BR112020014703A2 - support set and rail beam that has the same - Google Patents

Abstract

A set of support is revealed (100) and a rail beam (200) that has a support assembly (100). O support set (100) comprises an upper support plate (41); one lower support plate (42) located below the support plate superior (41); a support plate (43), with an upper surface which is in contact with and cooperates with the upper support plate (41) and a bottom surface that is in contact and cooperates with the backing plate lower (42); an upper traction seat (51) connected securely to the lower support plate (42); a lower drive seat (52) connected fixed to the upper support plate (41); and a drive block (53), with an upper surface that is in contact and cooperates with the headquarters of upper traction (51) and a lower surface that is in contact and cooperates with the lower traction seat (52). The upper support plate (41) and the lower support plate (42) can move one with respect to the another in a longitudinal direction and rotate relative to each other in a longitudinal vertical plane.

Description

“ASSEMBLY OF SUPPORT AND RAIL BEAM THAT HAS THE SAME” CROSS REFERENCE TO RELATED REQUESTS

[0001] This application is proposed on the basis of and claims the priority of Patent Application No. CN 201810069594.X filed on January 24, 2018. The full content of the application referenced above is incorporated into this document for reference.

FIELD

[0002] This order belongs to the field of rail transit and, in particular, refers to a support set and a rail beam that has the same.

BACKGROUND

[0003] In the related technique, most rail beams adopt an articulated support. A contact area between a pivot shaft and a pressure support plate is relatively small and the contact voltage is relatively large, limiting the general support capacity of the support. In addition, support has a relatively heavy volume, which increases costs.

SUMMARY

[0004] For the above technical problems, this order provides a rail beam support set. The support set has a relatively large pressure support area, which considerably improves the overall support capacity of the support set and reduces the volume and costs of manufacturing and assembling the support set.

[0005] The technical solutions specific to this application are as follows.

[0006] A rail beam support set, which includes: an upper support plate; a lower support plate located below the upper support plate; a support plate, an upper surface of the support plate being in contact and fitting the upper support plate and a lower surface of the support plate being in contact and fitting the lower support plate; an upper traction seat fixedly connected to the lower support plate; a lower traction seat fixedly connected to the upper support plate; and a traction block, an upper surface of the traction block being in contact and fitting the upper traction seat and a lower surface of the traction block being in contact and fitting the lower traction seat; wherein the upper support plate and the lower support plate are able to move relative to each other longitudinally and to rotate relative to each other in a vertical longitudinal plane.

[0007] The upper support plate is in contact and fits the upper surface of the support plate and the lower surface of the support plate is in contact and fits the lower support plate, so that there is a relatively large contact area between the upper support plate and the lower support plate, considerably improving the general support capacity of the support set and reducing the volume and costs of manufacturing and assembling the support set. In addition, the upper support plate and the lower support plate can move relative to each other longitudinally and rotate relative to each other in a vertical longitudinal plane to adapt to the flexural deformation and telescopic deformation of the rail beam .

[0008] The upper traction seat is fixedly connected to the lower support plate and is in contact and fits the upper surface of the traction block. The lower traction seat is fixedly connected to the upper support plate and is in contact and fits the lower surface of the traction block. In this way, the upper support plate and the lower support plate are prevented from moving with respect to each other vertically and rotating with respect to each other in a lateral vertical plane, improving the traction capacity and the lateral stability of the set of support.

[0009] In addition, the support set in this application may additionally have the following additional technical resources.

[0010] In some examples of this application, the upper surface of the support plate is a sliding surface and the lower surface of the support plate is a rotating surface; a lower surface of the upper support plate includes a sliding surface; and an upper surface of the lower support plate includes a rotating surface, the sliding surface of the upper support plate is in contact and engages the sliding surface of the support plate, and the rotating surface of the lower support plate is in contact, and fits the rotating surface of the support plate; or the upper surface of the support plate is a rotating surface and the lower surface of the support plate is a sliding surface; the lower surface of the upper support plate includes a rotating surface; and the upper surface of the lower support plate includes a sliding surface, where the rotating surface of the upper support plate is in contact and engages the rotating surface of the support plate and the sliding surface of the lower support plate is in contact and engages the sliding surface of the support plate.

[0011] The rotating surface of the support plate is in contact and fits the rotating surface of the upper support plate or the lower support plate, so that the upper support plate and the lower support plate can rotate one in relation to the another in a vertical longitudinal plane. The sliding surface of the support plate is in contact and engages the sliding surface of the upper support plate or the lower support plate, so that the upper support plate and the lower support plate can move longitudinally in relation to each other .

[0012] In some examples of this application, the rotating surface of the support plate is a spherical surface and the sliding surface of the support plate is a flat surface. The spherical rotating surface of the support plate is in contact and fits the upper support plate or the lower support plate, so that the upper support plate and the lower support plate can rotate relative to each other in a vertical plane longitudinal. The flat sliding surface of the support plate is in contact and engages the upper support plate or the lower support plate, so that the upper support plate and the lower support plate can move longitudinally in relation to each other.

[0013] In some examples of this application, an axis of rotation of the rotating surface of the support plate and an axis of rotation of the rotating surface of the drive block are collinear; the upper surface of the drive block is a rotating surface and the lower surface of the drive block is a sliding surface; a lower surface of the upper traction seat includes a rotating surface; and an upper surface of the lower traction seat includes a sliding surface, the rotating surface of the upper traction seat is in contact and engages the rotating surface of the traction block and the sliding surface of the lower traction seat is in contact and engages the surface traction block slider; or the upper surface of the drive block is a sliding surface and the lower surface of the drive block is a rotating surface; the lower surface of the upper traction seat includes a sliding surface; and the upper surface of the lower drive seat includes a rotating surface, the sliding surface of the upper drive seat is in contact and engages the sliding surface of the drive block and the rotating surface of the lower drive seat is in contact and engages the surface rotation of the traction block.

[0014] The axis of rotation of the rotating surface of the support plate is collinear with the axis of rotation of the rotating surface of the traction block, avoiding interference between the upper traction seat and the lower traction seat during the relative rotation of the support plate upper and lower support plate in the longitudinal vertical plane. The rotating surface of the drive block is in contact and fits the rotating surface of the upper drive seat or the lower drive seat, so that the upper drive seat and the lower drive seat can help the upper support plate and the lower support plate to rotate in relation to each other in the longitudinal vertical plane. The sliding surface of the drive block is in contact and fits the sliding surface of the upper traction seat or the lower traction seat, so that the upper traction seat and the lower traction seat can help the upper support plate and the lower support plate to move relative to each other longitudinally.

