CN223371838U - Coil stock loading platform - Google Patents

Abstract

The utility model relates to a coil loading platform, comprising a platform body, a plurality of fixed support frames, at least one support beam assembly, at least one connecting beam assembly and at least one pair of movable support seats. The plurality of fixed support frames are arranged at intervals along the longitudinal direction of the platform body. Each support beam assembly is respectively arranged between two adjacent fixed support frames. Each connecting beam assembly is respectively connected between two adjacent fixed support frames and fixedly connected to the support beam assembly. Each pair of movable support seats is respectively arranged between two adjacent fixed support frames, and the two movable support seats in each pair of movable support seats are respectively slidably connected to each connecting beam assembly, so that the two movable support seats in each pair of movable support seats can be moved closer to or farther away from each other. By arranging the movable support seats in pairs and enabling each movable support seat to slide longitudinally, it is possible to load coils of different diameters and different quantities of coils, and it is applicable to a wide range of coil specifications and flexible loading.

Description

Coil stock loading platform

Technical Field

The utility model relates to the technical field of containers, in particular to a coil stock loading platform.

Background

The coil stock transportation of coil stock such as coil of strip, aluminium coil is mostly adopted horizontal loading to make things convenient for the loading and unloading of coil stock. In order to prevent the rolling of the coil stock in transportation, the coil stock needs to be fixed, and the steel seat frame is widely applied due to the advantages of reliable fixation of the coil stock, convenient operation, repeated use and the like.

In order to improve the loading and unloading and transporting efficiency, the steel seat frame is developed into a special container for transporting coil stock in a containerization way, namely, a special container for transporting coil stock loads a plurality of coil stock and is suitable for intermodal transportation of railways, highways and the like.

Along with the continuous development of coil stock transportation technology, a novel special container needs to be developed and designed, so that the special container can be suitable for more coil stock specifications, and the transportation cost is reduced.

Disclosure of utility model

An object of the present utility model is to solve the drawbacks of the prior art and to provide a coil loading platform. In order to solve the technical problems, the utility model adopts the following technical scheme:

A coil loading platform comprising:

The platform body comprises two main longitudinal beams which are arranged in parallel at intervals;

the fixed support frames are arranged at intervals along the longitudinal direction of the platform body;

Each support beam assembly is arranged between two adjacent fixed support frames respectively, each support beam assembly is spaced from the fixed support frames on two sides of the support beam assembly, extends along the transverse direction of the platform body, and two ends of the support beam assembly are fixedly connected with two main longitudinal beams respectively;

Each connecting beam assembly is respectively connected between two adjacent fixed supporting frames and fixedly connected with the supporting beam assembly, extends along the longitudinal direction of the platform body and is arranged at intervals with the two main longitudinal beams;

at least a pair of movable supporting seats, every movable supporting seat sets up respectively between two adjacent fixed support frames, and two movable supporting seats in every movable supporting seat of pair respectively with every tie-beam subassembly sliding connection for can be close to each other or keep away from between two movable supporting seats in every movable supporting seat of pair.

In one embodiment, the connecting beam assembly is provided with a connecting chute, the connecting chute extends longitudinally along the platform body, the movable supporting seat is provided with a sliding connecting portion corresponding to the connecting chute, and the sliding connecting portion is in sliding connection with the connecting chute.

In one embodiment, the movable supporting seat comprises a supporting base, the sliding connection part comprises a first connecting piece and a second connecting piece, the first connecting piece is fixedly connected with the supporting base and can extend into the connecting chute, the second connecting piece is detachably connected with the first connecting piece, and the second connecting piece is used for preventing the first connecting piece from falling out of the connecting chute.

In one embodiment, the connecting beam assembly comprises a connecting plate and two connecting girders, the two connecting girders are arranged at opposite intervals, the connecting plate is connected between the two connecting girders, the connecting plate and the two connecting girders can be enclosed to form a connecting chute, and the connecting plate is provided with a strip-shaped hole for the first connecting piece to penetrate.

In one embodiment, the upper surface of the connecting girder is a surface in sliding contact with the movable supporting seat, the upper surface of the connecting plate is flush with the upper surface of the connecting girder, and the lower surface of the connecting girder protrudes downwards from the connecting plate, so that the notch of the connecting chute is downwards.

In one embodiment, the support base comprises a support base plate and two support panels, wherein the two support panels are respectively connected to two ends of the support base plate in the longitudinal direction, each support panel is respectively obliquely arranged relative to the support base plate, and the two support panels are mutually connected away from the side edges of the support base plate.

In one embodiment, the support base further comprises a support web vertically connected between the support floor and the two support panels.

In one embodiment, the movable supporting seat comprises a connecting and fixing piece, and the connecting and fixing piece is used for fixedly connecting the two supporting bases;

The connecting fixing piece and each supporting base connected with the connecting fixing piece can form a movable supporting base comprising a plurality of supporting bases, and the supporting bases in the movable supporting base are arranged at intervals along the transverse direction of the platform body;

And a connecting beam assembly is arranged between every two adjacent fixed support frames corresponding to each supporting base, and the supporting bases are in sliding connection with the connecting beam assemblies.

In one embodiment, each support beam assembly includes two main support beams disposed in opposed spaced relation;

Each connecting beam assembly comprises a first connecting beam and a second connecting beam, wherein the first connecting beam is arranged between two main supporting beams in each pair of main supporting beams, and the second connecting beam is connected between the main supporting beams in each pair of main supporting beams and a fixed supporting frame positioned at one side of the main supporting beams;

The first connecting beam and the second connecting beam are respectively provided with a connecting chute, the number of the sliding connecting parts arranged on the supporting base is two, and the two sliding connecting parts are respectively in sliding connection with the connecting chute on the first connecting beam and the connecting chute on the second connecting beam.

In one embodiment, the coil loading platform further comprises a limiting assembly, wherein the limiting assembly is arranged on the connecting beam assembly and is used for limiting the sliding range of each movable supporting seat relative to the connecting beam assembly.

In one embodiment, the limiting assembly comprises a first limiting stop and a second limiting stop, the first limiting stop is arranged on the upper surface of the connecting beam assembly and is positioned between the two movable supporting seats in each pair of movable supporting seats, and the first limiting stop can be abutted with the two movable supporting seats in each pair of movable supporting seats so as to limit the limit position of the two movable supporting seats in each pair of movable supporting seats close to each other;

The second limit stop is arranged on the upper surface of the connecting beam assembly and is positioned between each movable supporting seat in each pair of movable supporting seats and the fixed supporting frame at one side of the movable supporting seat, and the second limit stop can be respectively abutted with each movable supporting seat in each pair of movable supporting seats so as to limit the limit positions of the two movable supporting seats in each pair of movable supporting seats, which are far away from each other.

