 3 is a schematic diagram of a mini-cell according to the present utility model.

FIG. 4 is a schematic view of the gimbal and intermediate lever structure of the present utility model.

Fig. 5 is an enlarged schematic view of the structure of fig. 4 a according to the present utility model.

Fig. 6 is a schematic view of a first ball joint structure according to the present utility model.

Fig. 7 is a schematic view of a clamping assembly according to the present utility model.

FIG. 8 is a top view of the clamping assembly of the present utility model

Fig. 9 is a schematic structural view of a second support assembly according to the present utility model.

Fig. 10 is a schematic structural view of the leveling mechanism of the present utility model.

Figure 11 is a front cross-sectional view of a leveling structure of the present utility model.

Reference numerals:

1. a sampling assembly; 11. a delay camera; 12. placing a platform; 13. a first single threaded rod; 14. a first moving block; 15. a first support assembly; 151. a first support leg; 152. an intermediate lever; 153. a hexagonal fixing bolt; 154. a connecting plate; 16. a universal joint; 161. a locking sleeve; 162. a first locking stud; 163. a first ball joint; 17. a clamping assembly; 171. a second moving block; 172. a third moving block; 173. a double threaded rod; 174. an L-shaped clamping plate; 175. square rods; 176. a toothed plate; 177. a second single threaded rod; 178. a lock nut; 179. a rubber pad; 1710. a gear ring; 1711. a middle column; 1712. a coil spring; 18. a second support assembly; 181. a multi-section telescopic cylinder; 182. a moving ring; 183. the second locking stud; 184. a second support leg; 185. a connecting rod; 19. a leveling mechanism; 191. a circular plate; 192. a second ball joint; 193. adjusting the stud; 194. a bubble level; 195. a connecting column;

2. a sample placement assembly; 21. a small-sized culture room; 22. a hygrothermograph; 23. a photometric intensity adjustment knob; 24. a work table; 25. an LED lamp panel.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

In order to effectively explain the embodiments of the present utility model, the embodiments of the present application are explained in detail below with reference to the figures.

Example 1

Referring to fig. 1-3, a device for evaluating static anti-algae ability of a material includes:

the sampling assembly 1, the sampling assembly 1 comprises a placing platform 12, a sliding block is slidably arranged at the bottom of the placing platform 12, a first rectangular groove is formed in the top of the placing platform 12, first rotating holes are formed in the two ends of the first rectangular groove, a first single threaded rod 13 is installed in the two first rotating holes in a co-rotating mode, a first moving block 14 is connected to the first single threaded rod 13 through threads, the first moving block 14 is in contact with the inner wall of the rectangular groove, and a time delay camera 11 is installed at the top of the first moving block 14;

the sample placing assembly 2 is positioned at the front side of the shooting end of the delay camera 11, the sample placing assembly 2 comprises a workbench 24, a small-sized cultivation room 21 arranged on the workbench 24, a hygrothermograph 22 arranged on the small-sized cultivation room 21 and an LED lamp panel 25 arranged in the small-sized cultivation room 21, and a luminosity intensity adjusting knob 23 electrically connected with the LED lamp panel 25 is arranged on the small-sized cultivation room 21;

a plurality of conical flasks with scales on the surface are distributed in a straight line at equal distance and are arranged in the small-sized culture room 21.

In summary, by means of the above technical solution of the present utility model: algae stock solutions are filled, wherein algae harmful to human health or fish health are contained in the algae stock solutions, and six conical flasks are filled with six different samples.

The illumination intensity required by the experiment can be adjusted through the light intensity adjusting knob of the small cell culture room so as to accelerate the culture of algae and further accelerate the evaluation speed. A hygrothermograph 22 is arranged above the light intensity adjusting knob, so that the temperature and humidity in the environment can be observed for recording.

Continuously shooting all conical flasks in the small cell culture room by using an erected time-delay photographic camera, and evaluating the anti-algae capability of the material on line according to the recorded change speed (the speed of changing the liquid from clear) of the color of the algae liquid of the conical flasks by using analysis software built in the time-delay photographic camera;

the time delay camera lens department is provided with the illuminometer, can real-time supervision illumination intensity's change, and this illuminometer is correlated to the illumination adjust knob, and the user also accessible app adjusts illumination when adjusting through the knob to speed up algae cultivation.

