Automatic cleaning rack for ultraviolet disinfection quartz sleeve
By designing an automatic cleaning rack for UV-sterilized quartz sleeves, and utilizing the sleeve travel, cleaning, and rinsing structure, the problems of long cleaning time and easy damage to UV-sterilized quartz sleeves are solved, achieving efficient and safe automatic cleaning results.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 广州市净水有限公司
- Filing Date
- 2025-08-01
- Publication Date
- 2026-07-07
AI Technical Summary
The existing cleaning process for UV-sterilized quartz sleeves is time-consuming and easily damaged, while traditional manual cleaning steps are cumbersome and difficult to perform efficiently.
This invention relates to an automatic cleaning rack for ultraviolet disinfection equipment, comprising a frame, a tube travel device, and a maintenance device for ultraviolet disinfection equipment. Specifically, it relates to a maintenance device for tubular ultraviolet disinfection equipment, particularly an automatic cleaning rack for ultraviolet disinfection quartz tubes. By setting up a tube travel structure, a cleaning structure, and a rinsing structure, a first rotating mechanism drives a sponge gripper structure to automatically clean the tube, and the rinsing structure removes dirt.
This technology shortens the cleaning time of UV-sterilized quartz sleeves, avoids damage to the sleeves, adapts to the cleaning needs of sleeves with different outer diameters, and improves cleaning efficiency and safety.
Smart Images

Figure CN224463362U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of maintenance devices for tubular ultraviolet disinfection equipment, and more specifically, to an automatic cleaning rack for ultraviolet disinfection quartz sleeves. Background Technology
[0002] Currently, the maintenance of tubular ultraviolet disinfection equipment is quite difficult, time-consuming, and space-consuming. It is also highly susceptible to damage to the quartz sleeve. Key components of ultraviolet disinfection equipment include the ultraviolet lamp, quartz sleeve, and ultraviolet lamp holder. Among these, cleaning the surface of the quartz sleeve is the most challenging aspect. Traditional manual cleaning involves removing all the quartz sleeves, storing them together, and then manually wiping each two-meter-long sleeve, which is time-consuming for a single unit. Utility Model Content
[0003] The purpose of this invention is to overcome the shortcomings of the existing technology where manual wiping of ultraviolet disinfection quartz sleeves takes a long time, and to provide an automatic cleaning rack for ultraviolet disinfection quartz sleeves, thereby shortening the cleaning time of ultraviolet disinfection quartz sleeves.
[0004] To solve the above-mentioned technical problems, the technical solution adopted by this utility model is as follows:
[0005] An automatic cleaning rack for ultraviolet-sterilized quartz tubes is provided, comprising a frame and a tube traveling structure, a cleaning structure, and a rinsing structure sequentially arranged on the frame; the cleaning structure includes a first rotating mechanism and a sponge gripper structure for abutting against the tube to be cleaned, the first rotating mechanism is arranged on the frame, and the sponge gripper structure is connected to the output end of the first rotating mechanism.
[0006] This utility model discloses an automatic cleaning rack for UV-sterilized quartz sleeves. During cleaning, the sleeve enters from one end of the sleeve-moving structure. Activating the sleeve-moving structure automatically transports the sleeve sequentially to the cleaning structure and then to the rinsing structure. A first rotating mechanism drives a sponge gripper structure to rotate, which cleans the sleeve. After cleaning, the sleeve enters the rinsing structure, where it is rinsed to remove dirt. By designing the sleeve-moving structure to allow the sleeve to pass through the cleaning and rinsing structures sequentially, and the first rotating mechanism driving the sponge gripper structure to clean the sleeve, followed by the rinsing structure washing away dirt, the cleaning time for UV-sterilized quartz sleeves is shortened.
[0007] Furthermore, the sponge gripper structure includes an adjustment structure and a sponge structure. The adjustment structure is connected to the output end of the first rotating mechanism, and the sponge structure is connected to the output end of the adjustment structure. By setting the adjustment structure, the position of the sponge structure can be adjusted to avoid damaging the quartz sleeve during cleaning, and it also facilitates cleaning sleeves of different outer diameters.