In one embodiment, the number of the fixed support frames is four, the four fixed support frames are two end support frames and two inner support frames respectively, the two end support frames are respectively arranged at the two longitudinal ends of the platform body, the two inner support frames are arranged between the two end support frames, and the inner support frames and the end support frames at one side of the inner support frames form a first bearing groove for bearing the coil stock;

The support beam assembly is arranged between the two inner support frames, and the pair of movable support seats are slidably arranged on the connecting beam assembly between the two inner support frames.

In one embodiment, two movable supporting seats of the pair of movable supporting seats can be close to each other, so that each movable supporting seat of the pair of movable supporting seats forms a second bearing groove for bearing the coil stock with the inner supporting frame at one side of the movable supporting seat;

Two movable supporting seats in the pair of movable supporting seats can be far away from each other, so that a third bearing groove for bearing the coil stock is formed between the pair of movable supporting seats.

According to the technical scheme, the utility model has at least the following advantages and positive effects:

In the utility model, the coil stock loading platform comprises a platform body, a plurality of fixed supporting frames, at least one supporting beam component, at least one connecting beam component and at least one pair of movable supporting seats. Each movable supporting seat in the movable supporting seats arranged in pairs can longitudinally slide along the platform body. Therefore, the interval width between the two movable supporting seats is adjustable, and the interval width between each movable supporting seat and the adjacent fixed supporting frame is also adjustable. Therefore, the coil stock loading platform can load coil stocks with different diameters and different numbers of coil stocks according to the needs, and is applicable to a wide specification range of the coil stocks and more flexible in loading.

The movable supporting seats are arranged in pairs through the supporting beam assemblies and the connecting beam assemblies, so that the movable supporting seats can be designed into a lighter structure and a more convenient structure to move. And the stress of the movable supporting seat for bearing the coil stock can be borne by the supporting beam assembly, the connecting beam assembly and the fixed supporting frame together, so that the bearing capacity of the movable supporting seat is stronger, and the capability of the coil stock loading platform for resisting railway sliding impact is ensured. In other words, the coil stock loading platform can realize the supporting and limiting functions of the movable supporting seat by using less materials and by means of the integral strength of the supporting beam component, the connecting beam component and the fixed supporting frame, thereby being beneficial to reducing the integral manufacturing cost of the platform.

Drawings

Fig. 1 is a schematic structural view of a coil loading platform according to an embodiment.

Fig. 2 is a schematic side view of the coil loading platform of fig. 1.

Fig. 3 is a schematic view of the structure of fig. 2 in use at a first load-bearing recess.

Fig. 4 is a schematic view of the coil loading platform of fig. 1 adjusted to carry 4 coils.

Fig. 5 is a schematic view of the coil loading platform of fig. 1 adjusted to carry 3 coils.

Fig. 6 is a schematic rear view of the coil loading platform of fig. 1.

Fig. 7 is an enlarged schematic view of the structure shown in fig. 2 at B.

Fig. 8 is a schematic structural view of a movable supporting seat in the coil loading platform shown in fig. 1.

Fig. 9 is an enlarged schematic view at a in the structure shown in fig. 1.

The reference numerals are explained as follows:

10-coil loading platform, 101-first bearing groove, 102-second bearing groove, 103-third bearing groove and 20-coil;

100-of a platform body, 110-of a main longitudinal beam, 120-of a main cross beam, 130-of a top corner piece, 140-of a bottom corner piece, 150-of a turnover twist lock, 160-of a rope ring, 170-of a rope hook and 180-of a vertical baffle mounting hole;

200-fixing a supporting frame;

210-end support frames, 211-end main beams, 212-end support plates, 213-bevel back plates;

220-internal support frame, 221-bottom beam, 222-top beam, 223-support frame panel;

300-support beam assembly, 310-main support beam, 311-fork slot;

400-connecting beam assembly;

410-connecting sliding chute, 420-connecting plate, 421-long strip hole and 430-connecting main beam;

440-first connection beam, 450-second connection beam;

500-a movable supporting seat;

510-sliding connection, 511-first connection, 512-second connection;

520-support base, 521-support floor, 522-support panel, 523-support web;

530-connecting the fixing piece, 540-a flexible backing plate;

600-limit assembly, 610-first limit stop, 620-second limit stop.

Detailed Description

Exemplary embodiments that embody features and advantages of the present utility model will be described in detail in the following description. It will be understood that the utility model is capable of various modifications in various embodiments, all without departing from the scope of the utility model, and that the description and illustrations herein are intended to be by way of illustration only and not to be construed as limiting the utility model.

In the description of the present application, it should be understood that in the embodiments shown in the drawings, indications of directions or positional relationships (such as up, down, left, right, front, rear, etc.) are merely for convenience of describing the present application and simplifying the description, and are not indicative or implying that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation. These descriptions are appropriate when these elements are in the positions shown in the drawings. If the description of the position of these elements changes, the indication of these directions changes accordingly.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more of the described features. In the description of the present application, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

The present application provides a coil stock loading platform 10 which is suitable for loading columnar goods such as steel coils and aluminum coils (referred to as coil stock 20 in the present application). The coil loading platform 10 may be a special container for transporting coils to achieve stable loading of a plurality of coils 20 and is suitable for intermodal transportation of railways, roads, etc. For convenience of description, the following defines the longitudinal direction of the coil loading platform 10, the transverse direction, and the vertical direction.

Referring to fig. 1, a coil loading platform 10 according to an embodiment of the present utility model includes a platform body 100, a plurality of fixed supporting frames 200, at least one supporting beam assembly 300, at least one connecting beam assembly 400, and at least one pair of movable supporting seats 500.

The platform body 100 may have a substantially rectangular parallelepiped shape. As shown in fig. 1, the deck body 100 may include two main stringers 110 arranged in parallel at a spacing. The platform body 100 may further include two main beams 120, and the two main beams 120 are respectively connected to both ends of each main girder 110. Two ends of each main cross member 120 are fixedly connected to two main longitudinal members 110, respectively. The two main stringers 110 and the two main cross beams 120 may enclose to form a generally rectangular parallelepiped shaped platform body 100. The main stringers 110 may have a U-shaped steel structure or an H-shaped steel structure. The main beam 120 may be a U-shaped steel structure or an H-shaped steel structure.

