Excimer laser cavity transport case with anti-skid structure

By installing adjustable positioning frames and anti-slip pads in the transport box, and using magnets and wedges to fix the cavity, the problem of damage caused by cavity sliding during transportation is solved, achieving stability and cost-effectiveness during transportation.

CN224376328UActive Publication Date: 2026-06-19JIANGSU FENGYUE TECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANGSU FENGYUE TECHNOLOGY CO LTD
Filing Date
2025-08-08
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

In the prior art, the various cavities of excimer lasers are subject to size differences during transportation due to variations in equipment specifications. This leads to the inability of existing transport boxes to effectively secure the cavities, resulting in the risk of the cavities sliding and being damaged during transport.

Method used

Design a transport box for an excimer laser cavity with an anti-slip structure. By setting an adjustable positioning frame and anti-slip pad inside the transport box, the cavity is fixed and anti-slip by using magnets and wedges, which enhances friction and prevents the cavity from sliding. The vibration-damping rubber pads reduce the impact of bumps.

Benefits of technology

It effectively prevents the cavity from sliding during transportation, reduces the risk of damage, enhances transportation stability, adapts to the transportation needs of cavities of different specifications, and reduces transportation costs.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224376328U_ABST
    Figure CN224376328U_ABST
Patent Text Reader

Abstract

This utility model relates to the field of excimer laser cavity transportation technology, and more particularly to an excimer laser cavity transportation box with an anti-slip structure. It includes a base, a sliding groove, positioning frames, fixing holes, and insertion rods. The bottom surface of the base has two sets of symmetrical sliding grooves, and two sets of positioning frames are symmetrically arranged inside the base. The positioning frames are slidably connected to the sliding grooves. Multiple sets of fixing holes are linearly arranged on the sidewalls inside the sliding grooves. Insertion rods are slidably connected inside the positioning frames, with one end of the insertion rod located inside the fixing hole. This utility model positions the transported cavity by having the two sets of positioning frames contact the outer surface of the cavity placed inside the base, preventing accidental slippage during transportation. By using the positioning frames to slide along the sliding grooves and inserting the insertion rods into suitable fixing holes, it can limit the positioning of laser cavities of different specifications, effectively improving the applicability of the transportation box and reducing the risk of cavity transportation.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This utility model relates to the field of excimer laser cavity transportation technology, and in particular to an excimer laser cavity transportation box with an anti-slip structure. Background Technology

[0002] An excimer laser is a gas laser that uses excimer molecules as its working medium. It has unique physical properties and a wide range of applications. When transported over long distances or by air, it needs to be protected by transport cases that carry the various cavities used in the laser.

[0003] Because excimer laser cavities vary in size, they often slide within the transport container during transport due to bumps and jostling, posing a risk of damage during transit.

[0004] Therefore, to address the above issues, a transport box for excimer laser cavities with an anti-slip structure can be designed. An adjustable positioning frame can be added inside the transport box to position and fix various laser cavities inside the transport box, thereby reducing the risks associated with transportation. Utility Model Content

[0005] To overcome the risk of damage to various excimer laser cavities during transportation due to the different sizes of their cavities and the resulting slippage within the transport container caused by bumps during transport.

[0006] The technical solution of this utility model is as follows: an excimer laser cavity transport box with an anti-slip structure, including a base, a cover, a slide groove, a positioning frame, an anti-slip pad, a fixing hole, a rod, a spring, a first wedge, a handle, a second wedge, and a magnet. The cover is located above the base. The bottom surface of the base has two sets of symmetrical slide grooves. The base has two sets of positioning frames symmetrically arranged inside. The positioning frames are slidably connected to the slide grooves. An anti-slip pad is provided on one side of the positioning frame. Multiple sets of fixing holes are linearly arranged on the side wall inside the slide groove. A rod is slidably connected inside the positioning frame. One end of the rod is located inside the fixing hole. The other end of the rod is fixedly installed with a first wedge. A spring is fixedly installed between the first wedge and the positioning frame. The lower end of the handle is inserted into the positioning frame, and the handle is slidably connected to the positioning frame. The second wedge is fixedly installed at the lower end of the handle. The magnet is embedded and fixed at the upper end of the positioning frame, and the magnet is magnetically connected to the handle.