Example two

Referring to fig. 4 to 6, a first support member 15 is provided at the bottom of the mini-incubator 21;

the first support assembly 15 includes an intermediate rod 152 and a universal joint 16, the universal joint 16 includes a locking sleeve 161, a first ball joint 163 adapted to the locking sleeve 161, and a first locking stud 162, the locking sleeve 161 is rotatably mounted on one end of the intermediate rod 152, the universal joint 16 is fixed to the slider, the locking sleeve 161 is sleeved on the first ball joint 163, a notch is formed in one side of the locking sleeve 161, a first through hole and a first threaded hole are respectively formed in outer walls of two opposite sides of the notch of the locking sleeve 161, the first locking stud 162 penetrates through the first through hole and is in threaded connection with the first threaded hole, and a knob is fixed at one end of the first locking stud 162.

Still further, the first support assembly 15 further includes a plurality of first support legs 151, one end of the first support legs 151 forms a running fit with the middle rod 152, the first support legs 151 are rotatably provided with a connecting plate 154, one end of the connecting plate 154 far away from the first support legs 151 is provided with a second through hole, the bottom of the middle rod 152 is provided with a second threaded hole, the second threaded hole is connected with a hexagonal fixing bolt 153 through threads, and the plurality of connecting plates 154 are sleeved on the hexagonal fixing bolt 153 through the second through holes.

Further, the bottom ends of the first support legs 151 are rounded, which facilitates the engagement with the ground.

In summary, by means of the above technical solution of the present utility model: when the support is used, the connecting plate 154 is sleeved on the hexagonal fixing bolt 153 through the second through hole, and then the hexagonal fixing bolt 153 is connected to the bottom of the middle rod 152 through threads, so that the whole first support leg 151 is unfolded, the whole first support assembly 15 is conveniently placed on the ground, and meanwhile, the whole first support assembly 15 is convenient to fold and store.

Example III

Referring to fig. 7-8, the first moving block 14 is replaced with a clamping assembly 17;

the clamping assembly 17 comprises a first clamping mechanism, the first clamping mechanism comprises a second moving block 171, the second moving block 171 is connected with the first single threaded rod 13 through threads, the second moving block 171 is in contact with the first rectangular inner wall groove, a second rectangular groove is formed in the top of the second moving block 171, a centering assembly is installed in the second rectangular groove, two third moving blocks 172 are connected to the centering assembly, and the centering assembly enables the two third moving blocks 172 to perform synchronous and opposite linear motions;

the centering assembly comprises a middle column 1711, a gear ring 1710, a coil spring 1712 and two toothed plates 176, wherein the middle column 1711 is fixed at the middle position of the bottom of the second rectangular groove, the gear ring 1710 is rotatably installed in the second rectangular groove and is coaxially arranged with the middle column 1711, two ends of the coil spring 1712 are respectively fixed with the gear ring 1710 and the middle column 1711, square holes are formed in the toothed plates 176, square rods 175 are slidably installed in the square holes, two ends of the square rods 175 are respectively fixed at two ends of the second rectangular groove, two third moving blocks 172 are respectively fixed on the toothed plates 176, and the toothed plates 176 are meshed with the gear ring 1710.

Further, third rectangular grooves are formed in two sides of the top of the third moving block 172, a second rotating hole communicated with the two third rectangles is formed in one side of the third moving block 172, a double-threaded rod 173 is rotatably installed in the second rotating hole, left-handed threads and right-handed threads on the double-threaded rod 173 are connected with an L-shaped clamping plate 174, and the L-shaped clamping plate 174 is in contact with the third rectangular grooves where the L-shaped clamping plate 174 is located.

Further, a third through hole is formed at one end of the second rectangular groove, a second single threaded rod 177 is slidably disposed in the third through hole, one end of the second single threaded rod 177 is fixed to one of the toothed plates 176, and the second single threaded rod 177 is connected to a locking nut 178 through threads.

Further, a rubber gasket 179 is sleeved on the second single threaded rod 177, and the rubber gasket 179 is located between the locking nut 178 and the second moving block 171.

In summary, by means of the above technical solution of the present utility model: by pulling the second single threaded rod 177, the second single threaded rod 177 drives the toothed plate 176 fixed by the second single threaded rod 177 to move, the toothed plate 176 drives the other toothed plate 176 to move through the gear ring 1710, the third moving block 172 on the two toothed plates 176 moves synchronously and reversely, the double threaded rod 173 is rotated, the double threaded rod 173 drives the two L-shaped clamping plates 174 connected with the double threaded rod 173 to move synchronously and reversely, thus cameras with different specifications can be clamped, after the clamping is completed, the locking nut 178 is rotated, and the rubber pad 179 on the locking nut 178 contacts with the second moving block 171, so that locking is completed.