As shown in fig. 1, a plurality of fixed supporting frames 200 are disposed at intervals along the longitudinal direction of the platform body 100. In one embodiment, the number of the fixed support frames 200 is four, and the four fixed support frames 200 are two end support frames 210 and two inner support frames 220, respectively. The end support 210 refers to a fixed support 200 located at an end of the platform body 100. The inner support 220 refers to the fixed support 200 positioned between the two end supports 210. The end support frames 210 and the inner support frame 220 are each fixed support frames 200 that are fixed in position relative to the platform body 100.

As shown in fig. 1, two end support frames 210 are respectively disposed at both longitudinal ends of the platform body 100. Illustratively, both ends of each end bracket 210 are fixedly coupled to two main stringers 110, respectively. One side of each end support 210 is fixedly connected to the main beam 120.

Two inner support brackets 220 are disposed between the two end support brackets 210. Both ends of each inner support frame 220 are fixedly coupled to the two main stringers 110, respectively. Wherein, each inner support 220 has a space with the end support 210 at one side thereof, and forms a first bearing groove 101 for bearing the coil stock. As shown in fig. 2, the first bearing groove 101 is preferably in a structure with a wide top and a narrow bottom, so as to be suitable for loading coil materials with different radial dimensions.

Referring to fig. 3, the end support 210 may be constructed such that the end support 210 includes an end girder 211 and an end support plate 212 disposed to be inclined. The two ends of the end girder 211 are fixedly connected with the two main stringers 110, respectively. Wherein the end girders 211 may be rectangular steel structures. When the end main beams 211 are connected between the two main stringers 110, the upper surfaces of the end main beams 211 may be arranged perpendicular to the vertical direction.

As shown in fig. 3, the bottom end of the end support plate 212 is connected to the end main beam 211, and the top end of the end support plate 212 is connected to the main beam 120. In order to facilitate the reliable connection of the end girder 211 with the inclined end support plate 212 and to reduce the groove lower width of the first bearing groove 101, one side of the end girder 211 is further provided with a bevel back plate 213. The inclined plane back plate 213 can be attached to the end support plate 212, so that the end support plate 212 can extend obliquely downwards along the inclined plane back plate 213, and the width of the lower portion of the groove of the first bearing groove 101 is reduced, so that the first bearing groove 101 can load the coil stock 20 with smaller radial size.

In other embodiments, the upper surface of the end girder 211 may be disposed to be inclined with respect to the vertical direction, and the inclination thereof may be consistent with the inclination of the end support plate 212.

As shown in fig. 3, the internal support frame 220 may be constructed such that the internal support frame 220 includes two bottom beams 221 and one top beam 222, and a support frame panel 223 disposed on the top beam 222 and the two bottom beams 221. The top beam 222 is located above the two bottom beams 221. Both ends of each bottom girder 221 are fixedly connected to the two main stringers 110, respectively. The top beam 222 is fixedly connected to the two main stringers 110 at both ends thereof, respectively.

Wherein the bottom beam 221 may be a rectangular steel structure. When the bottom beam 221 is connected between the two main stringers 110, the upper surface of the bottom beam 221 may be arranged obliquely with respect to the vertical direction.

The header 222 may be a rectangular steel structure. The top beam 222 may be disposed with its upper surface perpendicular to the vertical direction when the top beam 222 is connected between the two main stringers 110.

As shown in fig. 3, the cross-sectional shape of the cage panel 223 is generally trapezoidal. The support frame panel 223 may be an integral fold. The two sides of the support frame panel 223 are respectively inclined surfaces which are attached to the upper surfaces of the two bottom beams 221.

As shown in fig. 3, in the present application, the end support 210 is provided with an inclined end support plate 212 and the inner support 220 is provided with an inclined support panel 223. The end support plate 212 and the opposite support frame panel 223 may define a first load bearing recess 101 therebetween that is wider at the top and narrower at the bottom.

In the present application, the purpose of the inclined arrangement of the bottom beams 221, or the inclined back plates 213 provided on the end main beams 211, is to reduce the groove width dimension of the lower portion of the first bearing groove 101, so as to accommodate the loading of the coil stock 20 with smaller diameter, and expand the specification range of the coil stock loading platform 10 for loading the coil stock. The inclined arrangement of the bottom beams 221 also facilitates a secure connection of the support frame panels 223 to the bottom beams 221, and the inclined back plates 213 provided to the end girders 211 also facilitate a secure connection of the end support plates 212 to the end girders 211.

In one example, the surface of the end support plate 212 that is intended to contact the coil stock may be provided with a flexible backing plate that is secured to the end support plate 212 at the top.

The surface of the support frame panel 223 for contacting the coil stock may be provided with a flexible backing plate, which may be fixed to the support frame panel 223 at the top. Wherein the flexible backing plate on the support frame panel 223 may be a single piece that can cover both sides of the support frame panel 223. When the flexible backing plate on the support frame panel 223 is a unitary piece, the middle of the flexible backing plate is secured to the top of the support frame panel 223 by fasteners.

Referring to fig. 1, in the present application, two inner support frames 220 are spaced apart from each other and form an installation space for installing a support beam assembly 300, a connection beam assembly 400, and a movable support 500.

In other embodiments, two inner support frames 220 may be spaced apart from each other to form the first bearing groove 101 for bearing the coil stock. And the support beam assembly 300, the connection beam assembly 400 and the movable support 500 are provided in the interval between the inner support 220 and the end support 210 on one side thereof.

It should be noted that, in the embodiments of the present application, two end supporting frames 210 and two inner supporting frames 220 are provided on the platform body 100 for illustration. It will be appreciated that the platform body 100 may also include a greater number of fixed support shelves 200. For example, the plurality of fixed support frames 200 may include two end support frames 210, and three or more inner support frames 220 may be disposed between the two end support frames 210 at intervals, as the case may be.