[0007] Preferably, a protective cover can protect the laser cavity supported by the base. By placing the laser cavity between two sets of positioning frames, pulling the handle upward away from the magnet causes the second wedge to move away from the first wedge. The spring provides tension to the insertion rod, causing one end of the insertion rod to move away from the fixing hole, thereby unlocking the positioning frame. By setting the positioning frame to slide along the slide groove, laser cavities of different specifications can be limited. Then, pressing down the handle and fixing it with the magnet causes the second wedge to push the first wedge to compress the spring, causing the insertion rod to insert into the fixing hole and lock the positioning frame. This prevents the laser cavity from sliding during transportation, reducing the risk of laser cavity transportation. By setting an anti-slip pad that directly contacts the outer surface of the cavity, wear on the cavity surface can be effectively prevented, while increasing friction and ensuring the stability of the cavity's anti-slip properties.

[0008] Preferably, a vibration-damping rubber pad is fixedly installed at the lower end of the base, and the lower end of the vibration-damping rubber pad is provided with multiple sets of protrusions arranged in a matrix.

[0009] Preferably, multiple sets of U-shaped grooves are formed on the inner walls of both ends of the base, and the multiple sets of U-shaped grooves are evenly and linearly arranged.

[0010] Preferably, the outer sidewalls of the cover are provided with protective plates, the outer side of the protective plates has a wavy structure, and the inner threads of the protective plates are connected with bolts.

[0011] Preferably, corner strips are fixedly installed at the four corners of the outer perimeter of the cover. The outer perimeter of the corner strips has an arc-shaped structure, and protective pads are fixedly installed on the outside of the arc-shaped structure of the corner strips.

[0012] Preferably, four sets of elastic clips are fixedly installed on the outer periphery of the cover, with the elastic clips located below the protective plate, and four sets of fixing brackets are fixedly installed on the outer periphery of the base, with the fixing brackets engaging with the elastic clips.

[0013] Preferably, the lower end of the cover is fixedly equipped with four sets of positioning rods, and the upper end of the base is provided with four sets of positioning holes, with the four sets of positioning rods corresponding to the four sets of positioning holes.

[0014] The beneficial effects of this utility model are:

[0015] When transporting the laser cavity, first place the laser cavity to be transported between the two sets of positioning frames on the upper part of the base. Pull the handle upward to disengage from the magnet. At this time, the second wedge block disengages from the first wedge block, and the spring provides tension to the insertion rod, causing one end of the insertion rod to disengage from the fixing hole, thereby unlocking the positioning frame. The positioning frame slides along the slide groove, which can limit the laser cavity of different specifications, so that the positioning frame contacts the outer wall of the cavity. Then, press down the handle and fix the handle with the magnet. At this time, the second wedge block pushes the first wedge block to compress the spring, causing the insertion rod to insert into the fixing hole and lock the positioning frame, thereby preventing the laser cavity from sliding during transportation and reducing the risk of laser cavity transportation. The anti-slip pad directly contacts the outer surface of the cavity, which can effectively prevent the cavity surface from being worn, while increasing the friction and ensuring the stability of the cavity anti-slip, effectively reducing the risk of transporting the cavity. Attached Figure Description

[0016] Figure 1 The diagram shown is a three-dimensional structural schematic of the excimer laser cavity transport box with anti-slip structure according to this utility model.

[0017] Figure 2 The diagram shown is a three-dimensional structural schematic of the excimer laser cavity transport box cover with anti-slip structure of this utility model in the separated state.

[0018] Figure 3 The diagram shown is a three-dimensional structural illustration of the interior of the excimer laser cavity transport box base with anti-slip structure according to this utility model.

[0019] Figure 4 The diagram shown is a three-dimensional cross-sectional view of the positioning frame for the excimer laser cavity transport box with anti-slip structure according to this utility model.