Example IV

Referring to fig. 9, the universal joint 16 is replaced with a leveling mechanism 19; the leveling mechanism 19 comprises a circular plate 191 and a second ball joint 192, the second ball joint 192 is sleeved in the circular plate 191, a connecting column 195 is fixed on the second ball joint 192, the connecting column 195 is fixed with a sliding block, a circular plate is fixed on the second ball joint 192, three threaded holes are formed in the top of the circular plate, an adjusting stud 193 is connected with the threaded holes through threads, and a bubble level 194 is fixed on the circular plate.

In summary, by means of the above technical solution of the present utility model: the leveling process is completed by continuously adjusting each adjustment stud 193 so that the bubble of the bubble level 194 on the circular plate is positioned in the middle.

Example five

Referring to fig. 10-11, the first support assembly 15 is replaced with a second support assembly 18;

the second support assembly 18 includes a plurality of telescopic barrels 181, a moving ring 182, and a plurality of second support legs 184, the moving ring 182 is slidably disposed on the telescopic barrels 181, each sleeve of the telescopic barrels 181 and the moving ring 182 are connected to a second locking stud 183 through threads, one end of each second support leg 184 is rotatably mounted on the telescopic barrels 181, and a connecting rod 185 is rotatably mounted between the second support leg 184 and the moving ring 182.

In summary, by means of the above technical solution of the present utility model: through the above connection relationship, the second support assembly 18 can adjust the height of the delay camera 11.

The last points to be described are: first, in the description of the present application, it should be noted that, unless otherwise specified and defined, the terms "mounted," "connected," "fixed," and "connected" are to be construed broadly, and may be mechanical or electrical, or may be a direct connection between two elements, and "upper," "lower," "left," "right," etc. are merely used to indicate relative positional relationships, which may be changed when the absolute position of the object being described is changed;

secondly: in the drawings of the disclosed embodiments, only the structures related to the embodiments of the present disclosure are referred to, and other structures can refer to the common design, so that the same embodiment and different embodiments of the present disclosure can be combined with each other under the condition of no conflict;

finally: the foregoing description of the preferred embodiments of the utility model is not intended to limit the utility model to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and principles of the utility model are intended to be included within the scope of the utility model.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (10)

1. A device for evaluating static anti-algae capability of a material, comprising:

the sampling assembly (1), sampling assembly (1) includes place platform (12), the bottom slidable mounting of place platform (12) has the slider, first rectangular channel has been seted up at the top of place platform (12), first rotation hole has all been seted up at the both ends of first rectangular channel, two rotate jointly in the first rotation hole and install a single threaded rod (13), there is first movable block (14) on single threaded rod (13) through threaded connection, first movable block (14) and rectangular channel inner wall contact, delay camera (11) are installed at the top of first movable block (14);

the sample placement component (2), the sample placement component (2) is positioned at the front side of the shooting end of the delay camera (11), the sample placement component (2) comprises a workbench (24), a small-sized cultivation room (21) arranged on the workbench (24), a hygrothermograph (22) arranged on the small-sized cultivation room (21) and an LED lamp panel (25) arranged in the small-sized cultivation room (21), and a luminosity intensity adjusting knob (23) electrically connected with the LED lamp panel (25) is arranged on the small-sized cultivation room (21);

a plurality of conical flasks with scales on the surfaces are distributed in a straight line at equal distance and are arranged in a small-sized culture room (21).

2. A device for evaluating the static anti-algae ability of a material according to claim 1, characterized in that the bottom of said small-sized culture room (21) is provided with a first supporting member (15);

the first support assembly (15) comprises a middle rod (152) and a universal joint (16), the universal joint (16) comprises a locking sleeve (161), a first ball joint (163) and a first locking stud (162), the first ball joint (163) is matched with the locking sleeve (161), the locking sleeve (161) is rotatably installed at one end of the middle rod (152), the universal joint (16) is fixed with the sliding block, the locking sleeve (161) is sleeved on the first ball joint (163), a notch is formed in one side of the locking sleeve (161), a first through hole and a first threaded hole are formed in the outer walls of two opposite sides of the notch of the locking sleeve (161), the first locking stud (162) penetrates through the first through hole and is in threaded connection with the first threaded hole, and one end of the first locking stud (162) is fixed with a knob.