[0015] In some examples of this application, the rotating surface of the drive block is a cylindrical surface and the sliding surface of the drive block is a flat surface. The cylindrical rotating surface of the drive block is in contact and fits the upper drive seat or the lower drive seat, so that the upper drive seat and the lower drive seat can help the upper support plate and plate lower support to rotate in relation to each other in the longitudinal vertical plane. The flat sliding surface of the drive block is in contact and fits the upper support plate or the lower support plate, so that the upper traction seat and the lower traction seat can help the upper support plate and the lower support to move one in relation to the other longitudinally.

[0016] In some examples of this application, the upper traction seat includes a first upper traction seat and a second upper traction seat; the first upper traction seat being fixedly connected to a left end of the lower support plate and the second upper traction seat being fixedly connected to a right end of the lower supporting plate; the lower traction seat includes a first lower traction seat and a second lower traction seat, the first lower traction seat is fixedly connected to a left end of the upper support plate and the second lower traction seat is fixedly connected to a right end of the upper support plate; and the traction block includes a first traction block and a second traction block, in which an upper surface of the first traction block is in contact and fits the first upper traction seat and a lower surface of the first traction block is in contact. contact and engages the first lower traction seat and an upper surface of the second traction block is in contact and engages the second upper traction seat and a lower surface of the second traction block is in contact and engages the second lower traction seat. The upper left and right traction seats, traction blocks and lower traction seats are in contact and fit together, so that the traction capacity and the lateral stability of the support set are considerably improved.

[0017] In some examples of this application, the support set additionally includes a first sliding plate, a second sliding plate, a third sliding plate and a fourth sliding plate, the upper support plate being in contact and fitting the support through the first sliding plate; the lower support plate is in contact and fits the support plate through the second sliding plate; the upper traction seat is in contact and fits the traction block through the third sliding plate; and the lower traction seat is in contact and fits the traction block through the fourth sliding plate. The first sliding plate, the second sliding plate, the third sliding plate and the fourth sliding plate facilitate the relative movement between the upper support plate and the lower support plate and have a vertical damping effect.

[0018] In some examples of this application, there are at least two support plates, an upper surface of each of the support plates is in contact and fits the upper support plate, a lower surface of each of the support plates is in contact and fits the bottom support plate and the at least two support plates are arranged laterally. The lateral arrangement of at least two support plates considerably improves the lateral stability of the support assembly.

[0019] In some examples of this application, at least two support projections are additionally arranged on the lower surface of the upper support plate, a lower surface of each of the support projections is in contact and fits an upper surface of one of the support plates supports. The upper support plate is in contact and fits the support plate through the support protrusion, facilitating the processing of a contact surface and reducing processing costs.

[0020] In some examples of this application, a shear projection is additionally arranged on the upper surface of the lower support plate, a lateral surface of the shear projection is in contact and engages a lateral surface of the support projection. The shear protrusion is configured to perform lateral positioning to mount the upper support plate and provide a shear function for the support assembly.

[0021] In some examples of this application, the support set additionally includes a fifth sliding plate, the fifth sliding plate being a flat plate and the side surface of the support projection is in contact and fits the side surface of the shear projection through the fifth sliding plate. The fifth sliding plate facilitates the relative longitudinal movement between the upper support plate and the lower support plate and has a lateral damping effect.

[0022] In some examples of this application, the support set additionally includes a base plate; the base plate being located below the lower support plate and connected to the lower support plate with the use of an anchor screw. The base plate is adapted to be pre-inserted into the rail beam to provide a mounting base for the bottom support plate.

[0023] In some examples of this order, the support set additionally includes a concrete insulation box; the concrete insulation box is mounted on a lower surface of the base plate and located below the anchor bolt. The concrete insulation box is configured to insulate the concrete and is adapted to provide a mounting space for the anchor bolt when dumping a beam.

[0024] In some examples of this order, the support set additionally includes a steel anchor bar mounting base, the steel anchor bar mounting base being located below the base plate and fixedly attached to the plate base, and the steel anchor bar mounting base is provided with a threaded hole, in which the threaded hole is adapted to be in a threaded connection to a steel anchor bar. The base plate is connected to the steel anchor bar via the steel anchor bar mounting base, and the steel anchor bar mounting base withstands tension during work, improving the traction capacity of the support.

[0025] In some examples of this application, the support set additionally includes a shear bar, the shear bar being a strip-like structure, located below the base plate and fixedly connected to the base plate. The shear bar is located below the base plate, improving the shear capacity of the base plate, thus improving the shear capacity of the support assembly.

[0026] In some examples of this application, the support set additionally includes two longitudinal adjustment devices arranged respectively on a front side and a rear side of the lower support plate, the longitudinal adjustment device including an adjustment plate and a adjustment screw, where the adjustment plate is fixedly connected to the base plate and one end of the adjustment screw is in contact and fits the lower support plate. A position of the adjusting screw is adjusted to fit and fix a longitudinal mounting position of the lower support plate.

[0027] In some examples of this application, the support assembly additionally includes a shear pin, the shear pin being located above the base plate and fixedly connected to the base plate, and a side surface of the shear pin is in contact and fits the lower support plate and is configured to position the lower support plate laterally and longitudinally in relation to the base plate. Through the insertion of the shear pin and the lower support plate, the shear capacity of the lower support plate is improved, thus improving the shear capacity of the support assembly.

[0028] This order additionally provides a rail beam, which includes: the support set provided in this order. According to the support set provided in this order, one end of the rail beam has a relatively large pressure support area, considerably improving the overall support capacity of the rail beam and reducing the volume of the support set and the costs of manufacture and assembly of the rail beam.

[0029] Other aspects and advantages of this application will be presented in the description below, some of which will be evident from the description below or can be learned from the practices of this application.

