Gas cylinder holder

By designing a cylinder support with a hollow bottom beam and transverse support beams, the instability problem of large-capacity cylinders when arranged horizontally was solved, achieving stable support and convenient transportation of the cylinders, and reducing weight and cost.

CN224454341UActive Publication Date: 2026-07-03DALIAN CIMC LOGISTICS EQUIP +2

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
DALIAN CIMC LOGISTICS EQUIP
Filing Date
2025-07-14
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

Large-capacity gas cylinders are difficult to place stably when arranged horizontally, making transportation inconvenient.

Method used

A gas cylinder support bracket was designed, comprising two bottom beams and two support beams. The bottom beams are hollow inside and have two horizontally connected ends. The support beams are fixed to the top of the bottom beams in the horizontal direction to form a support position to accommodate and limit the gas cylinders. The support beams are plugged into the transfer equipment for easy movement.

Benefits of technology

It improves the support stability and transportation convenience of gas cylinders, while reducing the weight and cost of gas cylinder brackets. It has a simple structure, strong practicality, and is easy to process.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model provides a gas cylinder support bracket, including at least two base beams and two support beams. The at least two base beams are spaced longitudinally, each base beam being hollow inside and having two through-holes at its transverse ends to form slots for insertion and engagement with transfer equipment. The two support beams are fixed laterally at intervals on the top of all the base beams, forming a support position for accommodating a gas cylinder extending longitudinally. The two support beams can abut against the gas cylinder on both transverse sides to limit its movement laterally, preventing rolling and improving the cylinder's stability. This application utilizes the base beams' own structure as slots for insertion and engagement with transfer equipment, facilitating subsequent movement of the gas cylinder support bracket and the gas cylinder for transfer. Furthermore, this design reduces the weight of the base beams, resulting in a lighter overall gas cylinder support bracket and easier movement.
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Description

Technical Field

[0001] This utility model relates to the field of gas cylinder transportation technology, and in particular to a gas cylinder bracket. Background Technology

[0002] Gas cylinders, as a type of pressure vessel, play a vital role in the storage and transportation of gaseous or liquid substances. However, with increasing production demands, the volume of gas cylinders is gradually increasing, which brings inconvenience to the transfer of gas cylinders.

[0003] To lower the center of gravity of large-capacity gas cylinders, they are currently often arranged horizontally. However, since gas cylinders are generally cylindrical, meaning their cross-section is circular, horizontally arranged cylinders cannot be placed stably.

[0004] Therefore, there is an urgent need to provide a gas cylinder support bracket for supporting gas cylinders. Utility Model Content

[0005] The purpose of this utility model is to provide a gas cylinder support with a simple structure, which can support the gas cylinder and limit its position.

[0006] To achieve the above objectives, the present invention adopts the following technical solution:

[0007] According to one aspect of this application, a gas cylinder holder is provided, comprising:

[0008] At least two bottom beams are distributed longitudinally at intervals; each bottom beam is hollow inside and has through-holes at both ends in the transverse direction to form slots, which are used to insert and cooperate with transfer equipment.

[0009] Two support beams are fixed at a lateral interval to the top of all the bottom beams. The two support beams enclose a support position for accommodating a gas cylinder that extends longitudinally along its axis, and the support beams are used to abut and support the gas cylinder.

[0010] In some embodiments, the bottom of the bottom beam has an opening;

[0011] The bottom beam includes two side plates and a top plate. The two side plates are spaced apart longitudinally, and the top plate is fixed to the top of the two side plates. The top plate and the two side plates enclose the slot.

[0012] The bottom beam also includes two reinforcing plates, each of which is fixed to the bottom of a side plate, and each reinforcing plate protrudes longitudinally from the corresponding side plate.

[0013] In some embodiments, the top surface of each of the support beams forms a support surface, the support surfaces of the two support beams are inclined from top to bottom towards each other, and the two support surfaces enclose the support position.

[0014] In some embodiments, each of the supporting beams is hollow inside and has longitudinally continuous ends;

[0015] Each of the supporting beams includes a first bearing plate, a second bearing plate, and a support plate. The first bearing plate and the second bearing plate are fixed to the top of the bottom beam at a transverse interval. The first bearing plate is located outside the second bearing plate and extends upward beyond the second bearing plate. The support plate is fixed to the top of the first bearing plate and the second bearing plate, and the top surface of the support plate constitutes the support surface.