Referring to fig. 1, the embodiment of the present application is specifically described by taking a support beam assembly 300, a connection beam assembly 400, and a movable support 500 disposed between two inner support frames 220 as an example. It will be appreciated that when the platform body 100 includes a greater number of fixed support frames 200, the support beam assembly 300, the connection beam assembly 400, and the movable support 500 may be disposed between any adjacent two of the fixed support frames 200, respectively. For example, the platform body 100 includes a plurality of fixed support frames 200, and the plurality of fixed support frames 200 may include two end support frames 210 and three inner support frames 220 disposed at intervals between the two end support frames 210. Wherein, a support beam assembly 300, a connection beam assembly 400 and a pair of movable support seats 500 may be provided between each end support frame 210 and the inner support frame 220 at one side thereof. And a support beam assembly 300, a connection beam assembly 400, and a pair of movable support seats 500 may be provided between the adjacent two inner support frames 220. That is, the platform body 100 may include at least one support beam assembly 300, at least one connection beam assembly 400, and at least one pair of movable support seats 500.

Referring to fig. 1, in the embodiment of the present application, each support beam assembly 300 is respectively disposed between two adjacent fixed support frames 200. Each support beam assembly 300 is spaced apart from the fixed support frames 200 at both sides thereof.

Illustratively, as shown in FIG. 1, each support beam assembly 300 may include two main support beams 310 disposed in opposed spaced relation. That is, two main support beams 310 are provided between the two inner support frames 220. Each main support beam 310 extends in the lateral direction of the platform body 100 and both ends thereof are fixedly connected to two main stringers 110, respectively.

Wherein the two main support beams 310 are spaced apart from each other. Each main support beam 310 is spaced apart from the inner support frame 220 located at one side thereof.

In the present application, the support beam assembly 300 is mainly used to support and arrange the connection beam assembly 400 and the pair of movable support blocks 500. Illustratively, each primary support beam 310 of the support beam assembly 300 may also be used as a forklift beam for forklift lifting. For example, the primary support beams 310 may be U-shaped steel structures that may form fork pockets that mate with the forks of a forklift.

Referring to fig. 1, in the embodiment of the present application, each of the connection beam assemblies 400 is respectively connected between two adjacent fixed support frames 200 and fixedly connected with the support beam assembly 300. Each of the connection beam assemblies 400 extends in the longitudinal direction of the deck body 100 and is spaced apart from two of the main stringers 110, respectively.

Illustratively, as shown in FIG. 1, a tie beam assembly 400 is disposed between two inner support brackets 220. Specifically, the connection beam assembly 400 includes a first connection beam 440 and a second connection beam 450, the first connection beam 440 being disposed between the two main support beams 310. The second connection beams 450 are connected between each main support beam 310 and the inner support frame 220 at one side thereof corresponding to the first connection beams 440. More specifically, each connection beam assembly 400 includes one first connection beam 440 and two second connection beams 450.

In the present application, the connection beam assembly 400 is mainly used for slidably arranging the pair of movable supporting seats 500. Referring to fig. 1, each pair of movable supporting seats 500 is respectively disposed between two adjacent fixed supporting frames 200. The two movable supporting seats 500 of each pair of movable supporting seats 500 are respectively slidably connected with the connection beam assembly 400, so that the two movable supporting seats 500 of each pair of movable supporting seats 500 can be close to or far from each other.

For example, as shown in fig. 1, a pair of movable supporting seats 500 may be provided between the two inner supporting frames 220, and two movable supporting seats 500 of the pair of movable supporting seats 500 may be respectively slid along the connection beam assembly 400. Therefore, two movable supporting seats 500 of the pair of movable supporting seats 500 may be close to or far from each other. And the distance between each movable supporting seat 500 and the inner supporting frame 220 at one side thereof is also adjustable.

Specifically, as shown in fig. 4, two movable supporting seats 500 of the pair of movable supporting seats 500 may be close to each other, so that each movable supporting seat 500 of the pair of movable supporting seats 500 forms a second bearing groove 102 for bearing the coil stock with the inner supporting frame 220 of one side thereof, respectively. The movable supporting seat 500 can slide longitudinally, so that the distance between the movable supporting seat 500 and the inner supporting frame 220 at one side thereof can be adjusted, and the width of the second bearing groove 102 along the longitudinal direction can be adjusted. So that the second carrying groove 102 can be adapted to carry rolls of different radial dimensions.

Preferably, the second bearing groove 102 has a structure with a wide top and a narrow bottom, so as to be suitable for loading coils with different radial dimensions.

As shown in fig. 5, two movable supporting seats 500 of the pair of movable supporting seats 500 may be spaced apart from each other, so that a third bearing groove 103 for bearing the coil stock is formed between the pair of movable supporting seats 500. Wherein, since the movable supporting seat 500 can slide longitudinally, the distance between the two movable supporting seats 500 can be adjusted, so that the width of the third bearing groove 103 along the longitudinal direction can be adjusted. So that the third bearing recess 103 can be adapted to bear rolls of different radial dimensions.

Preferably, the third bearing groove 103 has a structure with a wide top and a narrow bottom, so as to be suitable for loading coils with different radial dimensions.

Referring to fig. 1,6 and 7, in one embodiment, the movable supporting seat 500 may be slidably connected to the connection beam assembly 400 by providing a connection chute 410 on the connection beam assembly 400, and the connection chute 410 extends along the longitudinal direction of the platform body 100. The movable supporting seat 500 is provided with a sliding connection portion 510 corresponding to the connection chute 410, and the sliding connection portion 510 is slidably connected with the connection chute 410.

As shown in fig. 8, in one embodiment, the movable support 500 includes a support base 520. The sliding connection 510 is disposed at the bottom of the support base 520. Specifically, the support base 520 includes a support bottom plate 521 and two support panels 522, and the two support panels 522 are respectively connected to both ends of the support bottom plate 521 in the longitudinal direction. Each support panel 522 is disposed obliquely with respect to the support base 521, and the side edges of the two support panels 522 remote from the support base 521 are connected to each other. In this embodiment, the support bottom plate 521 and the two support panels 522 may form a support base 520 with a substantially triangular cross section. Preferably, the support base 520 may have a cross section of an isosceles triangle. Specifically, the support bottom plate 521 forms the base of an isosceles triangle, and the two support panels 522 form the two waist sides of the isosceles triangle, respectively.

In the present application, the support base 520 is provided with an inclined support panel 522 and the inner support frame 220 is provided with an inclined support frame panel 223. A second load bearing recess 102 may be formed between the support panel 522 and the opposing support frame panel 223 that is wider at the top and narrower at the bottom.

The support base 520 is provided with inclined support panels 522, and a third bearing groove 103 with a wider upper part and a narrower lower part can be formed between the two opposite inclined support panels 522 of the two movable support seats 500 arranged in pairs.