BRIEF DESCRIPTION OF THE DRAWINGS

[0030] Figure 1 is a schematic diagram of a rail beam support in the related technique;

[0031] Figure 2 is a schematic diagram of a rail beam support set, according to one embodiment of this order;

[0032] Figure 3 is a schematic diagram of a lower support plate and a base plate in a rail beam support set, according to one embodiment of this order;

[0033] Figure 4 is a partial cross-sectional view of a rail beam support assembly, according to one embodiment of this order;

[0034] Figure 5 is a schematic diagram of a base plate in a rail beam support set, according to one embodiment of this order;

[0035] Figure 6 is a bottom view of a base plate on a rail beam support assembly, according to one embodiment of this order;

[0036] Figure 7 is a schematic diagram of a lower support plate in a rail beam support set, according to one embodiment of this order;

[0037] Figure 8 is a schematic diagram of a bottom support plate and a base plate in a rail beam support set, according to another modality of this order;

[0038] Figure 9 is a schematic diagram of a base plate in a rail beam support set, according to another modality of this order; and

[0039] Figure 10 is a schematic diagram of a rail beam, according to one embodiment of this order.

REFERENCE NUMBERS 10 ’: Member of the balance sheet; 11 ’: Upper balance; 12 ’: Lower balance; 13 ': axis of the joint; 2 ': Base plate; 21 ’: Anchor bolt; 3 ': anchor steel bar; 200: Rail beam; 100: Support set; 2: Base plate; 21: Anchor bolt; 22: Concrete insulation box; 23: Mounting base of the steel anchor bar; 24: Shear bar; 25: Longitudinal adjustment device; 251: Adjustment plate; 252: Adjustment screw; 26: Shear pin; 261; Wedge block; 3: Anchor steel bar; 41: Upper support plate; 411: Support overhang; 42: Lower support plate; 421: Shear overhang; 422: Shear pin opening; 43: Support plate; 51: Upper traction seat; 511: First seat of upper traction;

512: Second upper traction seat; 52: Lower traction seat; 521: First lower traction seat; 522: Second lower traction seat; 53: Traction block; 531: First traction block; 532: Second traction block; 61: First sliding plate; 62: Second sliding plate; 63: Third sliding plate; 64: Fourth sliding plate; 65: Fifth sliding plate.

DETAILED DESCRIPTION

[0040] In order to make the technical problems solved by this application, technical solutions and advantageous effects clearer and more understandable, the following application is described in further details, with reference to the attached drawings and modalities. It should be understood that the specific modalities described in this document are used merely to explain this request, and are not intended to limit this request.

[0041] Details of this request are described in detail below. Examples of the modalities are shown in the accompanying drawings, and the same or similar reference signs in all the attached drawings indicate the same or similar components or components that have the same or similar functions. The modalities that are described with reference to the accompanying drawings are exemplary and are used only to interpret this request, instead of limiting it.

[0042] In describing this application, it should be understood that the orientation or position relations indicated by terms such as "center", "longitudinal", "lateral", "vertical", "length", "width", "above", “Below”, “front”, “rear”, “left”, “right”, “vertical”, “horizontal”, “upper”, “lower”, “internal” and “external” are based on orientation relationships or position shown in the accompanying drawings, and are used only for ease and brevity of illustration and description, instead of indicating or implying that the mentioned device or component necessarily has a specific orientation, that is, necessarily constructed and operated in a specific orientation. Therefore, such terms should not be construed as limiting this request. The direction of the x axis is lateral, the positive direction of the x axis is on the right and the negative direction of the x axis is on the left; the direction of the y axis is longitudinal, the positive direction of the y axis is forward and the negative direction of the y axis is backward; the direction of the z axis is vertical, the positive direction of the z axis is up and the negative direction of the z axis is down; and the xOy plane is the horizontal plane, the yOz plane is the longitudinal vertical plane and the xOz plane is the lateral vertical plane. In addition, a resource defined as "first" or "second" may explicitly or implicitly include one or more resources. In the description of this application, unless otherwise specified, "a plurality of" means two or more than two.

[0043] In the description of this application, it should be noted that, unless specified or explicitly defined otherwise, terms such as "assemble", "install", "connect" and "connection" must be understood in a broad sense. For example, the connection can be a fixed connection, a detachable connection or an integral connection; or the connection can be a mechanical or electrical connection; or the connection can be a direct connection, an indirect connection through an intermediary, or internal communication between two components. Persons of ordinary skill in the art may understand specific meanings of the terms mentioned in this application in accordance with specific situations.

[0044] The inventors of this application found through research and analysis, that the majority of rail beams of the related technique adopt an articulated compression support. As shown in Figure 1, an overhang 11 'is pre-inserted at the end of a PC beam using an anchor steel bar 3' and articulated to a underarm 12 'using a pivot shaft 13 '. The base plate 2 'is pre-inserted into a beam using a steel anchor bar 3' and is connected to the lower overhang 12 'using an anchor screw 21' after the beam is lifted. In the articulated support, the contact areas between the axis of the articulation 13 'and the upper balance 11' and the lower balance 12 'are small and the contact tension is very large, severely limiting the total support capacity of the support. In the case of a beam with a large span, the support cannot meet the requirements for use and a support capacity can be increased only by increasing the thickness of a 10 'swing member. In this case, a volume of the support and costs of manufacturing and assembling the support are increased, and the support is extremely bulky. In addition, when the PC beam is subjected to a torsional moment, the support encounters an eccentric load, that is, only one swing member 10 'is compressed and the other swing member 10' is pulled, resulting in a tendency to overload. In addition, a base plate body 2 'of the support is generally cast steel. When the anchor steel bar 3 'is welded directly to the base plate 2', the base plate 2 'must withstand both a shear force and a tension. Therefore, the quality of the base plate 2 'is required to be relatively high. In addition, due to the environmental impact, the production capacity of the support is limited, not meeting a large volume delivery demand. In addition, to leave space for rotation, a gap in a similar traction structure in the related technique is required. During work, a traction effect is generated only after the gap has been eliminated, resulting in extremely precarious stability of the support. In view of the above reasons, the inventor improved the support of the rail beam and obtained the technical solutions of this order.

[0045] A support set 100 and a rail beam 200, according to one embodiment of this application are described in detail below with reference from Figure 2 to Figure 9.

[0046] As shown in Figure 2 to Figure 4, the rail beam support assembly 100 provided in this embodiment of this order includes an upper support plate 41, a lower support plate 42, a support plate 43, a seat upper drive unit 51, a lower drive seat 52 and a drive block 53.