[0016] In some embodiments, the support beam further includes a first extension plate and a second extension plate, the first extension plate being fixed to the lateral inner side of the bottom of the first bearing plate, the first extension plate being attached to the top of the bottom beam and fixedly connected to the bottom beam;

[0017] The second extension plate is fixed to the inner side of the bottom of the second bearing plate, and the second extension plate is attached to the top of the bottom beam and fixedly connected to the bottom beam;

[0018] The first bearing plate, the support plate, the second bearing plate, the first extension plate, and the second extension plate are integrally bent into shape.

[0019] In some embodiments, the gas cylinder bracket further includes a plurality of stops, at least one of the stops is fixed to the lateral outer side of each support beam, and each stop is correspondingly fixed to the top of a bottom beam;

[0020] The outer lateral side of the stop block does not extend beyond the outer lateral side of the bottom beam.

[0021] In some embodiments, each of the support beams is provided with a buffer pad, which is used to elastically support the gas cylinder; the longitudinal ends of the buffer pad are flush with the longitudinal ends of the support beam.

[0022] The cushioning pad is made of elastic material.

[0023] In some embodiments, the gas cylinder bracket further includes a plurality of pads, and at least one of the pads is provided at the bottom of each of the bottom beams;

[0024] The pad is made of anti-slip material.

[0025] In some embodiments, the gas cylinder bracket further includes at least two connectors, all of which are longitudinally disposed at the bottom of the two support beams. The connectors are used to surround the outer periphery of the gas cylinder to achieve the connection and fixation between the gas cylinder and the support beam.

[0026] In some embodiments, each of the connectors has a locking member at its first end, which is used to wrap around and lock the second end of the connector so that the connector is in a ring shape and fits tightly against the outer periphery of the gas cylinder and the support beam.

[0027] As can be seen from the above technical solution, this utility model has at least the following advantages and positive effects:

[0028] In this application, since the two support beams are fixed to the top of all the bottom beams at a lateral interval, the support beams protrude upwards from the bottom beams. The support position formed by the two support beams can accommodate and limit a gas cylinder that extends longitudinally along an axis. The two support beams can abut against the gas cylinder on both lateral sides to achieve the purpose of limiting the gas cylinder in the lateral direction, thereby preventing the gas cylinder from rolling and improving the support stability of the gas cylinder.

[0029] Because each bottom beam has a hollow interior and is open at both ends laterally, this application utilizes the bottom beam's own structure as a slot for insertion and mating with the transfer equipment, facilitating the subsequent movement of the gas cylinder bracket and cylinders to achieve cylinder transfer. Furthermore, this design reduces the weight of the bottom beams, enabling a lighter overall gas cylinder bracket and facilitating its movement.

[0030] In addition, the gas cylinder bracket, which consists of a bottom beam and a support beam, has advantages such as high structural strength, simple structure, strong practicality, easy processing, and low cost. Attached Figure Description

[0031] Figure 1 This is a three-dimensional structural diagram of the gas cylinder bracket in this embodiment.

[0032] Figure 2 yes Figure 1 A schematic diagram of the structure along the AA direction.

[0033] Figure 3 yes Figure 1 A schematic diagram of the structure along the BB direction.

[0034] Figure 4 yes Figure 2 The diagram shows the effect of the gas cylinder support bracket supporting the gas cylinder.

[0035] Figure 5 yes Figure 3 The diagram shows the effect of the gas cylinder supporting the gas cylinder.

[0036] Figure 6 This is a rendering of the gas cylinder carrier and gas cylinder during the transfer process.

[0037] The annotations in the attached figures are explained as follows:

[0038] 100. Gas cylinder bracket; 1. Bottom beam; 11. Slot; 12. Side plate; 13. Top plate; 14. Reinforcing plate; 2. Support beam; 21. Support plate; 22. First bearing plate; 23. Second bearing plate; 24. First extension plate; 25. Second extension plate; 3. Stop block; 4. Buffer pad; 5. Pad plate; 6. Connector; 7. Locking device; 200. Gas cylinder; 300. Transfer equipment; 310. Forklift. Detailed Implementation

[0039] Typical embodiments embodying the features and advantages of this utility model will be described in detail in the following description. It should be understood that this utility model can have various variations in different embodiments, all of which do not depart from the scope of this utility model, and the descriptions and illustrations therein are for illustrative purposes only and not intended to limit this utility model.