In the present application, the two support panels 522 may be integrally formed, i.e., the two support panels 522 may be formed by bending an integral rectangular plate. In other embodiments, the two support panels 522 may also be two separate plates.

As shown in fig. 8, a flexible pad 540 may be provided on the surface of the support panel 522 for contact with the coil stock, and the flexible pad 540 and the support panel 522 may be fixed at the top. Wherein the flexible backing plates 540 on the two support panels 522 may be one integral piece capable of covering both support panels 522 at the same time on the surface in contact with the web 20. When the two support panels 522 are one piece and the flexible pad 540 thereon is one piece, the middle portion of the flexible pad 540 is secured to the top of the two support panels 522 of the one-piece structure by fasteners.

In the application, each flexible backing plate can deform and stretch downwards under the pressure of the coil stock. If the lower portion of the flexible mat is also fastened to the corresponding plate bodies, such as the end support plates 212, the support frame panels 223, and the support panels 522, by fasteners, the fastening points of the lower portion of the flexible mat are easily damaged by pulling and pressing. If the damage of the fastening point of the lower part of the flexible backing plate is avoided, the flexible backing plate can be adhered to the corresponding plate body and then fixedly connected through the fastening piece. Therefore, the flexible backing plate can be prevented from moving, and the fastening points at the lower part of the flexible backing plate are prevented from being damaged by pulling and extruding. However, the flexible backing plate is a wearing part, and the bonded flexible backing plate is difficult to replace. Only the upper part of the flexible backing plate is fixed, the flexible deformation of the flexible backing plate can be utilized to cope with the movement and the stretching of the flexible backing plate, and the damage of the lower part of the flexible backing plate caused by the rigid fixation is avoided. The rigid fixation of the lower part of the flexible backing plate is canceled, the damage possibly caused to coil materials by the fastener at the lower end can be avoided, the structure is simplified, the cost is reduced, and the replacement is convenient. The flexible backing plate can be made of rubber plate or rubber product. In the embodiment of the application, the flexible backing plate adopts an integrated rubber plate, and has simple structure and low cost.

Referring to fig. 7, the sliding connection part 510 includes a first connection piece 511 and a second connection piece 512, and the first connection piece 511 is fixedly connected with the support base 520 and can extend into the connection chute 410. Specifically, the first connector 511 may be fixedly coupled to the bottom surface of the support base 521. The second connecting piece 512 is detachably connected to the first connecting piece 511, and the second connecting piece 512 is used for preventing the first connecting piece 511 from being separated from the connecting chute 410. The first connecting member 511 may be a bolt, and the supporting base 521 may be provided with a hole penetrating the first connecting member 511. The second connector 512 may be a nut.

Referring to fig. 6 and 9, in one embodiment, the connection beam assembly 400 includes a connection plate 420 and two connection girders 430, the two connection girders 430 being disposed opposite to each other at a distance. The connection plate 420 is connected between the two connection girders 430, and the connection plate 420 and the two connection girders 430 can be enclosed to form the connection chute 410. The connection plate 420 is provided with an elongated hole 421 through which the first connection member 511 is inserted.

Referring to fig. 7, in the present embodiment, the first connecting member 511 is a bolt, one end of the bolt is fixedly connected to the supporting base 521, and the other end extends downward into the connecting chute 410 through the elongated hole 421. Wherein the diameter of the bolt is matched with the width of the elongated hole 421 so that the first connection member 511 can only slide along the length direction of the elongated hole 421. That is, the first connection member 511 cannot move in the width direction of the elongated hole 421, and thus the support base 520 can be restricted from moving in the lateral direction of the platform body 100.

The second connector 512 may be a nut that is screwed onto the bolt. The outer diameter of the nut is larger than the width of the elongated hole 421, so that the nut can prevent the bolt from coming out of the connecting chute 410, and the sliding connection between the sliding connection portion 510 and the connecting chute 410 is ensured, thereby also limiting the movement of the support base 520 in the height direction of the platform body 100. When the sliding connection 510 is assembled, the upper surface of the nut and the lower surface of the connection plate 420 may be provided with a gap, so that the sliding connection 510 has a movable amount of longitudinal movement, thereby facilitating the longitudinal movement of the support base 520. Wherein the support base 520 moves in the longitudinal direction on the connection beam assembly 400, the bolt moves in the elongated hole 421, and the nut moves in the connection chute 410.

Wherein the second connector 512 may employ double nuts or other conventional means of preventing the nuts from loosening and adding corresponding parts. In an embodiment not shown, the sliding connection 510 may also be formed by other manners, such as a pin for the first connector 511 and a pin for the second connector 512, where the pin is perpendicular to the pin and is connected to the bottom end of the pin. Or the first connecting piece 511 is a connecting rod, and the second connecting piece 512 is a screw, and the screw is connected to the bottom end of the connecting rod. In short, the second connecting member 512 and the first connecting member 511 may be detachably connected. The second connection member 512 is detachably connected to the first connection member 511, so that the installation, maintenance and replacement of the support base 520 can be facilitated.

In the embodiment of the present application, the sliding connection of the support base 520 and the connection beam assembly 400 is achieved by the sliding connection of the sliding connection portion 510 and the connection chute 410. The movement of the support base 520 in the lateral and height directions of the platform body 100 can be restricted by sliding the slide connection 510 with the connection chute 410.

Referring to fig. 6, 7 and 9, in one embodiment, the upper surface of the connection girder 430 is a surface in sliding contact with the movable supporting seat 500, and the upper surface of the connection plate 420 is flush with the upper surface of the connection girder 430. The lower surface of the connection girder 430 protrudes downward from the connection plate 420 such that the notch of the connection chute 410 is downward. In this embodiment, when the support base 520 moves longitudinally on the connection beam assembly 400, the first connecting member 511 is inserted into the elongated hole 421 and moves longitudinally along the elongated hole 421, and the second connecting member 512 moves longitudinally in the connection chute 410. Preferably, the sliding connection portion 510 does not entirely exceed the lower surface of the connecting main beam 430, i.e., the second connecting member 512 is completely accommodated in the connecting chute 410. Thus, the sliding connection 510 is prevented from contacting the ground or the ground foreign matter before the connection girder 430, and the sliding connection 510 is prevented from being damaged by collision.