[0047] As shown in Figure 2 and Figure 4, the lower support plate 42 is located below the upper support plate 41. An upper surface of support plate 43 is in contact and fits the upper support plate 41, and a lower surface of the support plate is in contact and engages the lower support plate 42. The upper surface and the lower surface of the support plate 43 are respectively a rotating surface or a sliding surface. The rotating surface is a surface obtained by rotating a graphic around a fixed line by a specific angle, and the sliding surface is a surface obtained by translating a graphic over a specific distance along a fixed direction. Specifically, the fixed line extends in a lateral direction (a direction of the x axis in the figure) and the fixed direction is a longitudinal direction (a direction of the y axis in the figure).

[0048] As shown in Figure 3 and Figure 4, the upper traction seat 51 is fixedly connected to the lower support plate 42. Specifically, the upper traction seat 51 and the lower support plate 42 can be fixedly connected via welding, screwing or integral formation. Specifically, the upper traction seat 51 and the lower support plate 42 are integrally formed. The lower traction seat 52 is fixedly connected to the upper support plate 41. Specifically, the lower traction seat 52 and the upper support plate 41 can be fixedly connected by welding, screwing or integral formation. Specifically, the lower traction seat 52 and the upper support plate 41 are integrally formed. An upper surface of the drive block 53 is in contact and fits the upper drive seat 51, and a lower surface of the drive block is in contact and fits the lower drive seat

52. The upper surface and the lower surface of the drive block 53 are, respectively, a rotating surface or a sliding surface. The rotating surface is a surface obtained by rotating a graphic around a fixed line by a specific angle, and the sliding surface is a surface obtained by translating a graphic over a specific distance along a fixed direction.

[0049] The upper support plate 41 is in contact and fits the upper surface (the upper surface is a rotating or sliding surface) of the support plate 43 and the lower surface (the lower surface is a rotating surface or a sliding surface) of the support plate 43 is in contact and fits the lower support plate 42, so that there is a contact area in a relative manner between the upper support plate 41 and the lower support plate 42, considerably improving the total support capacity of the support set 100 and reducing the volume and costs of manufacturing and assembling the support set 100. In addition, the upper support plate 41 and the lower support plate 42 can move in relation to each other longitudinally (the direction of the y-axis in the figure) and rotate relative to each other in a longitudinal vertical plane (a yOz plane in the figure) to adapt to the flexural deformation and telescopic deformation of the rail beam

200.

[0050] The upper traction seat 51 is fixedly connected to the lower support plate 42 and is in contact and fits the upper surface of the traction block 53. The lower traction seat 52 is fixedly connected to the upper support plate 41 and is in contact and fits the lower surface of the drive block 53. In this way, the upper support plate 41 and the lower support plate 42 are prevented from moving relative to each other vertically (a direction of the z axis in the figure) and rotate in relation to each other in a lateral vertical plane, improving the traction capacity and lateral stability of the support set 100 in this modality of this order. The traction block 53 cooperates with the support plate 43 to help the upper support plate 41 and the lower support plate 42 to move more flexibly in relation to each other, avoiding eccentric load or tension tension and tension of excessive compression of the support assembly 100. In addition, a traction structure composed of the upper traction seat 41, the traction block 43 and the lower traction seat 42 is a traction structure without play. The three are always in contact and fit together while working, considerably improving the traction performance and stability of the support set 100.

[0051] In another embodiment of this application, the support set 100 additionally includes a limiting structure of the upper support plate (not shown). The limiting structure of the upper support plate is arranged on the lower support plate 42 and the limiting structure of the upper support plate is in contact and engages the upper support plate 41 to longitudinally limit the upper support plate 41. Specifically, the structure upper support plate limit block includes an upper support plate limit block (not shown). The upper support plate limiting block is located on the front and rear sides of the upper support plate 41 and is in contact and fits the upper support plate 41 and is fixedly connected to the lower support plate 42. Through the structure that is limited to the support plate disposed, the support set 100 provided in this mode of this order is changed from a sliding support set 100 to a fixed support set 100, that is, the upper support plate 41 and the lower support plate 42 are prevented to move in relation to each other longitudinally, but they can rotate in relation to each other in the vertical longitudinal plane. The y-axis direction in the figure is the longitudinal direction and the yOz plane in the figure is the longitudinal vertical plane.

[0052] As shown in Figure 3 and Figure 4, specifically, the upper surface of the support plate 43 is a sliding surface and the upper surface of the support plate 43 is a flat surface. A plane is a surface obtained by translating a line segment along a fixed direction for a specific distance. Specifically, the fixed direction is a longitudinal direction (the direction of the y-axis in the figure). A lower surface of the upper support plate 41 includes a sliding surface, and the sliding surface of the upper support plate 41 is a flat surface. Specifically, the lower surface of the upper support plate 41 is provided with a support projection 411 and a lower surface of the support projection 411 is the flat sliding surface. The flat sliding surface of the upper support plate 41 is in contact and engages the flat sliding surface of the support plate 43.

[0053] As shown in Figure 4, specifically, the bottom surface of the support plate 43 is a rotating surface and the bottom surface of the support plate 43 is a spherical surface. A spherical surface is a surface obtained by rotating an arc around a diameter of the arc by a specific angle. Specifically, the diameter extends in a lateral direction (the direction of the x-axis in the figure). An upper surface of the lower support plate 42 includes a rotating surface and the rotating surface of the lower support plate 42 is a spherical surface. Specifically, the upper surface of the lower support plate 42 is provided with a circular groove and a surface of the circular groove is the spherical rotating surface. The spherical rotating surface of the lower support plate 42 is in contact and engages the spherical rotating surface of the lower support plate 43. Specifically, the spherical rotating surface of the lower support plate 42 is a concave surface and the spherical rotating surface of the support plate 43 is a convex surface. This request is certainly not limited to that. The spherical rotating surface of the lower support plate 42 can also be a convex surface and the spherical rotating surface of the support plate 43 can also be a concave surface. The diameters of the spherical rotating surface of the support plate 43 and the spherical rotating surface of the lower support plate 42 can be designed according to different support capacities. Contact and fit between the spherical rotating surfaces can reduce the contact stress concentration between the lower support plate 42 and the support plate 43 and eliminate a mounting error between the upper support plate 41 and the lower support plate 42 and can meet the corner requirements of rail beam 200.