[0040] In the description of this application, it should be understood that, in the embodiments shown in the accompanying drawings, the indications of direction or positional relationships (such as up, down, left, right, front, and back) are merely for the convenience of describing this application 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. These descriptions are appropriate when these elements are in the positions shown in the accompanying drawings. If the description of the positions of these elements changes, these directional indications also change accordingly.

[0041] Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of the stated features. In the description of this application, "a plurality of" means two or more, unless otherwise explicitly specified.

[0042] This application provides a gas cylinder bracket for supporting and limiting the position of a gas cylinder.

[0043] The following detailed description of specific embodiments of the gas cylinder holder of this application is provided in conjunction with the accompanying drawings.

[0044] Figure 1 This is a three-dimensional structural diagram of the gas cylinder holder in this embodiment. Figure 2 for Figure 1 A schematic diagram of the structure along the AA direction. Figure 3 for Figure 1 A schematic diagram of the structure along the BB direction. Figure 4 for Figure 2 The diagram shown illustrates the effect of the gas cylinder support bracket holding the gas cylinder. Figure 5 for Figure 3 The diagram shown illustrates the effect of the gas cylinder supporting the gas cylinder. Figure 6This is a rendering of the gas cylinder carrier and gas cylinder during the transfer process.

[0045] refer to Figures 1-6 The gas cylinder bracket 100 includes at least two bottom beams 1 and two support beams 2. The at least two bottom beams 1 are spaced longitudinally, each bottom beam 1 being hollow inside and having two transversely connected ends to form a slot 11, which is used for insertion and engagement with the transfer equipment 300. The two support beams 2 are fixed transversely at intervals to the top of all the bottom beams 1, and the two support beams 2 enclose a support position for accommodating a gas cylinder 200 extending longitudinally along its axis, and the support beams 2 are used to abut against and support the gas cylinder 200.

[0046] In this application, since the two support beams 2 are fixed to the top of all the bottom beams 1 at a lateral interval, the support beams 2 protrude upward from the bottom beams 1. The support position formed by the two support beams 2 can accommodate and limit the gas cylinder 200 extending longitudinally along an axis. The two support beams 2 can abut against the gas cylinder 200 on both sides of the lateral direction to achieve the purpose of limiting the gas cylinder 200 in the lateral direction, thereby preventing the gas cylinder 200 from rolling and improving the support stability of the gas cylinder 200.

[0047] Since each bottom beam 1 has a hollow interior and is open at both ends laterally, this application utilizes the structure of the bottom beam 1 itself as a slot 11 to engage with the transfer device 300, facilitating the subsequent movement of the gas cylinder bracket 100 and the gas cylinder 200 for the transfer of the gas cylinder 200. Furthermore, this design reduces the weight of the bottom beam 1, thereby achieving a lighter overall gas cylinder bracket 100 and facilitating its movement.

[0048] In addition, the gas cylinder bracket 100, which consists of the bottom beam 1 and the support beam 2, has advantages such as high structural strength, simple structure, strong practicality, easy processing and low cost.

[0049] Among them, the transfer device 300 mentioned above is a forklift, that is, the slot 11 is connected to the forklift fork 310.

[0050] It should be noted that the horizontal direction mentioned above refers to the length direction of the bottom beam 1, and the longitudinal direction refers to the extension direction of the support beam 2, and the same applies below. For ease of description, it is now defined that the direction towards the interval between the two support beams 2 is the inside, and the opposite direction is the outside.

[0051] In this embodiment, two bottom beams 1 are used as an example for illustration. Of course, in other embodiments, the number of bottom beams 1 can also be three or more.