Referring to fig. 6 and 7, in one embodiment, a connection chute 410 is provided on each of the first connection beam 440 and the second connection beam 450. The number of the sliding connection parts 510 provided on the support base 520 is two. The two sliding connection parts 510 are slidably connected with the connection sliding grooves 410 on the first connection beam 440 and the connection sliding grooves 410 on the second connection beam 450, respectively. The first and second connection beams 440 and 450 may each be a structure including a connection plate 420 and two connection main beams 430. The first and second connection beams 440 and 450 may each be provided with a connection chute 410 with a downward slot.

Since the first connection beam 440 is located between the two main support beams 310, the second connection beam 450 is located between the main support beams 310 and the inner support frame 220 at one side thereof. Accordingly, the connection runner 410 of the first connection beam 440 and the connection runner 410 of the second connection beam 450 are located at both sides of the same main support beam 310, respectively. The two sliding connection parts 510 are disposed on the support base 520 at a longitudinal interval, and the two sliding connection parts 510 can be respectively slidably connected with the two connection sliding grooves 410 on both sides of the main support beam 310, so that the horizontal rotation of the support base 520 on the connection beam assembly 400 can be limited, and the support base 520 can be ensured to move only in the longitudinal direction.

Referring to fig. 8, in one embodiment, the support base 520 further includes a support web 523, the support web 523 being vertically connected between the support floor 521 and the two support panels 522. Wherein, each support base 520 may be provided with two support webs 523, the two support webs 523 being disposed in parallel and spaced apart relation between the support bottom plate 521 and the two support panels 522. In this embodiment, the two support webs 523 can better support the support panel 522, and improve the support strength of the support base 520.

When the first connection piece 511 is connected to the support base 521, the upper end of the first connection piece 511 can be closed between two support webs 523, see in particular fig. 7. Therefore, since the upper end of the first connecting piece 511 is sealed between the two supporting webs 523, the second connecting piece 512 is protected by the connecting chute 410 with the downward slot opening, and if the coil loading platform 10 is lifted up integrally without lifting equipment, the sliding connecting portion 510 is not easy to be disassembled, so that the movable supporting seat 500 can be effectively prevented from being stolen.

Referring to fig. 8, in one embodiment, the movable supporting base 500 includes a connection fixing member 530, and the connection fixing member 530 is used to fixedly connect two supporting bases 520. The connection fixing member 530 and each support base 520 connected thereto can constitute a movable support base 500 including a plurality of support bases 520, and the plurality of support bases 520 in the movable support base 500 are disposed at intervals in the lateral direction of the platform body 100.

For example, as shown in fig. 1, each movable supporting seat 500 may include two supporting bases 520, and the two supporting bases 520 are spaced apart along the lateral direction of the platform body 100. The two support bases 520 are connected to each other by a connection fixture 530. Illustratively, the connection fixtures 530 may be connected with a support web 523 of the support base 520.

The two support bases 520 are connected through the connecting fixing piece 530, so that the two support bases 520 are connected into the integral movable support base 500, the strength and stability of the movable support base 500 for supporting the coil stock can be improved, and the movable support base 500 is convenient to move and operate.

As shown in fig. 1, a connection beam assembly 400 is disposed between two adjacent fixed supporting frames 200 corresponding to each supporting base 520, and the supporting base 520 is slidably connected to the connection beam assembly 400. Specifically, when each movable supporting seat 500 between two inner supporting frames 220 includes two supporting bases 520, the number of connecting beam assemblies 400 disposed between two inner supporting frames 220 is two. The two support bases 520 of each movable support 500 are slidably coupled to the two connection beam assemblies 400 in a one-to-one correspondence.

In this embodiment, the movable supporting seat 500 is made by adopting two supporting bases 520 and connecting them by using a connecting fixing member 530. The movable supporting seat 500 may have sufficient supporting strength and supporting surface width, and is advantageous in saving materials, reducing weight, and facilitating the longitudinal movement of the supporting base 520.

It will be appreciated that in an embodiment not shown, each movable support 500 may also include only one support base 520. For example, the movable supporting base 500 may be provided with a supporting base having a large lateral width, and the width of the supporting base may be the length of the entire structure in which the two supporting bases 520 are connected by the connection fixing member 530 as shown in fig. 8. Although the processing can be simple, the material consumption is more, the weight is heavy, the cost is high, and the movement is more laborious.

Referring to fig. 1 and 9, in one embodiment, the coil loading platform 10 further includes a limiting assembly 600, the limiting assembly 600 is disposed on the connection beam assembly 400, and the limiting assembly 600 is used to limit the sliding range of each movable supporting seat 500 relative to the connection beam assembly 400. Specifically, the limit assembly 600 includes a first limit stop 610, and the first limit stop 610 is disposed on an upper surface of the connection beam assembly 400. Specifically, the first limit stop 610 may be disposed on the upper surface of the first connection beam 440 between the two main support beams 310. The first limit stop 610 is located between two movable supporting seats 500 of each pair of movable supporting seats 500. Thus, the first limit stop 610 can abut against two movable supporting seats 500 of each pair of movable supporting seats 500 to define a limit position where the two movable supporting seats 500 of each pair of movable supporting seats 500 are close to each other.

The limit assembly 600 further includes a second limit stop 620, the second limit stop 620 being disposed on an upper surface of the connecting beam assembly 400. In particular, the second limit stop 620 may be disposed on the upper surface of the second connection beam 450 between the main support beam 310 and the inner support frame 220. The second limit stop 620 is located between each movable supporting seat 500 of each pair of movable supporting seats 500 and the inner supporting frame 220 at one side thereof. Therefore, the second limit stop 620 can respectively abut against each movable supporting seat 500 of each pair of movable supporting seats 500 to define a limit position where the two movable supporting seats 500 of each pair of movable supporting seats 500 are away from each other.

Wherein the first limit stop 610 may be welded to the upper surface of the first connection beam 440. The second limit stop 620 may be welded to the upper surface of the second connection beam 450.

When the two movable supporting seats 500 are located at the positions far away from each other, the second limit stop 620 can abut against the supporting bottom plate 521 of the movable supporting seat 500 to resist the horizontal component force generated by the pressure of the coil 20 placed between the two movable supporting seats 500 on the movable supporting seat 500, and when the two movable supporting seats 500 are located at the positions near each other, the first limit stop 610 can abut against the supporting bottom plate 521 of the movable supporting seat 500 to resist the horizontal component force generated by the pressure of the coil 20 placed between the inner supporting frame 220 and the movable supporting seat 500 on the movable supporting seat 500.

