A template carrier device

The template support device, with its aluminum alloy frame base and T-slot splicing structure, solves the problem of the solidification of existing template base structures, achieving flexible splicing and lightweight design, adapting to template components of different sizes, and improving construction efficiency and safety.

CN224393291UActive Publication Date: 2026-06-23CSCEC BRIDGES CO LTD +2

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CSCEC BRIDGES CO LTD
Filing Date
2025-08-26
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

The existing template base structure is rigid, lacks flexibility, has limited load-bearing capacity, cannot adapt to template components of different sizes, and the installation and moving process relies on cranes, which is inefficient and costly.

Method used

It adopts an aluminum alloy frame base with an internal reinforcing seat and T-slot splicing structure. Combined with detachable steel plates and I-beam locking parts, it can achieve seamless splicing of multiple bases. It is equipped with casters and diagonal bars to enhance stability and adapt to different size requirements.

Benefits of technology

It improves the flexibility and load-bearing consistency of the template base, reduces step errors, and the lightweight design reduces equipment costs, thereby improving construction efficiency and safety.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model provides a kind of sample bearing device, comprising: base, with cavity, multiple reinforcing seats are equipped in the cavity, the top surface height of the reinforcing seat is lower than the top surface height of the base, for being constructed into the supporting position of supporting sample component;Splicing structure, including first splicing structure and second splicing structure being located in the opposite ends of the base;Wherein, the first splicing structure and adjacent the second splicing structure are inlaid, and are locked by locking member, to make multiple the base seamless splicing.It solves the technical problem of poor flexibility of sample base structure solidification in the prior art.
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Description

Technical Field

[0001] This utility model relates to the field of building engineering technology, and in particular to a template support device. Background Technology

[0002] In current construction sites, to showcase standardized construction details or as part of quality month demonstration projects, "physical template bases" are typically used to support standardized construction template components. These bases are usually composed of lifting rings, channel steel, and steel plates. Their working principle is as follows: the base is hoisted to a designated location by a crane, and then the prefabricated template component is placed on it, completing the standardized display. This technology has a certain degree of widespread use in actual engineering projects, mainly in outdoor construction environments, to support large and heavy standardized template components, and can also serve as a field demonstration model of construction techniques. However, existing technology still has several shortcomings in terms of structure and use, specifically: First, existing physical template bases lack internal supporting components, limiting their load-bearing capacity and restricting their applicability to only certain components. Second, the overall structure of the base is bulky, large in size, and heavy, requiring crane lifting during installation and subsequent relocation, increasing equipment costs and reducing construction efficiency. Furthermore, due to the fixed structure and uniform size of the base, it cannot be flexibly assembled according to the size requirements of different sites and sample components, lacking adaptability and scalability. In summary, the existing solid sample base structure is rigid, lacks flexibility, and is difficult to meet the efficiency, safety, and diversity requirements of modern construction sites. Utility Model Content

[0003] To address the shortcomings of existing technologies, this utility model provides a template support device that solves the technical problems of rigid template base structure and poor flexibility in existing technologies.

[0004] According to the embodiments of this utility model, the following technical solution is adopted:

[0005] A template support device for supporting template components, the support device comprising:

[0006] The base has a cavity, and multiple reinforcing seats are provided inside the cavity. The top surface of the reinforcing seats is lower than the top surface of the base, which is used to construct a support position for supporting the template component.

[0007] The splicing structure includes a first splicing structure and a second splicing structure disposed at opposite ends of the base;

[0008] The first splicing structure fits into the adjacent second splicing structure and is locked in place by a locking member to ensure seamless splicing of the multiple bases.

[0009] Preferably, the first splicing structure is a first T-shaped groove provided on the base, the second splicing structure is a second T-shaped groove, and the opening directions of the first T-shaped groove and the second T-shaped groove are opposite.

[0010] Preferably, the locking element is an I-beam, which is detachably installed in the first T-slot and the second T-slot.

[0011] Preferably, the surface of the I-beam is provided with a magnet.

[0012] Preferably, the base is provided with a first inclined rod, and the two ends of the first inclined rod are provided with the corresponding reinforcing seats.

[0013] Preferably, the base is provided with a second inclined rod, the two ends of the second inclined rod are provided on the corresponding reinforcing seat, and the second inclined rod and the first inclined rod are arranged alternately vertically.

[0014] Preferably, the base is provided with multiple casters at its bottom.

[0015] Preferably, the base is provided with a plurality of threaded rods that correspond one-to-one with the universal wheels.

[0016] Compared with the prior art, this utility model has the following advantages: multiple bases can be flexibly combined to adapt to templates of different sizes; seamless splicing reduces step errors and improves the consistency of the bearing surface; the lightweight cavity of the base reduces weight without affecting the bearing performance. Attached Figure Description

[0017] Figure 1 This is a schematic diagram of the structure of the bearing device in one embodiment of the present invention;

[0018] Figure 2 This is a partial structural schematic diagram of the bearing device in one embodiment of the present invention;

[0019] Figure 3 This is a schematic diagram of the splicing structure of two support devices in one embodiment of the present invention.