[0052] In this embodiment, the two bottom beams 1 are spaced apart longitudinally. Each bottom beam 1 is hollow inside and has slots 11 formed at both ends laterally. The slots 11 are used to engage with the transfer device 300 to facilitate the subsequent transfer of the gas cylinder bracket 100. Furthermore, the above design can reduce the weight of the bottom beams 1, thereby achieving a lighter overall gas cylinder bracket 100 and facilitating its movement.

[0053] The bottom opening of the bottom beam 1 can further reduce the weight of the bottom beam 1.

[0054] Specifically, the bottom beam 1 includes two side plates 12 and a top plate 13. The two side plates 12 are spaced apart longitudinally, and the top plate 13 is fixed to the top of the two side plates 12. The top plate 13 and the two side plates 12 enclose a slot 11.

[0055] Optionally, the bottom beam 1 may also include two reinforcing plates 14, each reinforcing plate 14 being fixed to the bottom of one side plate 12. Each reinforcing plate 14 protrudes longitudinally from the corresponding side plate 12, thereby strengthening the structural strength of the bottom beam 1 and increasing the load-bearing area of ​​the bottom beam 1, thus improving the stability of the gas cylinder bracket 100. The two reinforcing plates 14 may be arranged on the same side of the two side plates 12 or on opposite sides of the two side plates 12.

[0056] In this embodiment, the bottom beam 1 can be made of channel steel. In other embodiments, the bottom beam 1 can also be made of square tubular steel, etc.

[0057] In this embodiment, two support beams 2 are fixed at a lateral interval to the top of all the bottom beams 1. The two support beams 2 enclose a support position for accommodating a gas cylinder 200 extending longitudinally along its axis. The two support beams 2 can abut against the gas cylinder 200 on both lateral sides to limit the gas cylinder 200 in the lateral direction, thereby preventing the gas cylinder 200 from rolling and improving the support stability of the gas cylinder 200.

[0058] The two support beams 2 are symmetrically arranged in the vertical plane about the transverse centerline of the bottom beam 1, which can balance the force on the bottom beam 1 in the transverse direction and reduce the deformation or damage of the bottom beam 1 caused by asymmetrical force. When the two support beams 2 jointly support a gas cylinder 200, the axis of symmetry of the two support beams 2, the axis of the gas cylinder 200 and the transverse centerline of the bottom beam 1 can be located on the same vertical plane, which facilitates the collinear distribution of the center of gravity of the gas cylinder 200 and the center of gravity of the gas cylinder bracket 100 in the vertical direction. This allows the weight of the gas cylinder 200 to be evenly distributed on the two support beams 2, and evenly distributed at both ends of the transverse direction of the bottom beam 1, and evenly distributed on the two bottom beams 1, so that the entire gas cylinder bracket 100 can be evenly stressed in the transverse and longitudinal directions, improving the stability of the gas cylinder 200.

[0059] Optionally, the top surface of each support beam 2 forms a support surface, and the support surfaces of the two support beams 2 are inclined towards each other from top to bottom, forming a support position when the two support surfaces enclose each other. When supporting the gas cylinder 200, the inclined support surfaces can decompose the force exerted by the gas cylinder 200 into a normal force perpendicular to the support surface and a tangential force parallel to the support surface, reducing the risk of lateral slippage of the gas cylinder 200, improving its stability, and avoiding stress concentration. Furthermore, the above design also allows the distance between the two support surfaces to gradually decrease from top to bottom, facilitating the adaptation to gas cylinders 200 of different diameters and improving the versatility and practicality of the gas cylinder bracket 100.

[0060] In this embodiment, each support beam 2 is hollow inside and has two longitudinal ends that are through. This design makes the support beam 2 have a smaller weight, so as to make the gas cylinder bracket 100 lighter and facilitate the movement of the gas cylinder bracket 100.

[0061] Specifically, each supporting beam 2 includes a first bearing plate 22, a second bearing plate 23, and a support plate 21. The first bearing plate 22 and the second bearing plate 23 are fixed to the top of the bottom beam 1 at a transverse interval, with the first bearing plate 22 located outside the second bearing plate 23 and extending upwards beyond the second bearing plate 23. The support plate 21 is fixed to the top of the first bearing plate 22 and the second bearing plate 23. Because the first bearing plate 22 extends upwards beyond the second bearing plate 23, the support plate 21 tilts downwards towards the other supporting beam 2, meaning that the top surface of the support plate 21 constitutes a supporting surface.

