A rapid material transfer auxiliary device inside a template support system
By designing a protective mechanism with adjustable angle and length, the problem of material instability during transportation of existing equipment was solved, achieving stable material protection and improving construction speed.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- CHINA HYDROPOWER ELEVENTH ENG BUREAU (ZHENGZHOU) CO LTD
- Filing Date
- 2025-08-11
- Publication Date
- 2026-07-03
AI Technical Summary
Existing material transfer auxiliary devices are unable to stably protect materials during transportation, leading to material collapse and affecting the construction speed.
An auxiliary device for rapid material transfer within a template support system was designed. Through a protective mechanism with adjustable angle and length, the protection of materials on the support plate is improved, preventing materials from falling off during transportation.
The use of multiple protective mechanisms enhances the stability of materials during transportation, ensures construction speed, and reduces the environmental impact of transportation.
Smart Images

Figure CN224452267U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of building formwork construction technology, specifically relating to an auxiliary device for rapid material transfer within a formwork support system. Background Technology
[0002] The rapid material transfer auxiliary device inside the formwork support system is a mechanized transfer tool designed specifically for building formwork engineering. It is used to move construction materials such as formwork and prefabricated components efficiently and safely in confined spaces. By replacing manual handling, it solves the problems of narrow internal space, low efficiency and high safety hazards of manual handling in the formwork support system, and realizes rapid positioning, transfer and installation of materials.
[0003] Existing material transfer auxiliary devices often use two iron bars placed on the side of the auxiliary device to protect the stacked materials and prevent them from falling during transportation. However, depending on the materials being transferred at the construction site, it is difficult to provide stable protection for the materials using only iron bars, which can cause the materials to collapse during transportation and affect the construction speed. Utility Model Content
[0004] To address the aforementioned issues, this invention provides an auxiliary device for rapid material transfer within a template support system. The device features a protective mechanism that allows for adjustment of angle and length, enhancing edge support and protection of the material on the support plate and preventing material from falling during transport.
[0005] This utility model achieves the above objectives through the following technical solutions:
[0006] A rapid material transfer auxiliary device for a template support system includes: two support plates and two running tracks. An extension plate and a fixing opening plate are provided between the two support plates. A limit bolt is provided through one of the two support plates. Both support plates are provided with two protection mechanisms.
[0007] Both of the aforementioned running tracks are provided with two support mechanisms, both of the aforementioned support plates are provided with two wheels, both of the aforementioned support plates are connected to limit plates, both of the aforementioned running tracks include a semi-circular track, and the plurality of aforementioned protection mechanisms include a protection placement groove.
[0008] Furthermore, the semicircular track has a T-shaped groove, and the semicircular track is connected to a T-shaped locking block. The T-shaped groove is slightly larger than the T-shaped locking block.
[0009] Furthermore, the protective placement slot is connected to a rotating rod, and the rotating rod is rotatably connected to a first fixing bolt, which is connected to a first locking nut.
[0010] Furthermore, the protective placement groove is provided with a fixing hole, the fixing hole is connected to a second fixing bolt, and the second fixing bolt is connected to a second locking nut.
[0011] Furthermore, the second fixing bolt is provided with a protective plate, the protective plate is connected to a hand handle, and the protective plate is slidably disposed inside the protective placement groove.
[0012] Furthermore, each of the aforementioned support mechanisms includes a through plate, the through plate having two grooves, and each of the two grooves being provided with a through support rod.
[0013] Furthermore, both through-bracing rods are provided with multiple limiting support blocks, and each through-bracing rod is connected to a damping rod.
[0014] Furthermore, the two grooves are a combination of circular and rectangular grooves, and the through support rod and multiple limiting support blocks slide longitudinally inside the grooves.
[0015] Furthermore, the two limiting plates are respectively disposed on the edges of the two support plates.
[0016] Furthermore, multiple of the wheels are concave in shape.
[0017] In summary, the beneficial effects of this utility model are as follows: by adjusting the different angles and lengths of multiple protective mechanisms, the protection of materials stacked on the support plate during transportation is improved, preventing materials from falling off the support plate, increasing the stability of materials stacked in different forms, and ensuring the construction speed.