[0020] In the above attached figures: 1. Base; 2. Cavity; 3. Reinforcing seat; 4. Support position; 5. Steel plate; 6. First T-slot; 7. Second T-slot; 8. I-beam; 9. First diagonal brace; 10. Second diagonal brace; 11. Caster wheel; 12. Threaded rod. Detailed Implementation

[0021] To make the objectives, technical solutions, and beneficial effects of this utility model clearer, the technical solutions of this utility model are further described below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of this utility model and are not intended to limit it.

[0022] See Figures 1 to 3 This utility model provides a template support device for supporting template components. The support device includes:

[0023] The base 1 has a cavity 2, and a plurality of reinforcing seats 3 are provided in the cavity 2. The top surface of the reinforcing seats 3 is lower than the top surface of the base 1, and is used to form a support position 4. The support position 4 is detachably provided with a steel plate 5.

[0024] The splicing structure includes a first splicing structure and a second splicing structure disposed at opposite ends of the base 1;

[0025] The first splicing structure fits into the adjacent second splicing structure and is locked in place by a locking member to ensure that the multiple bases 1 are seamlessly spliced ​​together.

[0026] In this embodiment, the base 1 uses a hollow cast aluminum alloy frame. Compared with welded rectangular tubes, the casting process can optimize the internal stress distribution, and the strength and rigidity of the aluminum alloy are significantly improved after heat treatment, while reducing the overall weight of the base 1 and facilitating transportation. The base 1 has a rectangular cavity 2, and four reinforcing seats 3 are provided at the top corners of the cavity 2. The top surface of the base 3 is lower than the top surface of the base 1, forming a support position 4 to ensure structural strength. The steel plate 5 is detachably set on the support position 4. Different specifications (such as thickness, material, surface treatment) of steel plate 5 can be replaced according to the size, shape, or load-bearing requirements of different plate components, or the steel plate 5 can be replaced after wear, improving the versatility and service life of the device. A splicing structure is also provided on the base 1 to connect multiple identical base 1 units together to form a larger area of ​​load-bearing platform. The splicing structure includes a first splicing structure and a second splicing structure located at opposite ends of the base 1, i.e. A first splicing structure and a second splicing structure are provided in the length or width direction of the base 1. Depending on the actual situation, they can also be provided in both the length and width directions. In this embodiment, the first splicing structure and the second splicing structure are provided in the length direction of the base 1, with the ends spaced apart. The first splicing structure is used to fit with the second splicing structure of the adjacent base 1 and is locked by locking members to ensure that after multiple bases 1 are connected, their bearing surfaces (especially the surface of the steel plate 5) are as flat as possible, avoiding steps or gaps, and ensuring the flatness of the sample component display. This bearing device can support a sample component by installing a suitable steel plate 5 on the support position 4 of a single base 1. When a larger bearing area is required, multiple bases 1 can be fitted together by the first splicing structure and the second splicing structure and locked by locking members to achieve seamless splicing, forming a large platform with a larger bearing area and a flatter surface. It can also be flexibly combined according to needs to adapt to samples of different sizes.

[0027] The first splicing structure is a first T-shaped groove 6 provided on the base 1, and the second splicing structure is a second T-shaped groove 7, and the opening directions of the first T-shaped groove 6 and the second T-shaped groove 7 are opposite.

[0028] In this embodiment, the first splicing structure and the second splicing structure are a first T-shaped groove 6 and a second T-shaped groove 7 provided on the base 1. The first T-shaped groove 6 is provided at the first end along the length direction of the base 1, and the second T-shaped groove 7 is provided at the end along the length direction of the base 1. The opening direction of the second T-shaped groove 7 is opposite to the opening direction of the first T-shaped groove 6. By using the first T-shaped groove 6 and the second T-shaped groove 7 as splicing structures and inserting locking members between them, the locking members can lock two adjacent bases 1 together, preventing displacement or separation when bearing load. Since the opening directions of the first T-shaped groove 6 and the second T-shaped groove 7 are opposite, when two bases 1 approach each other for splicing, they will naturally guide each other into the correct alignment position, reducing the need for manual adjustment and making the splicing process more efficient and accurate. At the same time, the splicing of the T-shaped grooves also supports bidirectional expansion, and more base 1 units can be added in any direction to expand the bearing area. Whether in the length direction or the width direction, a larger bearing plane can be quickly constructed while maintaining good stability and consistency.

[0029] The locking component is an I-beam 8, which is detachably installed in the first T-slot 6 and the second T-slot 7.

[0030] In this embodiment, the I-beam 8 itself has extremely high bending and shear resistance, which can effectively bear the load at the splice and prevent the base 1 from sliding or deforming relative to each other when bearing load or moving, thus ensuring the stability of the seamless splice. The cross-section of the I-beam is perfectly matched with the first T-slot 6 and the second T-slot 7 with opposite opening directions. After the two bases 1 are aligned and fitted together through the first T-slot 6 and the second T-slot 7, a suitable length of I-beam 8 is installed in the first T-slot 6 and the second T-slot 7. When one end of the I-beam 8 is inserted into the first T-slot 6, the flange direction of its other end can be matched with the opening of the second T-slot 7 of the adjacent base 1 in the opposite direction and be smoothly inserted, realizing quick disassembly and seamless splicing.