[0008] Furthermore, the adjustment structure includes the outer shell, a rotating assembly, a travel annular disk, and a sliding annular frame. The outer shell is connected to the output end of the first rotating mechanism. The rotating assembly is mounted on the outer shell. The travel annular disk is connected to the output end of the rotating assembly. The sliding annular frame is fixedly connected to the outer shell. The travel annular disk and the sliding annular frame are coaxially arranged. The travel annular disk has multiple travel grooves around its circumference, which gradually incline clockwise from the center of the travel annular disk. The sliding annular frame has multiple sliding grooves radially along its axis. The sponge structure is provided in multiple sets, each set slidably connected to one of the travel grooves and the other set slidably connected to one of the sliding grooves. During adjustment, the rotating assembly is activated to rotate the travel annular disk. The sponge structure moves within the travel grooves under the constraint of the sliding grooves, thereby changing the position of the sponge structure. This avoids damage to the quartz sleeve during cleaning and facilitates cleaning of sleeves with different outer diameters.
[0009] Furthermore, the rotating assembly includes a worm and a worm wheel, which are rotatably connected to the housing. The worm and the worm wheel are meshed together, and the travel annular disk is connected to the worm wheel. Rotating the worm causes the worm wheel to rotate, thereby causing the travel annular disk to rotate.
[0010] Furthermore, the sponge structure includes grippers and a sponge. The two sides of the grippers are slidably connected to the travel groove and the sliding groove, respectively, and the sponge is detachably connected to the grippers. The sponge is held by the grippers to clean the sleeve, and the sponge can be easily replaced and maintained after cleaning, thus maintaining the cleaning effect.
[0011] Furthermore, the sleeve traveling structure includes a tensioning structure bracket, a second rotating mechanism, and multiple sets of roller tensioning structures. Both the tensioning structure bracket and the second rotating mechanism are mounted on the frame. The multiple sets of roller tensioning structures are respectively arranged circumferentially on the tensioning structure bracket, and each roller tensioning structure is connected to the output end of the second rotating mechanism. The multiple sets of roller tensioning structures support and clamp the sleeve, while the second rotating mechanism drives the roller tensioning structures to move, thereby moving the sleeve.
[0012] Furthermore, the roller tensioning structure includes rollers and two sets of symmetrically arranged tensioning mechanisms. Each tensioning mechanism includes a carriage, a slider, a fixing structure, and a connecting rod. The carriage is mounted on the tensioning structure support, and the slider is slidably connected to the carriage. The slider can be fixed to the carriage via the fixing structure. Both ends of the connecting rod are rotatably connected to the slider and the roller, respectively. By sliding the slider on the carriage, the slider drives the connecting rod to rotate, thereby changing the distance between the roller and the carriage. This avoids damage to the quartz sleeve during transportation and also facilitates the transportation of sleeves with different outer diameters.
[0013] Furthermore, the rinsing structure includes a water receiving tank, a circular water pipe, and multiple nozzles. The water receiving tank is mounted on the frame, the circular water pipe is mounted on the water receiving tank, and the multiple nozzles are respectively mounted circumferentially on the circular water pipe, all of which are connected to the circular water pipe. The circular water pipe directs water into the nozzles, and the multiple nozzles simultaneously rinse the circumference of the casing, improving rinsing efficiency. The rinsed water then flows into the water receiving tank.
[0014] Furthermore, following the flushing structure, another set of the sleeve traveling structure, the cleaning structure, and the flushing structure are sequentially arranged. By providing two sets of sleeve traveling structures, it is easier to stably clamp and transport the sleeve, and by providing two sets of cleaning structures and the flushing structure, the cleaning effect on the sleeve is improved.
[0015] Furthermore, it also includes a storage rack mounted on the frame. By providing the storage rack, the sleeves before and after cleaning can be stored.
[0016] Compared with the prior art, the beneficial effects of this utility model are:
[0017] 1. The present invention relates to an automatic cleaning rack for ultraviolet disinfection quartz sleeves. By setting a sleeve traveling structure, the sleeve passes through a cleaning structure and a rinsing structure in sequence. The first rotating mechanism rotates to drive the sponge clamp structure to clean the sleeve. After cleaning, the rinsing structure washes away the stains, thus shortening the cleaning time of ultraviolet disinfection quartz sleeves.
[0018] 2. The present invention provides an automatic cleaning rack for ultraviolet disinfection quartz sleeves. By setting an adjustment structure, the position of the sponge structure can be adjusted to avoid damage to the quartz sleeves during cleaning, and it can also facilitate the cleaning of sleeves with different outer diameters.