3. The static anti-algae capability assessment device for materials according to claim 2, wherein the first supporting component (15) further comprises a plurality of first supporting legs (151), one ends of the first supporting legs (151) are in running fit with the middle rod (152), connecting plates (154) are rotatably installed on the first supporting legs (151), second through holes are formed in one ends, far away from the first supporting legs (151), of the connecting plates (154), second threaded holes are formed in the bottoms of the middle rods (152), hexagonal fixing bolts (153) are connected to the second threaded holes through threads, and a plurality of connecting plates (154) are sleeved on the hexagonal fixing bolts (153) through the second through holes.

4. A static algae resistance evaluation apparatus for materials as claimed in claim 3, wherein the bottom end of said first support leg (151) is spherical.

5. A device for evaluating the static anti-algae ability of a material according to claim 4, characterized in that said first mobile block (14) is replaced by a clamping assembly (17);

the clamping assembly (17) comprises a first clamping mechanism, the first clamping mechanism comprises a second moving block (171), the second moving block (171) is connected with a first single threaded rod (13) through threads, the second moving block (171) is in contact with a first rectangular inner wall groove, a second rectangular groove is formed in the top of the second moving block (171), a centering assembly is arranged in the second rectangular groove, two third moving blocks (172) are connected to the centering assembly, and the centering assembly enables the two third moving blocks (172) to perform synchronous and opposite linear motions;

the centering assembly comprises a middle column (1711), a gear ring (1710), a coil spring (1712) and two toothed plates (176), wherein the middle column (1711) is fixed at the middle position of the bottom of the second rectangular groove, the gear ring (1710) is rotatably arranged in the second rectangular groove and is coaxially arranged with the middle column (1711), two ends of the coil spring (1712) are respectively fixed with the gear ring (1710) and the middle column (1711), square holes are formed in the toothed plates (176), square rods (175) are slidably arranged in the square holes, two ends of each square rod (175) are respectively fixed at two ends of the second rectangular groove, two third moving blocks (172) are respectively fixed on the toothed plates (176), and the toothed plates (176) are meshed with the gear ring (1710).

6. The static algae resistance capacity assessment device for materials according to claim 5, wherein the top two sides of the third moving block (172) are provided with third rectangular grooves, one side of the third moving block (172) is provided with second rotating holes communicated with two third rectangles, a double threaded rod (173) is rotatably arranged in the second rotating holes, left-handed threads and right-handed threads on the double threaded rod (173) are connected with L-shaped clamping plates (174), and the L-shaped clamping plates (174) are in contact with the third rectangular grooves where the L-shaped clamping plates are located.

7. The static algae resistance capacity assessment apparatus as claimed in claim 6, wherein a third through hole is provided at one end of the second rectangular groove, a second single threaded rod (177) is slidably provided in the third through hole, one end of the second single threaded rod (177) is fixed to one of the toothed plates (176), and the second single threaded rod (177) is connected with a lock nut (178) through threads.

8. A device for evaluating the static anti-algae ability of a material according to claim 7, wherein a rubber pad (179) is sleeved on the second single threaded rod (177), and the rubber pad (179) is located between the lock nut (178) and the second moving block (171).

9. A device for evaluating the static anti-algae ability of a material according to claim 6, characterized in that said universal joint (16) is replaced by a levelling mechanism (19); the leveling mechanism (19) comprises a circular plate (191) and a second ball joint (192), the second ball joint (192) is sleeved in the circular plate (191), a connecting column (195) is fixed on the second ball joint (192), the connecting column (195) is fixed with a sliding block, a circular plate is fixed on the second ball joint (192), three threaded holes are formed in the top of the circular plate, the threaded holes are connected with adjusting studs (193) through threads, and a bubble level (194) is fixed on the circular plate.

10. A material static algae resistance assessment apparatus according to claim 2, wherein said first support member (15) is replaced by a second support member (18);

the second support assembly (18) comprises a plurality of telescopic barrels (181), a movable ring (182) and a plurality of second support legs (184), the movable ring (182) is slidably arranged on the telescopic barrels (181), each sleeve of the telescopic barrels (181) and the movable ring (182) are connected with a second locking stud (183) through threads, one end of each second support leg (184) is rotatably arranged on the telescopic barrels (181), and a connecting rod (185) is rotatably arranged between each second support leg (184) and the movable ring (182).

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