[0031] The surface of the I-beam 8 is provided with magnets.

[0032] In this embodiment, the magnet is disposed on the surface of the I-beam 8. The magnet can be embedded in the surface of the I-beam 8, or it can be fixed to its exposed flanges or web by means of adhesive, screws, etc. During disassembly or transportation, if the I-beam 8 is only fixed by the engagement of the T-slot, when the base 1 is tilted or flipped, the I-beam 8 may slide out of the T-slot due to gravity and fall off. When the I-beam 8 is inserted into the T-slot, the magnet on its surface will be attracted to the metal part of the base 1 (the base 1 itself is usually a steel structure), providing additional safety. Even in a non-horizontal state, it can effectively prevent the I-beam 8 from easily slipping off, avoiding the loss of parts or causing safety hazards. When the I-beam 8 is not used in a single base 1, the I-beam 8 can be magnetically attracted to any position of the base 1 that does not affect the load-bearing capacity.

[0033] The base 1 is provided with a first inclined rod 9, and the two ends of the first inclined rod 9 are provided with the corresponding reinforcing seat 3.

[0034] In this embodiment, the first diagonal bar 9 is installed inside the base 1, and its two ends are respectively fixed on the corresponding reinforcing seat 3, thereby forming a triangular stable structure to increase the rigidity and deformation resistance of the entire base 1.

[0035] The base 1 is provided with a second inclined rod 10, the two ends of the second inclined rod 10 are provided on the corresponding reinforcing seat 3, and the second inclined rod 10 and the first inclined rod 9 are arranged in an alternating manner.

[0036] In this embodiment, the staggered arrangement of the first diagonal bar 9 and the second diagonal bar 10 can more effectively resist torque from different directions and avoid torsional deformation. Compared with a single diagonal bar or a parallel arrangement, the staggered diagonal bars can simultaneously improve the structural stiffness in both the longitudinal and transverse directions, reduce overall sway, and when under stress, the load will be transmitted to the base 1 (similar to a truss structure) through two paths, dispersing stress concentration points and avoiding local overload. If one of the diagonal bars is damaged, the other can still provide partial support, improving the reliability of the structure.

[0037] The base 1 is provided with multiple casters 11 at its bottom.

[0038] In this embodiment, in order to facilitate the movement of the device, four casters 11 are provided on the base 1. In addition, when multiple bases 1 are spliced ​​together, the support angle of adjacent casters 11 can be rotated to avoid interference between the casters 11, which would cause misalignment of the spliced ​​bearing platform. The locking function of the casters 11 can also be used in conjunction with the splicing structure to restrict the movement between two adjacent bases 1.

[0039] The base 1 is provided with a plurality of threaded rods 12 that correspond one-to-one with the universal wheels 11.

[0040] In this embodiment, by manually rotating the threaded rod 12, the height of each caster wheel 11 can be finely adjusted to a certain extent, thereby adjusting the levelness of the entire device to adapt to uneven ground.

[0041] Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of this utility model and are not intended to limit it. Although this utility model has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solutions of this utility model without departing from the spirit and scope of the technical solutions of this utility model, and all such modifications or substitutions should be covered within the scope of the claims of this utility model.

Claims

1. A template carrier device for carrying a template member, the device comprising: The supporting device includes: The base has a cavity, and multiple reinforcing seats are provided in the cavity. The top surface of the reinforcing seats is lower than the top surface of the base, which is used to construct a support position. The support position is detachably provided with a steel plate. The splicing structure includes a first splicing structure and a second splicing structure disposed at opposite ends of the base; The first splicing structure fits into the adjacent second splicing structure and is locked in place by a locking member to ensure seamless splicing of the multiple bases.

2. A template carrier according to claim 1, wherein, The first splicing structure is a first T-shaped groove provided on the base, and the second splicing structure is a second T-shaped groove, with the opening directions of the first T-shaped groove and the second T-shaped groove being opposite.

3. A template carrier according to claim 2, wherein, The locking component is an I-beam, which is detachably installed in the first T-slot and the second T-slot.

4. A template carrier according to claim 3, wherein, The surface of the I-beam is equipped with magnets.

5. A template carrier according to claim 1, wherein, The base is provided with a first inclined rod, and the two ends of the first inclined rod are provided with the corresponding reinforcing seats.

6. A template carrier according to claim 5, wherein, The base is provided with a second inclined rod, the two ends of which are located at the corresponding reinforcing seats, and the second inclined rod and the first inclined rod are arranged in an alternating manner.

7. A template carrier according to claim 1, wherein, The base is equipped with multiple casters at its bottom.

8. A template carrier according to claim 7, wherein, The base is provided with multiple threaded rods that correspond one-to-one with the casters.