[0054] The flat sliding surface of the upper support plate 41 is in contact and fits the flat sliding surface of the support plate 43, so that the upper support plate 41 and the lower support plate 42 can move in relation to each other. the other longitudinally (the direction of the y-axis in the figure), to adapt to the telescopic deformation of the rail beam 200. The spherical rotating surface of the lower support plate 42 is in contact and fits the spherical rotating surface of the support plate 43, so that the upper support plate 41 and the lower support plate 42 can rotate relative to each other in the longitudinal vertical plane (the plane yOz in the figure), to adapt to the flexural deformation of the rail beam 200.

[0055] In another embodiment of this application, the upper surface of the support plate 43 is a spherical rotating surface and the lower surface of the support plate 43 is a flat sliding surface. The lower surface of the upper support plate 41 includes a spherical rotating surface. The upper surface of the lower support plate 42 includes a flat sliding surface. The spherical rotating surface of the upper support plate 41 is in contact and engages the spherical rotating surface of the support plate 43, so that the upper support plate 41 and the lower support plate 42 can rotate relative to each other in the plane longitudinal vertical (the yOz plane in the figure), to adapt to the flexion deformation of the rail beam 200. The flat sliding surface of the lower support plate 42 is in contact and fits the flat sliding surface of the support plate 43, so that the upper support plate 41 and the lower support plate 42 can move relative to each other longitudinally (the direction of the y-axis in the figure), to adapt to the telescopic deformation of the rail beam 200.

[0056] As shown in Figure 3, specifically, the upper surface of the drive block 53 is a rotating surface and is a cylindrical surface. A cylindrical surface is a surface obtained by rotating a line segment around a parallel line by a specific angle. Specifically, the parallel line extends in a lateral direction (the direction of the x-axis in the figure). An axis of rotation of the cylindrical rotating surface of the drive block 53 is collinear with an axis of rotation of the spherical rotating surface of the support plate 43. The upper drive seat 51 includes a rotating surface and the rotating surface of the upper drive seat 51 it is a cylindrical surface. Specifically, a part of the lower surface of the upper traction seat 51 is in contact and engages the lower support plate 42, and the other part is the cylindrical rotating surface. The cylindrical rotating surface of the upper drive seat 51 is in contact and fits the cylindrical rotating surface of the drive block 53. Specifically, the cylindrical rotating surface of the upper drive seat 51 is a convex surface and the cylindrical rotating surface of the drive block 53 is a concave surface. This request is certainly not limited to that. The cylindrical rotating surface of the upper drive seat 51 can also be a concave surface and the cylindrical rotating surface of the drive block 53 can also be a convex surface. The axis of rotation of the cylindrical rotating surface of the drive block 53 can also be parallel to the axis of rotation of the spherical rotating surface of the support plate 43.

[0057] As shown in Figure 3, specifically, the bottom surface of the drive block 53 is a sliding surface and is a flat surface. The lower traction seat 52 includes a sliding surface, and the sliding surface of the lower traction seat 52 is a flat surface. Specifically, a projection of the lower traction seat 52 on a lateral vertical plane (an xOz plane in the figure) is L-shaped, and the lower traction seat includes a first upper surface and a second lower surface. The first upper surface is superior to the second lower surface. The first upper surface of the lower traction seat 52 is in contact and engages the lower surface of the upper traction seat 51. The second lower surface of the lower traction seat 52 is the flat sliding surface. The flat sliding surface of the lower drive seat 52 is in contact and engages the flat sliding surface of the drive block 53.

[0058] The axis of rotation of the cylindrical surface of the drive block 53 may be parallel or collinear with the axis of rotation of the spherical surface of the support plate 43. For example, when the axis of rotation of the surface of the cylindrical surface of the drive block 53 is collinear with the axis of rotation of the spherical rotating surface of the support plate 43, interference between the upper traction seat 51 and the lower traction seat 52 during the relative rotation of the upper support plate 41 is avoided and the lower support plate 42 in the longitudinal vertical plane (the plane yOz in the figure). The cylindrical rotating surface of the upper drive seat 51 is in contact and engages the cylindrical rotating surface of the drive block 53, so that the upper drive seat 51 and the lower drive seat 52 can assist the upper support plate 41 and the lower support plate 42 to rotate relative to each other in the longitudinal vertical plane, to adapt to the flexion deformation of the rail beam 200. The flat sliding surface of the lower tension seat 52 is in contact and fits the flat rotating surface of the drive block 53, so that the upper drive seat 51 and the lower drive seat 52 can help the upper support plate 41 and the lower support plate 42 to move relative to each other longitudinally (the axis direction y in the figure), to adapt to the telescopic deformation of the rail beam 200.

[0059] In another embodiment of this application, the upper surface of the drive block 53 is a flat sliding surface and the lower surface of the drive block 53 is a cylindrical rotating surface. The upper drive seat 51 includes a flat sliding surface. The lower drive seat 52 includes a cylindrical rotating surface. The axis of rotation of the cylindrical surface of the drive block 53 is collinear with the axis of rotation of the spherical surface of the support plate 43, so that the interference between the upper seat 51 and the lower seat 52 it is avoided during the relative rotation of the upper support plate 41 and the lower support plate 42 in the longitudinal vertical plane (the plane yOz in the figure). The flat sliding surface of the upper drive seat 51 is in contact and engages the flat rotating surface of the drive block 53, so that the upper drive seat 51 and the lower drive seat 52 can assist the upper support plate 41 and the lower support to the plate 42 to move relative to each other longitudinally (the direction of the y-axis in the figure), to adapt to the telescopic deformation of the rail beam 200. The cylindrical rotating surface of the lower drive seat 52 is in contact and engages the cylindrical rotating surface of the drive block 53, so that the upper drive seat 51 and the lower drive seat 52 can assist the upper support plate 41 and the lower support plate 42 to rotate relative to each other in the longitudinal vertical plane, to adapt to the flexural deformation of the rail beam 200.