[0020] Figure 5 This invention relates to a transport box for an excimer laser cavity with an anti-slip structure. Figure 4 Enlarged 3D structural diagram of the circled area;

[0021] Explanation of reference numerals in the attached drawings: 1. Base support; 101. Vibration-damping pad; 102. Protrusion; 103. U-shaped groove; 2. Protective cover; 201. Protective plate; 202. Bolt; 203. External corner strip; 204. Protective pad; 301. Elastic retaining strip; 302. Fixing bracket; 303. Positioning rod; 304. Positioning hole; 401. Slide groove; 402. Positioning frame; 403. Anti-slip pad; 404. Fixing hole; 405. Insert rod; 406. Spring; 407. First wedge; 408. Handle; 409. Second wedge; 410. Magnet. Detailed Implementation

[0022] The present invention will be further described below with reference to the accompanying drawings and embodiments.

[0023] Please see Figure 2 , Figure 4 and Figure 5 This utility model provides an embodiment of an excimer laser cavity transport box with an anti-slip structure, including a base 1, a cover 2, a sliding groove 401, a positioning frame 402, an anti-slip pad 403, a fixing hole 404, a plug rod 405, a spring 406, a first wedge 407, a handle 408, a second wedge 409, and a magnet 410. The cover 2 is disposed above the base 1. The bottom surface of the base 1 has two sets of symmetrical sliding grooves 401. The base 1 has two sets of symmetrical positioning frames 402 disposed inside the base 1. The positioning frames 402 are slidably connected to the sliding grooves 401. One side is provided with an anti-slip pad 403. Multiple sets of fixing holes 404 are linearly arranged on the side wall inside the slide groove 401. A rod 405 is slidably connected inside the positioning frame 402. One end of the rod 405 is located inside the fixing hole 404, and a first wedge 407 is fixedly installed at the other end of the rod 405. A spring 406 is fixedly installed between the first wedge 407 and the positioning frame 402. The lower end of the handle 408 is inserted into the positioning frame 402, and the handle 408 is slidably connected to the positioning frame 402. A second wedge 409 is fixedly installed at the lower end of the handle 408. A magnet 410... The upper end of the positioning frame 402 is embedded and fixed, and the magnet 410 is magnetically connected to the handle 408. The cover 2 protects the laser cavity supported by the base 1. By placing the laser cavity between the two positioning frames 402, pulling the handle 408 upwards away from the magnet 410 causes the second wedge 409 to move away from the first wedge 407. The spring 406 provides tension to the insertion rod 405, causing one end of the insertion rod 405 to leave the fixing hole 404, thereby unlocking the positioning frame 402. The positioning frame 402 can then slide along the slide groove 401. To limit the laser cavity of different specifications, the handle 408 is pressed down and fixed by the magnet 410. At this time, the second wedge 409 pushes the first wedge 407 to compress the spring 406, so that the insertion rod 405 is inserted into the fixing hole 404 and the positioning frame 402 is locked, thereby preventing the laser cavity from sliding during transportation and reducing the risk of laser cavity transportation. By setting the anti-slip pad 403 to directly contact the outer surface of the cavity, the wear of the cavity surface can be effectively prevented, and the friction can be increased to ensure the stability of the cavity anti-slip.

[0024] Please see Figure 1 and Figure 3In this embodiment, a shock-absorbing rubber pad 101 is fixedly installed at the lower end of the base 1. The lower end of the shock-absorbing rubber pad 101 is provided with multiple sets of protrusions 102, which are arranged in a matrix. By providing the shock-absorbing rubber pad 101, the impact of the bumps on the base 1 and the inside of the cover 2 during transportation can be reduced. By providing the protrusions 102, the friction between the base 1 and the contact surface with the transport vehicle can be increased, preventing the base 1 from sliding accidentally. Multiple sets of U-shaped grooves 103 are opened on the inner walls of both ends of the base 1, which are arranged linearly and evenly. By providing multiple sets of U-shaped grooves 103, it is convenient to use straps to bind and fix the cavity placed above the base 1, and the positioning frame 402 can be used to prevent the cavity from sliding.