[0062] That is, the support beam 2 in this embodiment adopts a trapezoidal cross-section, which has good structural stability.

[0063] Optionally, the support beam 2 further includes a first extension plate 24, which is fixed to the inner lateral side of the bottom of the first bearing plate 22 and fits against the top of the bottom beam 1, and is fixedly connected to the bottom beam 1. This design can increase the contact and connection area between the support beam 2 and the bottom beam 1, thereby improving the connection strength and stability between the support beam 2 and the bottom beam 1. In other embodiments, the first extension plate 24 may also be located on the outer lateral side of the first bearing plate 22.

[0064] In this embodiment, the first extension plate 24 and the second bearing plate 23 are distributed laterally, which makes the support beam 2 have a smaller weight, so as to achieve the weight reduction of the gas cylinder bracket 100 and facilitate the movement of the gas cylinder bracket 100.

[0065] Specifically, the first extension plate 24 is welded and fixed to the bottom beam 1. The design of the first extension plate 24 also facilitates welding operations.

[0066] The support beam 2 also includes a second extension plate 25, which is fixed to the inner lateral side of the bottom of the second bearing plate 23. The second extension plate 25 is attached to the top of the bottom beam 1 and is fixedly connected to the bottom beam 1. This design increases the contact and connection area between the support beam 2 and the bottom beam 1, increases the load-bearing area of ​​the support beam 2, and thus improves the connection strength and stability between the support beam 2 and the bottom beam 1.

[0067] Specifically, the second extension plate 25 is welded and fixed to the bottom beam 1. The design of the second extension plate 25 also facilitates welding operations.

[0068] In other embodiments, the second extension plate 25 may also be located laterally outside the second support plate 23. When the first extension plate 24 is located laterally inside the first support plate 22, the first extension plate 24 and the second extension plate 25 may be laterally spaced or connected to form a single unit. Alternatively, when the first extension plate 24 is located laterally outside the first support plate 22, the second extension plate 25 and the first support plate 22 are laterally spaced.

[0069] In this embodiment, the first bearing plate 22, the support plate 21, the second bearing plate 23, the first extension plate 24, and the second extension plate 25 are integrally bent and formed, which makes the support beam 2 have high structural strength.

[0070] In this embodiment, the gas cylinder bracket 100 further includes multiple stops 3. At least one stop 3 is fixed to the outer lateral side of each support beam 2, and each stop 3 is correspondingly fixed to the top of a bottom beam 1. The stop 3 can provide abutment support to the support beam 2 on the outer lateral side, thereby improving the stability of the support beam 2. Furthermore, the above design can also increase the connection strength between the support beam 2 and the bottom beam 1, thereby improving the structural strength of the gas cylinder bracket 100.

[0071] Specifically, the stop block 3 corresponding to each support beam 2 is also provided in a one-to-one correspondence with the bottom beam 1. For example, when there are two bottom beams 1, there are four stop blocks 3. Two stop blocks 3 are welded and fixed to the outer side of the first bearing plate 22 of each support beam 2 along the longitudinal direction, and the two stop blocks 3 are welded and fixed to the top of the two bottom beams 1 in a one-to-one correspondence.

[0072] In this embodiment, the outer lateral side of the stop block 3 does not extend beyond the outer lateral side of the bottom beam 1 to avoid interfering with the slot 11 on the bottom beam 1, thus facilitating the alignment of the forklift fork 310 with the slot 11 and its insertion into the slot 11. Exemplarily, the outer lateral side of the stop block 3 is flush with the outer lateral side of the bottom beam 1. Alternatively, the outer lateral side of the bottom beam 1 extends outward beyond the stop block 3.

[0073] The interior of the stop block 3 is hollow. This design makes the stop block 3 lighter, so as to achieve the weight reduction of the gas cylinder bracket 100 and facilitate the movement of the gas cylinder bracket 100.