[0060] As shown in Figure 2 to Figure 4, the upper traction seat 51 includes a first upper traction seat 511 and a second upper traction seat 512. The first upper traction seat 511 is fixedly connected to a left end of the bottom support plate

42. The second upper traction seat 512 is fixedly connected to a right end of the lower support plate 42. The lower traction seat 52 includes a first lower traction seat 521 and a second lower traction seat 522. The first seat of traction lower drive 521 is fixedly connected to a left end of upper support plate 41. The second lower drive seat 522 is fixedly connected to a right end of upper support plate 41. Drive block 53 includes a first drive block 531 and a second drive block 532. An upper surface of the first drive block 531 is in contact and fits the first upper drive seat 511 and a lower surface of the first drive block 531 is in contact and fits the first lower drive seat 521. An upper surface of the second drive block 532 is in contact and fits the second upper drive seat 512, and a lower surface of the second drive block 532 is in contact contact and fits the second lower traction seat 522.

In real applications, it has been found that the support assembly 100 generally needs to withstand only a relatively small voltage. Therefore, only an upper traction seat 51 needs to be arranged at each of the two ends of the lower support plate 42 to meet the traction requirements. The upper left and right traction seats 51, the traction blocks 53 and the lower traction seats 52 are in contact and fit together, greatly improving the traction capacity and the lateral stability of the support set 100 provided in this modality of this order.

[0061] As shown in Figure 3 and Figure 4, the support assembly 100 provided in this embodiment of this application includes at least two support plates 43. Specifically, there are two support plates 43. An upper surface of each of the support plates support 43 is in contact and fits the upper support plate 41. A lower surface of each of the support plates 43 is in contact and fits the lower support plate 42. The plurality of support plates 43 is arranged laterally (the direction the x-axis in the figure). The plurality of support plates 43 arranged laterally provide a plurality of lateral supports for the connection between the upper support plate 41 and the lower support plate 42. In addition, since the upper support plate 41, the support plate 43 and the lower support plate 42 are connected in a non-fixed manner, eccentric load or excessive tension is avoided for the left and right parts of the support set 100, significantly improving the lateral stability of the support set

100.

[0062] As shown in Figure 4, the lower surface of the upper support plate 41 is additionally provided with at least two support projections 411. Specifically, there are two support projections

411. A lower surface of each of the support protrusions 411 is in contact and fits an upper surface of one of the support plates

43. The bottom surface of the support projection 411 is a rotating or sliding surface. Specifically, the bottom surface of the support projection 411 is a flat sliding surface. The upper support plate 41 is in contact and fits the support plate 43 through the support projection 411, facilitating the processing of a contact surface and reducing the processing costs.

[0063] As shown in Figure 3 in Figure 4 and Figure 7, the upper surface of the lower support plate 42 is additionally provided with two shear projections 421. A side surface of each of the shear projections 421 is in contact and fits a side surface of one of the support projections 411. The shear projection 421 is configured to perform lateral positioning (the direction of the x-axis in the figure) to mount the upper support plate 41 and provide a shear function for the assembly support 100.

[0064] As shown in Figure 2 and Figure 4, the upper surface of the upper support plate 41 is fixedly connected to a plurality of steel anchor bars 3. Specifically, the upper surface of the upper support plate 41 is provided with a plurality of screwed holes in a screwed connection and welded to a plurality of anchor steel bars 3. Through the anchor steel bar 3, the upper support plate 41 can be pre-inserted into the rail beam 200 during casting of the rail beam 200.

[0065] As shown in Figure 4, the support set 100 provided in this embodiment of this application additionally includes a first sliding plate 61, a second sliding plate 62, a third sliding plate 63, a fourth sliding plate 64 and a fifth sliding plate

65. The upper support plate 41 is in contact and fits the support plate 43 through the first sliding plate 61. The lower support plate 42 is in contact and engages the support plate 43 through the second sliding plate

62. The upper drive seat 51 is in contact and engages the drive block 53 through the third sliding plate 63. The lower drive seat 52 is in contact and engages the drive block 53 through the fourth sliding plate 64. The surface side of the support projection 411 of the upper support plate 41 is in contact with the lateral surface of the shear projection 421 of the lower support plate 42 and the fifth sliding plate 65. The first sliding plate 61, the second sliding plate 62, the third sliding plate 63, fourth sliding plate 64 and fifth sliding plate 65 are all made of selected materials of modified ultra-high molecular weight polyethylene (ultra-high molecular weight polyethylene is linear unbranched linear polyethylene with a molecular weight of more than 1.5 million, and modified ultra-high molecular weight polyethylene is ultra-high molecular weight polyethylene obtained after modification processing). Modified ultra-high molecular weight polyethylene has low friction, is flexible and has a cushioning effect.

[0066] Specifically, the first sliding plate 61 is a flat plate, the second sliding plate 62 is a spherical plate, the third sliding plate 63 is a cylindrical plate, the fourth sliding plate 64 is a flat plate and the fifth sliding plate 65 it is a flat plate. The first sliding plate 61, the second sliding plate 62, the third sliding plate 63 and the fourth sliding plate 64 greatly reduce the frictional resistance that exists during the sliding and rotation of the upper support plate 41 and the lower support plate 42 and have a damping effect in the vertical direction (a direction on the z axis in the figure). The fifth sliding plate 65 facilitates the relative longitudinal movement (the direction of the y-axis in the figure) between the upper support plate 41 and the lower support plate 42 and has a damping effect in a lateral direction (a direction of the x axis in the figure).

[0067] As shown in Figure 2 to Figure 6, the support set 100 provided in this embodiment of this order additionally includes a base plate 2. Base plate 2 is located below the lower support plate 42 and connected to the support plate lower 42 using an anchor screw 21. The lower support plate 42 has a waist-shaped anchor screw hole, which can be configured to adjust a construction error when mounting the lower support plate 42. A projection and a movable plate are additionally arranged between the lower support plate 42 and the base plate 2 and are connected using the anchor screw 21 to adjust a height of the lower support plate 42 in a vertical direction (the direction the z-axis in the figure). The base plate 2 is adapted to be pre-inserted into the rail beam to provide a mounting base for the lower base plate 42 and a shear function for the base assembly 100. The left and right ends of the base plate 2 are mounting surfaces and are required to have a relatively small roughness in order to be further processed to form two-stage structures. The base plate 2 is additionally provided with a plurality of through holes, which include a large hole for grouting and a small hole for exhaust.