[0019] 3. The present invention provides an automatic cleaning rack for ultraviolet disinfected quartz sleeves. By sliding a slider on the slide, the slider drives the connecting rod to rotate, thereby changing the distance between the roller and the slide, avoiding damage to the quartz sleeves during transportation, and also facilitating the transportation of sleeves with different outer diameters. Attached Figure Description
[0020] Figure 1 This is a schematic diagram of the structure of the automatic cleaning rack for ultraviolet disinfection quartz sleeves of this utility model;
[0021] Figure 2 This is a schematic diagram of the cleaning structure;
[0022] Figure 3 This is an exploded view of the cleaning structure from a first-person perspective;
[0023] Figure 4 This is an exploded view of the cleaning structure from a second perspective;
[0024] Figure 5 This is a schematic diagram of the casing travel structure;
[0025] Figure 6 This is a schematic diagram of the roller tensioning structure;
[0026] Figure 7 This is a schematic diagram of the flushing structure.
[0027] In the attached diagram: 100, frame; 200, sleeve traveling structure; 210, tensioning structure support; 220, second rotating mechanism; 230, roller tensioning structure; 231, roller; 232, slide; 233, slider; 234, fixing structure; 235, connecting rod; 300, cleaning structure; 310, first rotating mechanism; 320, sponge gripper structure; 321, outer shell; 322, rotating assembly; 322a, worm gear; 322b, worm wheel; 323, stroke annular disc; 324, stroke groove; 325, sliding annular frame; 326, sliding groove; 327, gripper; 328, sponge; 400, rinsing structure; 410, water receiving tank; 420, annular water pipe; 430, nozzle; 500, storage rack. Detailed Implementation
[0028] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only a part of the embodiments of the present utility model, and not all of them. The present utility model will be further described below with reference to specific embodiments. The accompanying drawings are only for illustrative purposes and represent only schematic diagrams, not actual pictures, and should not be construed as limiting the present patent. In order to better illustrate the embodiments of the present utility model, some parts in the drawings may be omitted, enlarged or reduced, and do not represent the actual product size. It is understandable to those skilled in the art that some well-known structures and their descriptions may be omitted in the drawings.
[0029] In the accompanying drawings of this utility model, the same or similar reference numerals correspond to the same or similar components. In the description of this utility model, it should be understood that if terms such as "upper," "lower," "left," and "right" indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, they are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, the terms used to describe positional relationships in the drawings are only for illustrative purposes and should not be construed as limiting this patent. For those skilled in the art, the specific meaning of the above terms can be understood according to the specific circumstances.
[0030] Example 1
[0031] This embodiment is a first embodiment of an automatic cleaning rack for ultraviolet disinfection quartz sleeves, such as... Figure 1 As shown, it includes a frame 100 and a sleeve traveling structure 200, a cleaning structure 300, and a rinsing structure 400 sequentially arranged on the frame 100; as Figure 2 As shown, the cleaning structure 300 includes a first rotating mechanism 310 and a sponge gripper structure 320 for abutting against the tube being cleaned. The first rotating mechanism 310 is mounted on the frame 100, and the sponge gripper structure 320 is connected to the output end of the first rotating mechanism 310. It also includes a storage rack 500, mounted on the frame 100, which includes multiple arranged storage compartments, each with a concave arc-shaped groove into which the tube is placed. By providing the storage rack 500, tubes before and after cleaning can be stored. Specifically, a control box may also be provided, with the tube traveling structure 200, cleaning structure 300, and rinsing structure 400 all electrically connected to the control box. The control box can control the operation of the tube traveling structure 200, cleaning structure 300, and rinsing structure 400.
[0032] like Figure 6As shown, the sleeve traveling structure 200 includes a tensioning structure bracket 210, a second rotating mechanism 220, and multiple sets of roller tensioning structures 230. Both the tensioning structure bracket 210 and the second rotating mechanism 220 are mounted on the frame 100. The multiple sets of roller tensioning structures 230 are respectively arranged circumferentially on the tensioning structure bracket 210, and are connected to the output end of the second rotating mechanism 220. The multiple sets of roller tensioning structures 230 support and clamp the sleeve, and the second rotating mechanism 220 drives the roller tensioning structures 230 to move, thereby driving the sleeve to move. Specifically, the second rotating mechanism 220 includes a servo motor and a universal joint coupling structure. The servo motor is mounted on the frame 100, and both ends of the universal joint coupling structure are connected to the output end of the servo motor and one of the sets of roller tensioning structures 230, respectively. The servo motor outputs power to the universal joint coupling structure, which then transmits the power to the roller tensioning structures 230.