[0074] refer to Figure 1 , Figure 2 Each support beam 2 is also equipped with a buffer pad 4, which is used to elastically support the gas cylinder 200, so as to buffer the gas cylinder 200, avoid stress concentration, and better protect the gas cylinder 200. Specifically, the buffer pad 4 can be glued to the top surface of the support plate 21 of the support beam 2, and the buffer pad 4 is distributed parallel to the support plate 21.

[0075] In this embodiment, the buffer pad 4 is made of an elastic material to allow it to undergo elastic deformation. Since the buffer pad 4 is parallel to the support plate 21, that is, the buffer pad 4 is a planar shape sloping from top to bottom, and since the contact between the planar surface and the cylindrical gas cylinder 200 is often a line-to-surface contact, the buffer pad 4, made of an elastic material, can undergo elastic deformation under the gravity of the gas cylinder 200 after contacting it. This allows it to adapt to the outer periphery of the gas cylinder 200, ensuring its surface completely adheres to the outer periphery, thus better enveloping and protecting the gas cylinder 200. For example, the buffer pad 4 can be made of rubber or polyurethane.

[0076] The longitudinal ends of the buffer pad 4 are flush with the longitudinal ends of the support beam 2. This design allows the buffer pad 4 to fully cover the support beam 2 in the longitudinal direction, resulting in a larger contact area between the buffer pad 4 and the gas cylinder 200, so as to better protect the gas cylinder 200.

[0077] The buffer pad 4 is wider than 30mm, which gives the buffer pad 4 a larger contact area with the gas cylinder 200, so as to better protect the gas cylinder 200.

[0078] The number of buffer pads 4 can be one or multiple pads distributed at intervals.

[0079] refer to Figures 1-3 In this embodiment, the gas cylinder bracket 100 also includes multiple pads 5, and at least one pad 5 is provided at the bottom of each bottom beam 1. Specifically, the pads 5 are fixed to the bottom of the two reinforcing plates 14 of the bottom beam 1.

[0080] In this embodiment, at least two pads 5 are fixed at a transverse interval at the bottom of each bottom beam 1, and all the pads 5 are evenly distributed on the bottom beam 1. In other embodiments, the number of pads 5 may also be one.

[0081] In this embodiment, the pad 5 is made of an anti-slip material to increase friction with the outside and prevent the gas cylinder holder 100 from sliding, thereby improving the stability of the gas cylinder holder 100. For example, the pad 5 can be made of EVA material.

[0082] refer to Figure 5 The gas cylinder bracket 100 also includes at least two connectors 6. All connectors 6 are longitudinally arranged at the bottom of the two support beams 2. The connectors 6 are used to wrap around the outer periphery of the gas cylinder 200 to achieve the connection and fixation between the gas cylinder 200 and the support beam 2, so as to prevent the gas cylinder 200 from falling off during transportation and improve the stability and transportation safety of the gas cylinder 200.

[0083] The connector 6 can be a strip structure with a certain width and length, or a rope structure with a certain length.

[0084] Each connector 6 has a locking member 7 at its first end. The locking member 7 is used to wrap around and lock the second end of the connector 6 so that the connector 6 is in a ring shape and closely attached to the outer periphery of the gas cylinder 200 and the support beam 2, thereby securing the gas cylinder 200 to the gas cylinder bracket 100.

[0085] For example, the locking element 7 can be a ratchet tightener.

[0086] In other embodiments, the opposite ends of the connector 6 can also be connected or disassembled through a detachable locking ring or a latch.

[0087] As can be seen from the above technical solution, this utility model has at least the following advantages and positive effects:

[0088] In this application, since the two support beams are fixed to the top of all the bottom beams at a lateral interval, the support beams protrude upwards from the bottom beams. The support position formed by the two support beams can accommodate and limit a gas cylinder that extends longitudinally along an axis. The two support beams can abut against the gas cylinder on both lateral sides to achieve the purpose of limiting the gas cylinder in the lateral direction, thereby preventing the gas cylinder from rolling and improving the support stability of the gas cylinder.

[0089] Because each bottom beam has a hollow interior and is open at both ends laterally, this application utilizes the bottom beam's own structure as a slot for insertion and mating with the transfer equipment, facilitating the subsequent movement of the gas cylinder bracket and cylinders to achieve cylinder transfer. Furthermore, this design reduces the weight of the bottom beams, enabling a lighter overall gas cylinder bracket and facilitating its movement.