[0068] As shown in Figure 2, Figure 3, Figure 5 and Figure 6, four concrete insulation boxes 22 are fixedly mounted on the bottom surface of the base plate 2 and located below the anchor bolt 21. The box concrete insulation 22 is configured to insulate the concrete and is adapted to provide a mounting space for the anchor bolt 21 during the dumping of a beam.

[0069] As shown in Figure 2 to Figure 6, the bottom surface of the base plate 2 is additionally provided with eight anchoring steel bar mounting bases 23. Each of the two anchoring steel bar mounting bases 23 it is located on both sides of a concrete insulation box 22. Specifically, the mounting base of the steel anchor bar 23 is fixedly connected to the bottom surface of the base plate 2 by threading or welding. Specifically, the mounting base of the anchor steel bar 23 is provided with a threaded hole in a threaded connection and welded to an anchor steel bar 3. The base plate 2 is connected to the anchor steel bar 3 via of the mounting base of the anchor steel bar 23, and the mounting base of the anchor steel bar 23 withstands tension during work, improving the traction capacity of the support set 100 provided in this embodiment of this order.

[0070] As shown in Figure 4 and Figure 6, the bottom surface of the base plate 2 is additionally provided with a strip-shaped shear bar 24. Specifically, the shear bar 24 is welded to the bottom surface of the plate base 2. The shear bar 24 is located below the base plate 2, and is inserted into the concrete when pouring the beam, improving the shear capacity of the base plate 2, thus improving the shear capacity of the support set 100 provided in this modality of this order.

[0071] As shown in Figure 2 to Figure 5, the upper surface of the base plate 2 is provided with two longitudinal adjustment devices 25 arranged respectively on the front and rear side of the lower support plate 42. The longitudinal adjustment device 25 includes an adjustment plate 251 and an adjustment screw 252. The adjustment plate 251 is fixedly connected to the base plate 2. Specifically, the adjustment plate 251 is welded to the base plate 2. The adjustment screw 252 is threaded to the adjustment plate 251 and one end of the adjustment screw. 252 is in contact and fits the lower support plate 42. Due to a construction error and a beam error, the support assembly 100 cannot be assembled in place at once. Therefore, a screw position of the adjustment screw 252 on the adjustment plate 251 can be adjusted to adjust and fix a longitudinal mounting position (the direction of the y-axis in the figure) of the lower support plate 42.

[0072] As shown in Figure 3 to Figure 5, the upper surface of the base plate 2 is additionally provided with a shear pin 26. The shear pin 26 is fixedly connected to the base plate 2. Specifically, the shear pin 26 is welded to a central part of the upper surface of the base plate 2 and fits a shear pin opening 422 provided in the central part of the lower support plate 42, to position laterally (the direction of the x-axis in the figure) and longitudinally ( the direction of the y-axis in the figure) the lower support plate 42 in relation to the base plate 2. After being adjusted laterally in place, the lower support plate 42 is wedged using a wedge block 261 and then fixed by welding. Through the engagement of the shear pin 26 and the lower support plate 42, the shear capacity of the lower support plate 42 is improved, thereby improving the shear capacity of the support assembly 100.

[0073] As shown in Figure 8 and Figure 9, in a support assembly 100 in another embodiment of this order, there may be two shear pins 26. The two shear pins 26 are welded on the top surface of the base plate 2 and they are located respectively on the front and rear side of the lower support plate 42. In addition, each of the shear pins 26 is in contact and engages the lower support plate 42 through three lateral surfaces. Two of the shear pins 26 position the lower support plate 42 relative to the base plate 2 laterally (the direction of the x-axis in the figure) and longitudinally (the direction of the y-axis in the figure) and additionally serve as the longitudinal adjustment device. 25. After being adjusted longitudinally in place, the lower support plate 42 is wedged using the wedge block 261 on the three side surfaces of the shear pin 26 that are in contact and fit the lower support plate 42 and then fixed by welding.

[0074] As shown in Figure 10, a rail beam 200 provided in one embodiment of this order includes support set 100 provided in the embodiments of this order. The loads generated by the rail beam 200 and a train are transmitted to the upper support plate 41, then to the lower support plate 42 through the support plate 43, and then to the base plate 2 and the beam. A moment load of tension or bending generated at one end of the rail beam 200 is transmitted to the lower support plate 42 through the lower drive seat 52, the drive block 53 and the upper drive seat 51, and then to the top of the beam through the anchor bolt 21. A lateral load generated at the end of the rail beam 200 is transmitted to the lower support plate 42 through the support projection 411 and the shear projection 421 and then to the base plate 2 and the beam through the shear pin 26).

[0075] According to the support set 100 provided in the modalities of this order, the total support capacity of beam 200 is considerably improved, and the volume and costs of manufacturing and assembling support set 100 on rail beam 200 are reduced. In addition, one end of the beam 200 on which the support assembly 100 is mounted can perform a relative longitudinal movement (the direction of the y-axis in the figure) and a relative rotation in the vertical longitudinal plane (the yOz plane in the figure) to adapt flexural deformation and telescopic deformation of the rail beam 200. In addition, the tensile strength and lateral stability of the rail beam 200 are also improved, preventing eccentric loading or excessive tensile stress of the rail beam 200.

[0076] Other compositions and operations of the rail beam 200, according to the modalities of this application, are known to persons of ordinary skill in the art, and the details are not described in this document again.

[0077] In the descriptions of this specification, descriptions using the terms of reference "a modality", "some modalities", "an exemplary modality", "an example", "a specific example" or "some examples" mean that specific characteristics, structures, materials or resources described with reference to the modality or example are included in at least one modality or example of this application. In this specification, schematic descriptions of the aforementioned terms are not necessarily directed to the same modality or example. In addition, the specific features, structures, materials or characteristics described can be combined in any one or more modalities or examples in an appropriate manner.

[0078] Although the modalities of this application have been shown and described, people of ordinary skill in the art must understand that various changes, modifications, substitutions and variations can be made in the modalities without departing from the principles and spirit of this application, and the scope of this order is defined by the appended claims and their equivalents.