[0033] like Figure 3 and Figure 4 As shown, the sponge gripper structure 320 includes an adjustment structure and a sponge structure. The adjustment structure is connected to the output end of the first rotating mechanism 310, and the sponge structure is connected to the output end of the adjustment structure. By setting the adjustment structure, the position of the sponge structure can be adjusted to avoid damaging the quartz sleeve during cleaning, and it also facilitates cleaning sleeves with different outer diameters.
[0034] like Figure 5 As shown, the rinsing structure 400 includes a water receiving tank 410, a circular water pipe 420, and multiple nozzles 430. The water receiving tank 410 is mounted on the frame 100 and has a water outlet. The bottom of the water receiving tank 410 is inclined, and the water outlet is located at the lowest point of the bottom of the water receiving tank 410. The circular water pipe 420 is mounted on the water receiving tank 410, and the multiple nozzles 430 are respectively mounted circumferentially on the circular water pipe 420. The multiple nozzles 430 are connected to the circular water pipe 420. Figure 5 Specifically, the system is equipped with four nozzles 430, located in the top, bottom, left, and right directions respectively. These nozzles simultaneously spray high-pressure water in a fan shape to flush the casing. A circular water pipe 420 directs water into the nozzles 430. Multiple nozzles 430 simultaneously flush the circumference of the casing, improving flushing efficiency. The flushed water then flows into a receiving tank 410. Specifically, the flushing water is supplied and pressurized by the wastewater treatment plant's greywater system. Treated wastewater is also collected and processed within the greywater system; the circular water pipe 420 is connected to the clean water source in the greywater system, and the receiving tank 410 is connected to the wastewater in the greywater system.
[0035] The working principle of the automatic cleaning rack for ultraviolet disinfection quartz sleeves in this embodiment is as follows:
[0036] During the cleaning of the sleeve, the sleeve enters from one end of the sleeve traveling structure 200. The sleeve traveling structure 200 is activated, automatically transporting the sleeve sequentially to the cleaning structure 300 and the rinsing structure 400. The first rotating mechanism 310 drives the sponge gripper structure 320 to rotate, cleaning the sleeve. After cleaning, the sleeve enters the rinsing structure 400, which rinses the sleeve, cleaning it thoroughly. By setting the sleeve traveling structure 200 to allow the sleeve to pass sequentially through the cleaning structure 300 and the rinsing structure 400, and by having the first rotating mechanism 310 rotate to drive the sponge gripper structure 320 to clean the sleeve, and then having the rinsing structure 400 wash away the dirt, the cleaning time for UV-sterilized quartz sleeves is shortened.
[0037] Example 2
[0038] This embodiment is the second embodiment of the automatic cleaning rack for ultraviolet disinfection quartz sleeves. This embodiment is similar to the first embodiment, except that, as Figure 3 and Figure 4 As shown, the adjustment structure includes a housing 321, a rotating assembly 322, a stroke annular disk 323, and a sliding ring frame 325. The housing 321 is connected to the output end of the first rotating mechanism 310. The rotating assembly 322 is mounted on the housing 321. The stroke annular disk 323 is connected to the output end of the rotating assembly 322. The sliding ring frame 325 is fixedly connected to the housing 321. The stroke annular disk 323 and the sliding ring frame 325 are coaxially arranged. The stroke annular disk 323 has multiple stroke grooves 324 on its circumference. The stroke grooves 324 are formed by the stroke annular disk 323. The travel ring 323 gradually tilts clockwise from its center outwards, or the travel groove 324 gradually tilts counterclockwise from its center outwards. The travel groove 324 only needs to be tilted; it can tilt clockwise or counterclockwise. Multiple sliding grooves 326 are provided radially along the sliding ring frame 325. Multiple sets of sponge structures are provided, each set slidingly connected to a different travel groove 324 and a different sliding groove 326. During adjustment, the rotating assembly 322 is activated, causing the travel ring 323 to rotate. The sponge structure moves within the travel groove 324 under the constraint of the sliding groove 326, thereby changing the position of the sponge structure. This prevents damage to the quartz sleeve during cleaning and facilitates cleaning of sleeves with different outer diameters.
[0039] Specifically, the first rotating mechanism 310 is configured as a belt pulley drive structure. The first rotating mechanism 310 includes a servo motor, a small pulley, a large pulley and a belt. The servo motor is mounted on the frame 100. The small pulley is connected to the output end of the servo motor. The large pulley is mounted on the outer shell 321. The belt is wound around the small pulley and the large pulley. The small pulley is connected to the large pulley via the belt drive.