[0025] Please see Figure 1 and Figure 2 In this embodiment, protective plates 201 are provided on the outer sidewalls of the cover 2. The outer side of the protective plate 201 has a wavy structure, and bolts 202 are threadedly connected to the inside of the protective plate 201. By providing protective plates 201, the outer perimeter of the cover 2 can be protected. The wavy structure can effectively disperse external impact forces, thereby protecting the inside of the cover 2. The bolts 202 can be used to easily replace the protective plate 201. When the protective plate 201 is damaged, it is not necessary to replace the entire cover 2, which saves costs. Corner strips 203 are fixedly installed at the four corners of the cover 2. The outer perimeter of the corner strips 203 has an arc-shaped structure, and protective pads 204 are fixedly installed on the outside of the arc-shaped structure of the corner strips 203. By providing corner strips 203, the corners of the cover 2 can be shielded and protected. At the same time, the arc-shaped structure cooperates with the corner strips 204 to protect the corners of the cover 2. The protective pad 204 prevents the cover 2 from bumping into other items. Four sets of elastic clips 301 are fixedly installed on the outer periphery of the cover 2, located below the protective plate 201. Four sets of fixing brackets 302 are fixedly installed on the outer periphery of the base 1, and the fixing brackets 302 are engaged with the elastic clips 301. By setting the fixing brackets 302 in conjunction with the elastic clips 301, the cover 2 and the base 1 can be connected and fixed. Four sets of positioning rods 303 are fixedly installed at the lower end of the cover 2, and four sets of positioning holes 304 are opened at the upper end of the base 1. The four sets of positioning rods 303 correspond to the four sets of positioning holes 304. By setting the positioning rods 303 and positioning holes 304 in conjunction, positioning assistance can be provided when connecting the base 1 and the cover 2, ensuring that the elastic clips 301 and the fixing brackets 302 can be stably connected.

[0026] During operation, the laser cavity to be transported is first placed between the two sets of positioning frames 402 above the base 1. Pulling the handle 408 upwards away from the magnet 410 causes the second wedge 409 to disengage from the first wedge 407. The spring 406 then provides tension to the insertion rod 405, causing one end of the insertion rod 405 to disengage from the fixing hole 404, thereby unlocking the positioning frame 402. By allowing the positioning frame 402 to slide along the slide groove 401, different specifications of laser cavities can be positioned, ensuring proper contact between the positioning frame 402 and the cavity. The outer wall contacts the handle 408, and the handle 408 is fixed by the magnet 410. At this time, the second wedge 409 pushes the first wedge 407 to compress the spring 406, so that the insertion rod 405 is inserted into the fixing hole 404 and the positioning frame 402 is locked, thereby preventing the laser cavity from sliding during transportation and reducing the risk of laser cavity transportation. The anti-slip pad 403 is in direct contact with the outer surface of the cavity, which can effectively prevent the cavity surface from being worn, while increasing the friction and ensuring the stability of the cavity's anti-slip.

[0027] The cavity placed above the base 1 is secured by straps using the U-shaped groove 103, and the positioning bracket 402 is used to prevent the cavity from sliding.

[0028] Then, the cover 2 is placed on top of the base 1 to shield and protect the internal cavity. The cooperation between the positioning rod 303 and the positioning hole 304 can provide positioning assistance when connecting the base 1 and the cover 2, ensuring that the elastic clip 301 and the fixing frame 302 can be stably connected, thereby connecting and fixing the cover 2 and the base 1.

[0029] The protective plate 201 can provide protection for the outer perimeter of the cover 2. The wave-shaped structure can effectively disperse the external impact force, thereby providing protection for the inside of the cover 2. The protective plate 201 can be easily replaced using the bolt 202. When the protective plate 201 is damaged, there is no need to replace the entire cover 2, which saves costs. The corner strip 203 can shield and protect the top corner of the cover 2. At the same time, the arc-shaped structure, together with the protective pad 204, can prevent the cover 2 from bumping into other items.

[0030] The shock-absorbing rubber pad 101 installed at the lower end of the base support 1 can reduce the impact of bumps on the base support 1 and the inside of the cover 2 during transportation. The protrusions 102 can increase the friction between the base support 1 and the transport vehicle, preventing the base support 1 from sliding accidentally, thereby effectively reducing the risk of the transport cavity.