[0090] In addition, the gas cylinder bracket, which consists of a bottom beam and a support beam, has advantages such as high structural strength, simple structure, strong practicality, easy processing, and low cost.

[0091] Although the present invention has been described with reference to several typical embodiments, it should be understood that the terminology used is descriptive and exemplary, and not restrictive. Since the present invention can be embodied in many forms without departing from the spirit or essence of the invention, it should be understood that the above embodiments are not limited to any of the foregoing details, but should be interpreted broadly within the spirit and scope defined by the appended claims. Therefore, all variations and modifications falling within the scope of the claims or their equivalents should be covered by the appended claims.

Claims

1. A gas cylinder cradle, characterised in that, include: At least two bottom beams are distributed longitudinally at intervals; each bottom beam is hollow inside and has through-holes at both ends in the transverse direction to form slots, which are used to insert and cooperate with transfer equipment. Two support beams are fixed at a lateral interval to the top of all the bottom beams. The two support beams enclose a support position for accommodating a gas cylinder that extends longitudinally along its axis, and the support beams are used to abut and support the gas cylinder.

2. The gas cylinder cradle of claim 1, wherein The bottom opening of the bottom beam; The bottom beam includes two side plates and a top plate. The two side plates are spaced apart longitudinally, and the top plate is fixed to the top of the two side plates. The top plate and the two side plates enclose the slot. The bottom beam also includes two reinforcing plates, each of which is fixed to the bottom of a side plate, and each reinforcing plate protrudes longitudinally from the corresponding side plate.

3. The gas cylinder cradle of claim 1, wherein The top surface of each of the supporting beams forms a supporting surface, and the supporting surfaces of the two supporting beams are inclined from top to bottom towards each other, and the two supporting surfaces enclose the supporting position.

4. The gas cylinder cradle of claim 3, wherein Each of the aforementioned support beams is hollow inside and has two longitudinally continuous ends; Each of the supporting beams includes a first bearing plate, a second bearing plate, and a support plate. The first bearing plate and the second bearing plate are fixed to the top of the bottom beam at a transverse interval. The first bearing plate is located outside the second bearing plate and extends upward beyond the second bearing plate. The support plate is fixed to the top of the first bearing plate and the second bearing plate, and the top surface of the support plate constitutes the support surface.

5. The gas cylinder holder according to claim 4, characterized in that, The support beam also includes a first extension plate and a second extension plate. The first extension plate is fixed to the inner side of the bottom of the first bearing plate and is attached to the top of the bottom beam and fixedly connected to the bottom beam. The second extension plate is fixed to the inner side of the bottom of the second bearing plate, and the second extension plate is attached to the top of the bottom beam and fixedly connected to the bottom beam; The first bearing plate, the support plate, the second bearing plate, the first extension plate, and the second extension plate are integrally bent into shape.

6. The gas cylinder cradle of claim 1, wherein, The gas cylinder bracket also includes multiple stops, with at least one stop fixed on the lateral outer side of each support beam, and each stop correspondingly fixed to the top of a bottom beam; The outer lateral side of the stop block does not extend beyond the outer lateral side of the bottom beam.

7. The gas cylinder cradle of claim 1, wherein Each of the support beams is provided with a buffer pad, which is used to elastically support the gas cylinder; the longitudinal ends of the buffer pad are flush with the longitudinal ends of the support beam. The cushioning pad is made of elastic material.

8. The gas cylinder cradle of claim 1, wherein, The gas cylinder support also includes multiple pads, and at least one pad is provided at the bottom of each of the bottom beams; The pad is made of anti-slip material.

9. The gas cylinder cradle of claim 1, wherein, The gas cylinder bracket also includes at least two connectors, all of which are longitudinally disposed at the bottom of the two support beams. The connectors are used to wrap around the outer periphery of the gas cylinder to achieve the connection and fixation between the gas cylinder and the support beam.

10. The gas cylinder cradle of claim 9, wherein, Each of the connectors has a locking member at its first end, which is used to wrap around and lock the second end of the connector so that the connector is in a ring shape and fits tightly against the outer periphery of the gas cylinder and the support beam.