Claims (18)

1. Support set for a rail beam, characterized by comprising: an upper support plate; a lower support plate located below the upper support plate; a support plate, an upper surface of the support plate that is in contact with and fits in the upper support plate, and a lower surface of the support plate that is in contact and fits in the lower support plate; an upper traction seat fixedly connected to the lower support plate; a lower traction seat fixedly connected to the upper support plate; and a traction block, an upper surface of the traction block being in contact with and engaging the upper traction seat and a lower surface of the traction block being in contact with and engaging the lower traction seat; the upper support plate and the lower support plate are able to move relative to each other longitudinally and to rotate relative to each other in a vertical longitudinal plane. A rail beam support assembly according to claim 1, characterized in that the upper surface of the support plate is a sliding surface and the lower surface of the support plate is a rotating surface; a lower surface of the upper support plate comprises a sliding surface; and an upper surface of the lower support plate comprises a rotating surface, the sliding surface of the upper support plate is in contact and engages with the sliding surface of the support plate and the rotating surface of the lower support plate is in contact and engaging with the surface rotating support plate; or the upper surface of the support plate is a rotating surface and the lower surface of the support plate is a sliding surface; the lower surface of the upper support plate comprises a rotating surface; and the upper surface of the lower support plate comprises a sliding surface, the rotating surface of the upper support plate is in contact and engages with the rotating surface of the support plate and the sliding surface of the lower support plate is in contact and engaging with the surface support plate slide. A rail beam support assembly according to claim 2, characterized in that the rotating surface of the support plate is a spherical surface and the sliding surface of the support plate is a flat surface. 4. A rail beam support assembly according to any one of claims 1 to 3, characterized in that each of the support plate and the drive block has a rotating surface, an axis of rotation of the rotating surface of the plate support and an axis of rotation of the rotating surface of the traction block are collinear; the upper surface of the traction block is a rotating surface and the lower surface of the traction block is a sliding surface; a lower surface of the upper traction seat comprises a rotating surface; and an upper surface of the lower traction seat comprises a sliding surface, the rotating surface of the upper traction seat is in contact and engaging with the rotating surface of the traction block and the sliding surface of the lower traction seat is in contact and engaging with the surface traction block slider; or the upper surface of the drive block is a sliding surface and the lower surface of the drive block is a rotating surface; the lower surface of the upper traction seat comprises a sliding surface; and the upper surface of the lower traction seat comprises a rotating surface, the sliding surface of the upper traction seat is in contact and engaging with the sliding surface of the traction block and the rotating surface of the lower traction seat is in contact and engaging with the surface rotation of the traction block. A rail beam support assembly according to claim 4, characterized in that the rotating surface of the traction block is a cylindrical surface and the sliding surface of the traction block is a flat surface. A rail beam support assembly according to any one of claims 1 to 5, characterized in that the upper traction seat comprises a first upper traction seat and a second upper traction seat, the first upper traction seat be fixedly connected to a left end of the lower support plate and the second upper traction seat fixedly connected to a right end of the lower support plate; the lower traction seat comprises a first lower traction seat and a second lower traction seat, the first lower traction seat is fixedly connected to a left end of the upper support plate and the second lower traction seat is fixedly connected to a right end of the upper support plate; and the drive block includes a first drive block and a second drive block, an upper surface of the first drive block is in contact and engages the first upper drive seat, and a lower surface of the first drive block is in contact, and engage the first lower drive seat and an upper surface of the second drive block be in contact and engage the second upper drive seat, and a lower surface of the second drive block be in contact and engage the second lower drive seat. A rail beam support assembly according to any one of claims 1 to 6, characterized in that it additionally comprises: a first sliding plate, a second sliding plate, a third sliding plate and a fourth sliding plate, a upper support plate is in contact and fits on the support plate through the first sliding plate; the lower support plate is in contact and fits on the support plate through the second sliding plate; the upper traction seat is in contact and fits the traction block through the third sliding plate; and the lower traction seat is in contact and fits the traction block through the fourth sliding plate. 8. A rail beam support assembly according to any one of claims 1 to 7, characterized in that there are at least two support plates, an upper surface of each of the support plates being in contact and engaging with the support plate. upper support, a lower surface of each of the support plates being in contact and engaging with the lower support plate and the at least two support plates being arranged laterally. A rail beam support assembly according to claim 8, characterized in that at least two support projections are additionally arranged on the lower surface of the upper support plate, a lower surface of each of the support projections being in contact and fit on an upper surface of one of the support plates. A rail beam support assembly according to claim 9, characterized in that a shear protrusion is additionally arranged on the upper surface of the lower support plate, a lateral surface of the shear protrusion is in contact and engages a surface side of the support overhang. 11. Support set for a rail beam, according to claim 10, characterized in that it further comprises: a fifth sliding plate, the fifth sliding plate being a flat plate and the lateral surface of the support projection being in contact with and fitted on the side surface of the cutting boss through the fifth sliding plate. Support set for a rail beam according to any one of claims 1 to 11, characterized in that it additionally comprises: a base plate, the base plate of which is located below the lower support plate and connected to the plate lower support with the use of an anchor bolt. 13. Rail beam support set according to claim 12, characterized in that it further comprises: a concrete insulation box, the concrete insulation box being mounted on a lower surface of the base plate and located below the anchor bolt. 14. A rail beam support set according to claim 12 or 13, characterized in that it further comprises: an anchor steel bar mounting base, the anchor steel bar mounting base being located below the base plate and fixedly connected to the base plate and the mounting base of the steel anchor bar is provided with a threaded hole, in which the threaded hole is adapted to be in a threaded connection to a steel bar anchoring. A rail beam support assembly according to any one of claims 12 to 14, characterized in that it further comprises: a shear bar, wherein the shear bar is a strip-like structure, located below the plate base and fixedly connected to the base plate. 16. A rail beam support assembly according to any one of claims 12 to 15, characterized in that it additionally comprises: two longitudinal adjustment devices arranged respectively on a front side and a rear side of the lower support plate, being that the longitudinal adjustment device comprises an adjustment plate and an adjustment screw, in which the adjustment plate is fixedly connected to the base plate and one end of the adjustment screw is in contact and engages the lower support plate. Support set according to any one of claims 12 to 16, characterized in that it further comprises: a shear pin located above the base plate and fixedly connected to the base plate, where a side surface of the shear pin is in contact and fits the lower support plate and is configured to position the lower support plate laterally and longitudinally in relation to the base plate. 18. Rail beam, characterized by comprising: the support assembly of a rail beam, as defined in any one of claims 1 to 17.