[0040] like Figure 4 As shown, the rotating assembly 322 includes a worm gear 322a and a worm wheel 322b, which are rotatably connected to the housing 321. Specifically, the worm gear 322a is housed in a worm groove provided in the housing 321, and the worm wheel 322b is rotatably connected to the housing 321 via a bearing. The worm gear 322a and worm wheel 322b are meshed together, and the travel ring disk 323 is connected to the worm wheel 322b. Rotating the worm gear 322a causes the worm wheel 322b to rotate, thereby causing the travel ring disk 323 to rotate. Specifically, both ends of the worm gear 322a are provided with hexagonal sockets. When adjustment is required, an Allen wrench is inserted into the hexagonal socket to rotate the worm gear 322a, causing the worm wheel 322b to rotate.
[0041] like Figure 3 As shown, the sponge structure includes a clamp 327 and a sponge 328. The two sides of the clamp 327 are slidably connected to the travel groove 324 and the sliding groove 326, respectively. The sponge 328 is detachably connected to the clamp 327. The sponge 328 is held by the clamp 327 to clean the sleeve. After cleaning, the sponge 328 can be easily replaced and maintained, thus maintaining the cleaning effect.
[0042] Example 3
[0043] This embodiment is the third embodiment of the automatic cleaning rack for UV-sterilized quartz sleeves. This embodiment is similar to Embodiment 1, except that, as Figure 7 As shown, the roller tensioning structure 230 includes a roller 231 and two sets of symmetrically arranged tensioning mechanisms. Each tensioning mechanism includes a slide 232, a slider 233, a fixing structure 234, and a connecting rod 235. The slide 232 is mounted on the tensioning structure support 210. The slider 233 is slidably connected to the slide 232 and can be fixed to the slide 232 via the fixing structure 234. The two ends of the connecting rod 235 are rotatably connected to the slider 233 and the roller 231, respectively. By sliding the slider 233 on the slide 232, the slider 233 drives the connecting rod 235 to rotate, thereby changing the distance between the roller 231 and the slide 232. This prevents damage to the quartz sleeve during transportation and also facilitates the transportation of sleeves with different outer diameters.
[0044] Specifically, the fixing structure 234 is a bolt, which is threadedly connected to the slide 232. The bolt's axial direction is parallel to the sliding direction of the slider 233, and the end of the bolt abuts against the slider 233. When the bolt is rotated, it pushes the slider 233 to slide within the slide 232. The roller tensioning structure 230 also includes an elastic element, which is a spring. The two ends of the spring are connected to the bolt end and the slider 233 respectively, allowing the roller 231 to have a certain amount of room to move when it abuts against the quartz sleeve, thus avoiding squeezing and damaging the quartz sleeve.
[0045] Example 4
[0046] This embodiment is the fourth embodiment of the automatic cleaning rack for UV-sterilized quartz sleeves. This embodiment is similar to Embodiment 1, except that, as Figure 1 As shown, after the flushing structure 400, another set of sleeve traveling structure 200, cleaning structure 300 and flushing structure 400 are arranged in sequence.
[0047] Because the UV disinfection quartz sleeve is quite long, two sets of sleeve travel structures 200 are set up to facilitate stable clamping and transportation of the sleeve. At the same time, two sets of cleaning structures 300 and rinsing structures 400 are set up to improve the cleaning effect of the sleeve.
[0048] In the description of this specification, the references to terms such as "one embodiment," "some embodiments," "example," "specific example," or "some examples," etc., indicate that a specific feature, structure, material, or characteristic described in connection with that embodiment or example is included in at least one embodiment or example of the present invention. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples. Moreover, without contradiction, those skilled in the art can combine and integrate the different embodiments or examples described in this specification, as well as the features of different embodiments or examples.
[0049] Obviously, the above embodiments of this utility model are merely examples for clearly illustrating this utility model, and are not intended to limit the implementation of this utility model. Those skilled in the art can make other variations or modifications based on the above description. It is neither necessary nor possible to exhaustively describe all embodiments here. Any modifications, equivalent substitutions, and improvements made within the spirit and principles of this utility model should be included within the protection scope of the claims of this utility model.
Claims
1. An automatic cleaning rack for ultraviolet-sterilized quartz sleeves, comprising a frame (100) and a sleeve traveling structure (200), a cleaning structure (300), and a rinsing structure (400) sequentially disposed on the frame (100); characterized in that, The cleaning structure (300) includes a first rotating mechanism (310) and a sponge gripper structure (320) for abutting against the tube being cleaned. The first rotating mechanism (310) is mounted on the frame (100), and the sponge gripper structure (320) is connected to the output end of the first rotating mechanism (310).