In an embodiment not shown, the stop assembly 600 may be eliminated if the force of the movable support 500 is not great. For example, the end of the elongated hole 421 abuts against the first connector 511 to limit and bear the force of the movable supporting seat 500.

The coil stock loading platform 10 of the embodiment of the application, when in use:

As shown in fig. 4, two first bearing grooves 101 may be formed between the two end supporting frames 210 and the inner supporting frame 220 at one side thereof, respectively. The two movable supporting seats 500 are moved in the direction approaching each other, so that the first limit stop 610 abuts against the two movable supporting seats 500. At this time, two second bearing grooves 102 may be formed between the two movable supporting seats 500 and the inner supporting frame 220 at one side thereof, respectively. Thus, the coil loading platform 10 can load 4 coils, and the 4 coils are respectively positioned in the two first bearing grooves 101 and the two second bearing grooves 102.

As shown in fig. 5, two first bearing grooves 101 may be formed between the two end supporting frames 210 and the inner supporting frame 220 at one side thereof, respectively. The two movable supporting seats 500 are moved in a direction away from each other, so that the two second limit stops 620 respectively abut against the two movable supporting seats 500. At this time, a third bearing groove 103 is formed between the two movable supporting seats 500. Thus, the coil loading platform 10 can load 3 coils, and the 3 coils are respectively located in the two first bearing grooves 101 and one third bearing groove 103.

When the coil loading platform 10 loads 2 coils, the 2 coils may be respectively located in the two first bearing grooves 101. Therefore, the coil loading platform 10 according to the embodiment of the present application can selectively load 2, 3 or 4 coils according to the diameter and weight of the coil 20, and has a wide range of applicable coil specifications and flexible loading.

The coil loading platform 10 according to the embodiment of the present application is provided with a pair of movable supporting seats 500, and each movable supporting seat 500 can slide longitudinally along the platform body 100. Therefore, the width of the interval between the two movable supporting seats 500 is adjustable, and the width of the interval between each movable supporting seat 500 and the adjacent fixed supporting frame 200 is also adjustable. Thereby the coil stock loading platform 10 can realize the loading to different diameter coil stocks 20 and load different quantity of coil stocks 20 as required, and its applicable coil stock specification scope is wide, and the loading is more nimble.

The coil loading platform 10 according to the embodiment of the present application supports the movable supporting seat 500 provided in the pair by providing the supporting beam assembly 300 and the connecting beam assembly 400, so that the movable supporting seat 500 can be designed to have a lighter structure and a more convenient movement structure. And the stress of the movable supporting seat 500 for bearing the coil stock 20 can be borne by the supporting beam assembly 300, the connecting beam assembly 400 and the fixed supporting frame 200 together, so that the bearing capacity of the movable supporting seat 500 is improved, and the capability of the coil stock loading platform 10 for resisting railway rolling impact is ensured. In other words, the coil loading platform 10 of the present application can realize the support limiting function of the movable supporting seat 500 with less material by means of the overall strength of the supporting beam assembly 300, the connecting beam assembly 400 and the fixed supporting frame 200, thereby being beneficial to reducing the cost.

In the coil loading platform 10 according to the embodiment of the present application, the movable supporting seat 500 is designed to have a structure including two supporting bases 520 and connected by the connecting fixing member 530, so that the weight of the movable supporting seat 500 is reduced to the greatest extent on the premise of ensuring the overall strength and stability, the cost is reduced, and the weight is lighter than that of the moving operation.

Referring to fig. 1, a coil loading platform 10 according to an embodiment of the present application may be used as a special container for transporting coils. Wherein, top corner pieces 130 may be disposed at the top of four corners of the platform body 100, and bottom corner pieces 140 may be disposed at the bottom of four corners of the platform body 100. The top corner piece 130 may be a raised structure. The bottom corner piece 140 may be a groove structure. Stacking of a plurality of special containers up and down can be achieved by the male-female engagement of the top corner piece 130 with the bottom corner piece 140.

The top of the four corners of the platform body 100 may further be provided with a flip twist lock 150, and the flip twist lock 150 may be detachably connected with the top corner piece 130. Wherein the flip twist lock 150 may be used for detachable fixed connection between two adjacent special containers. Illustratively, the flip twistlock 150 has an upper lock head and a lower lock head, and when the flip twistlock 150 is located at the connection position, the lower lock head is fixedly connected with the top hole of the top corner element 130, and at this time, the upper lock head is inserted into the bottom hole of the bottom corner element 140 of another special container and is fixedly connected, so that the stacked special containers can be fixedly connected. When the flip twistlock 150 is in the open position, the top aperture of the top corner element 130 may be used for crane operations, which may hoist a special container or a stack of special containers.

The bottom corner fitting 140 may also be used for a fixed connection between a special container and a container transport vehicle. For example, the bottom corner piece 140 may be adapted to be fixedly connected to a twist lock of a railroad car or to a twist lock of a container truck. The top corner piece 130 and the bottom corner piece 140 of the special container of the present application are the same in position, size and function as standard containers. Correspondingly, the length and width outer dimensions of the special container are the same as those of the standard container, so that the special container is suitable for intermodal transportation of railways and highways.

Referring to fig. 1, a rope loop 160 and a rope hook 170 may be provided around the platform body 100. The cord loop 160 may be used for tethering to a transport vehicle without a twist lock. The rope hook 170 may be used for fastening tarpaulin.

Vertical baffle mounting holes 180 can be further formed around the platform body 100, and upright posts can be inserted into the vertical baffle mounting holes 180, so that the coil loading platform 10 can be suitable for loading long-strip-shaped cargoes such as wood and steel. For example, after the coil is transported, the upright posts are inserted into the vertical baffle mounting holes 180 around during the return, so that long-bar-shaped cargoes such as wood and steel can be loaded on the platform body 100 along the length direction of the platform body 100, and the upright posts can play a role in supporting and reinforcing the cargoes.

The coil loading platform 10 of the embodiment of the application can realize the intermodal transportation of railways and highways through standard upper and lower corner fitting arrangement. When the coil stock loading platform 10 is applied to special containers, the special containers can be widely applied to coil stock specifications and are flexible to load. And the special container is convenient and labor-saving to adjust, reasonable in structure, light in weight and high in strength, can be lifted, and is safe and reliable.