[0031] Through the above steps, the two sets of positioning frames 402 contact the outer surface of the cavity placed inside the base 1, thereby positioning the transported cavity and preventing accidental sliding of the cavity during transportation. The positioning frames 402 slide along the slide groove 401 and are inserted into the appropriate fixing hole 404 by the insertion rod 405, thereby limiting the position of laser cavities of different specifications, effectively improving the applicability of the transport box and reducing the risk of cavity transportation. This solves the problem that due to the different sizes of various excimer laser cavities, the cavities often slide inside the transport box due to bumps during transportation, which may cause damage to various cavities of the excimer laser during transportation.

[0032] The embodiments of the present invention have been described in detail above with reference to the accompanying drawings. However, the present invention is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present invention.

Claims

1. A transport box for an excimer laser cavity with an anti-slip structure, comprising a base (1) and a cover (2); characterized in that: It also includes a slide groove (401), a positioning frame (402), an anti-slip pad (403), a fixing hole (404), a plug rod (405), a spring (406), a first wedge (407), a handle (408), a second wedge (409), and a magnet (410). The cover (2) is located above the base (1). The bottom surface of the base (1) has two sets of symmetrical slide grooves (401). The base (1) has two sets of symmetrical positioning frames (402) inside. The positioning frames (402) are slidably connected to the slide grooves (401). An anti-slip pad (403) is provided on one side of the positioning frame (402). Multiple fixing holes are linearly arranged on the side wall inside the slide groove (401). (404) A rod (405) is slidably connected inside the positioning frame (402). One end of the rod (405) is located inside the fixing hole (404). A first wedge (407) is fixedly installed at the other end of the rod (405). A spring (406) is fixedly installed between the first wedge (407) and the positioning frame (402). The lower end of the handle (408) is inserted into the positioning frame (402). The handle (408) is slidably connected to the positioning frame (402). A second wedge (409) is fixedly installed at the lower end of the handle (408). A magnet (410) is embedded and fixed at the upper end of the positioning frame (402). The magnet (410) is magnetically connected to the handle (408).

2. The excimer laser cavity transport box with anti-slip structure according to claim 1, characterized in that: The bottom of the base (1) is fixedly installed with a vibration isolation pad (101). The bottom of the vibration isolation pad (101) is provided with multiple sets of protrusions (102), and the multiple sets of protrusions (102) are arranged in a matrix.

3. The excimer laser cavity transport box with anti-slip structure according to claim 1, characterized in that: Multiple sets of U-shaped grooves (103) are opened on the inner walls of both ends of the base (1), and the multiple sets of U-shaped grooves (103) are evenly arranged in a linear manner.

4. The excimer laser cavity transport box with anti-slip structure according to claim 1, characterized in that: The outer sidewalls of the cover (2) are provided with protective plates (201). The outer side of the protective plate (201) is a wavy structure, and the inner thread of the protective plate (201) is connected with bolts (202).

5. The excimer laser cavity transport box with anti-slip structure according to claim 1, characterized in that: An external corner strip (203) is fixedly installed at each of the four corners of the outer perimeter of the cover (2). The outer perimeter of the external corner strip (203) is an arc-shaped structure, and a protective pad (204) is fixedly installed on the outside of the arc-shaped structure of the external corner strip (203).

6. The excimer laser cavity transport box with anti-slip structure according to claim 4, characterized in that: Four sets of elastic clips (301) are fixedly installed on the outer periphery of the cover (2). The elastic clips (301) are located below the protective plate (201). Four sets of fixing brackets (302) are fixedly installed on the outer periphery of the base (1). The fixing brackets (302) are engaged with the elastic clips (301).

7. The excimer laser cavity transport box with anti-slip structure according to claim 1, characterized in that: The lower end of the cover (2) is fixedly installed with four sets of positioning rods (303), and the upper end of the base (1) is provided with four sets of positioning holes (304). The four sets of positioning rods (303) correspond to the four sets of positioning holes (304).