2. The automatic cleaning rack for ultraviolet disinfection quartz sleeves according to claim 1, characterized in that, The sponge gripper structure (320) includes an adjustment structure and a sponge structure. The adjustment structure is connected to the output end of the first rotating mechanism (310), and the sponge structure is connected to the output end of the adjustment structure.
3. The automatic cleaning rack for ultraviolet-sterilized quartz sleeves according to claim 2, characterized in that, The adjustment structure includes a housing (321), a rotating assembly (322), a travel annular disk (323), and a sliding annular frame (325). The housing (321) is connected to the output end of the first rotating mechanism (310). The rotating assembly (322) is mounted on the housing (321). The travel annular disk (323) is connected to the output end of the rotating assembly (322). The sliding annular frame (325) is fixedly connected to the housing (321). The travel annular disk (323) and the sliding annular frame (325) are connected to each other. 25) Coaxial arrangement, the travel annular disk (323) is provided with a plurality of travel grooves (324) around its circumference, the travel grooves (324) gradually tilt clockwise from the center of the travel annular disk (323) outward, the sliding annular frame (325) is provided with a plurality of sliding grooves (326) along the radial direction of the sliding annular frame (325), the sponge structure is provided with a plurality of sets, the plurality of sets of sponge structures are slidably connected to the plurality of travel grooves (324) respectively, and the plurality of sets of sponge structures are slidably connected to the plurality of sliding grooves (326) respectively.
4. The automatic cleaning rack for ultraviolet-sterilized quartz sleeves according to claim 3, characterized in that, The rotating assembly (322) includes a worm (322a) and a worm wheel (322b), which are rotatably connected to the housing (321) respectively. The worm (322a) and the worm wheel (322b) are meshed together, and the travel ring disk (323) is connected to the worm wheel (322b).
5. The automatic cleaning rack for ultraviolet-sterilized quartz sleeves according to claim 3, characterized in that, The sponge structure includes a gripper (327) and a sponge (328). The two sides of the gripper (327) are slidably connected to the travel groove (324) and the sliding groove (326) respectively. The sponge (328) is detachably connected to the gripper (327).
6. The automatic cleaning rack for ultraviolet-sterilized quartz sleeves according to any one of claims 1 to 5, characterized in that, The sleeve traveling structure (200) includes a tensioning structure bracket (210), a second rotating mechanism (220), and multiple sets of roller tensioning structures (230). The tensioning structure bracket (210) and the second rotating mechanism (220) are both mounted on the frame (100). The multiple sets of roller tensioning structures (230) are respectively mounted on the tensioning structure bracket (210) along the circumference. The roller tensioning structures (230) are connected to the output end of the second rotating mechanism (220).
7. The automatic cleaning rack for ultraviolet disinfection quartz sleeves according to claim 6, characterized in that, The roller tensioning structure (230) includes a roller (231) and two sets of symmetrically arranged tensioning mechanisms. The tensioning mechanism includes a slide (232), a slider (233), a fixing structure (234), and a connecting rod (235). The slide (232) is mounted on the tensioning structure support (210). The slider (233) is slidably connected to the slide (232). The slider (233) can be fixed to the slide (232) through the fixing structure (234). The two ends of the connecting rod (235) are rotatably connected to the slider (233) and the roller (231), respectively.
8. The automatic cleaning rack for ultraviolet-sterilized quartz sleeves according to any one of claims 1 to 5, characterized in that, The flushing structure (400) includes a water receiving tank (410), a circular water pipe (420), and a plurality of nozzles (430). The water receiving tank (410) is mounted on the frame (100), the circular water pipe (420) is mounted on the water receiving tank (410), and the plurality of nozzles (430) are respectively mounted on the circular water pipe (420) along the circumference. The plurality of nozzles (430) are connected to the circular water pipe (420).
9. The automatic cleaning rack for ultraviolet-sterilized quartz sleeves according to any one of claims 1 to 5, characterized in that, Following the flushing structure (400), another set of the sleeve traveling structure (200), the cleaning structure (300), and the flushing structure (400) are sequentially provided.
10. The automatic cleaning rack for ultraviolet-sterilized quartz sleeves according to any one of claims 1 to 5, characterized in that, It also includes a storage rack (500) disposed on the rack (100).