The above embodiments are merely illustrative of structures, and the structures in the embodiments are not fixedly matched and combined structures, and in the case of no structural conflict, the structures in the embodiments can be arbitrarily combined for use.

While the utility model has been described with reference to several exemplary embodiments, it is to be understood that the terminology used is intended to be in the nature of words of description and of limitation. As the present utility model may be embodied in several forms without departing from the spirit or essential characteristics thereof, it should also be understood that the above-described embodiments are not limited by any of the details of the foregoing description, but rather should be construed broadly within its spirit and scope as defined in the appended claims, and therefore all changes and modifications that fall within the meets and bounds of the claims, or equivalences of such meets and bounds are therefore intended to be embraced by the appended claims.

Claims (13)

1. A coil loading platform, comprising: The platform body includes two main longitudinal beams arranged in parallel and spaced apart; A plurality of fixed support frames, wherein the plurality of fixed support frames are arranged at intervals along the longitudinal direction of the platform body; at least one support beam assembly, each of the support beam assemblies being disposed between two adjacent fixed support frames, each support beam assembly being spaced apart from the fixed support frames on both sides thereof, the support beam assembly extending transversely along the platform body and having two ends thereof fixedly connected to the two main longitudinal beams; at least one connecting beam assembly, each connecting beam assembly being connected between two adjacent fixed support frames and fixedly connected to the support beam assembly, each connecting beam assembly extending longitudinally of the platform body and spaced apart from the two main longitudinal beams; At least one pair of movable support seats, each pair of movable support seats is respectively arranged between two adjacent fixed support frames, and the two movable support seats in each pair of movable support seats are respectively slidably connected to each connecting beam assembly, so that the two movable support seats in each pair of movable support seats can move closer to or farther away from each other. 2. The coil material loading platform according to claim 1 is characterized in that a connecting groove is provided on the connecting beam assembly, the connecting groove extends along the longitudinal direction of the platform body, the movable support seat is provided with a sliding connection part corresponding to the connecting groove, and the sliding connection part is slidably connected to the connecting groove. 3. The coil loading platform according to claim 2 is characterized in that the movable support seat includes a support base, the sliding connection part includes a first connecting member and a second connecting member, the first connecting member is fixedly connected to the support base and can extend into the connecting slide groove, the second connecting member is detachably connected to the first connecting member, and the second connecting member is used to prevent the first connecting member from falling out of the connecting slide groove. 4. The coil material loading platform according to claim 3 is characterized in that the connecting beam assembly includes a connecting plate and two connecting main beams, the two connecting main beams are arranged relatively spaced apart, the connecting plate is connected between the two connecting main beams, the connecting plate and the two connecting main beams can be enclosed to form the connecting slide groove, and the connecting plate is provided with a long strip hole for the first connecting member to pass through. 5. The coil material loading platform according to claim 4 is characterized in that the upper surface of the connecting main beam is the surface in sliding contact with the movable support seat, the upper surface of the connecting plate is flush with the upper surface of the connecting main beam, and the lower surface of the connecting main beam protrudes downward from the connecting plate, so that the notch of the connecting slide is downward. 6. The coil material loading platform according to claim 3 is characterized in that the support base includes a support bottom plate and two support panels, the two support panels are respectively connected to the two ends of the support bottom plate in the longitudinal direction, each support panel is respectively inclined relative to the support bottom plate, and the two support panels are connected to each other away from the side of the support bottom plate. 7 . The coil loading platform according to claim 6 , wherein the support base further comprises a support web, and the support web is vertically connected between the support bottom plate and the two support panels. 8. The coil loading platform according to claim 3, wherein the movable support base comprises a connecting fixture, and the connecting fixture is used to fixedly connect the two support bases; The connecting fixing member and the supporting bases connected thereto can form a movable supporting base comprising a plurality of supporting bases, wherein the plurality of supporting bases in the movable supporting base are arranged at intervals along the lateral direction of the platform body; One connecting beam assembly is arranged between two adjacent fixed support frames corresponding to each supporting base, and the supporting base is slidably connected to the connecting beam assembly. 9. The coil loading platform according to claim 3, wherein each of the support beam assemblies comprises two main support beams spaced apart from each other; Each of the connecting beam assemblies comprises a first connecting beam and a second connecting beam, wherein the first connecting beam is arranged between the two main support beams, and the second connecting beam is connected between the main support beam and the fixed support frame located on one side thereof corresponding to the first connecting beam; The connecting groove is provided on both the first connecting beam and the second connecting beam, and the number of the sliding connecting parts provided on the support base is two, and the two sliding connecting parts are respectively slidably connected to the connecting groove on the first connecting beam and the connecting groove on the second connecting beam. 10. The coil loading platform according to any one of claims 1 to 9 is characterized in that it also includes a limit assembly, wherein the limit assembly is arranged on the connecting beam assembly, and the limit assembly is used to limit the sliding range of each movable support seat relative to the connecting beam assembly. 11. The coil material loading platform according to claim 10, characterized in that the limit assembly comprises a first limit stopper and a second limit stopper, the first limit stopper being arranged on the upper surface of the connecting beam assembly and being located between the two movable support seats in each pair of the movable support seats, the first limit stopper being able to abut against the two movable support seats in each pair of the movable support seats to limit the extreme position at which the two movable support seats in each pair of the movable support seats approach each other; The second limit stop is arranged on the upper surface of the connecting beam assembly and is located between each movable support seat in each pair of movable support seats and the fixed support frame on one side thereof. The second limit stop can abut against each movable support seat in each pair of movable support seats respectively to limit the extreme positions of the two movable support seats in each pair of movable support seats away from each other. 12. The coil loading platform according to any one of claims 1 to 9, characterized in that the number of the fixed support frames is four, and the four fixed support frames are respectively two end support frames and two internal support frames, the two end support frames are respectively arranged at the longitudinal ends of the platform body, and the two internal support frames are arranged between the two end support frames, and the internal support frame and the end support frame on one side thereof form a first bearing groove for bearing the coil; The support beam assembly is arranged between the two internal support frames, and a pair of movable support seats are slidably arranged on the connecting beam assembly between the two internal support frames. 13. The coil loading platform according to claim 12, wherein two movable support seats in a pair of movable support seats can be close to each other, so that each movable support seat of the pair of movable support seats forms a second bearing groove for bearing the coil with the internal support frame on one side thereof; Two movable support seats in a pair of movable support seats can be spaced apart from each other, so that a third bearing groove for bearing the coil is formed between the pair of movable support seats.