[0018] By splicing semicircular tracks in the running track and changing the height of the support mechanism, the environmental impact is reduced and the convenience of transportation is improved when workers transport materials through the support plate. Attached Figure Description
[0019] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0020] Figure 1 This is a front view of the present invention;
[0021] Figure 2 This is an axonometric view of the present invention;
[0022] Figure 3 This is a bottom-view axonometric view of the present invention;
[0023] Figure 4 This is an exploded view of the protective mechanism of this utility model;
[0024] Figure 5 This is an isometric view of the support mechanism of this utility model.
[0025] The annotations in the attached figures are explained as follows:
[0026] 1. Support plate; 2. Extension plate; 3. Limiting plate; 4. Fixing opening plate; 5. Limiting bolt; 6. Protection mechanism; 601. First fixing bolt; 602. First locking nut; 603. Rotating rod; 604. Protection placement groove; 605. Fixing hole; 606. Second fixing bolt; 607. Second locking nut; 608. Protection plate; 609. Hand handle; 7. Running track; 701. Semicircular track; 702. T-shaped groove; 703. T-shaped locking block; 8. Support mechanism; 801. Through plate; 802. Slide groove; 803. Through support rod; 804. Damping rod; 805. Limiting support block; 9. Wheel. Detailed Implementation
[0027] To make the objectives, technical solutions, and advantages of this utility model clearer, the technical solutions of this utility model will be described in detail below. Obviously, the described embodiments are only a part of the embodiments of this utility model, and not all of them. Based on the embodiments of this utility model, all other implementation methods obtained by those skilled in the art without creative effort are within the scope of protection of this utility model.
[0028] See Figures 1-3 As shown, this utility model provides an auxiliary device for rapid material transfer inside a template support system, including: two support plates 1 and two running tracks 7. An extension plate 2 and a fixed opening plate 4 are provided between the two support plates 1. A limit bolt 5 is provided through one of the two support plates 1. Two protective mechanisms 6 are provided on each of the two support plates 1. Two support mechanisms 8 are provided on each of the two running tracks 7. Two wheels 9 are provided on each of the two support plates 1. Limit plates 3 are connected to each of the two support plates 1. The two limit plates 3 are respectively provided on the edges of the two support plates 1. The wheels 9 are concave.
[0029] Using the above technical solution, a transport vehicle is formed by two support plates 1 and multiple wheels 9. The upper side of the support plate 1 is used to stack the materials to be transported. The support plate 1 can move above the running track 7 and the wheels 9. The extension plate 2 and the fixed opening plate 4 are connected to one of the two support plates 1, and the other side is recessed inside the other support plate 1. The fixed opening plate 4 is limited by the limit bolt 5 and the hole in the fixed opening plate 4, so as to limit the length of the two support plates 1. The protective mechanism 6 protects the materials stacked on the support plate 1 during transportation to prevent the materials from falling. The limit plate 3 initially limits the bottom of the materials.
[0030] See Figure 4 As shown, each of the multiple protective mechanisms 6 includes a protective placement groove 604. The protective placement groove 604 is connected to a rotating rod 603. The rotating rod 603 is rotatably connected to a first fixing bolt 601. The first fixing bolt 601 is connected to a first locking nut 602. The protective placement groove 604 is provided with a fixing hole 605. The fixing hole 605 is connected to a second fixing bolt 606. The second fixing bolt 606 is connected to a second locking nut 607. The second fixing bolt 606 is provided with a protective plate 608. The protective plate 608 is connected to a hand handle 609. The protective plate 608 is slidably disposed inside the protective placement groove 604.
[0031] In the above embodiment, the protective plate 608 is placed in the protective placement slot 604. Both the protective placement slot 604 and the protective plate 608 have the same function: protecting the stacked materials and preventing them from falling during transportation. The first fixing bolt 601 is fixedly installed on the side of the support plate 1. The rotating rod 603 rotates on the outer surface of the first fixing bolt 601, and the first locking nut 602 clamps or loosens the rotating rod 603 to achieve the purpose of fixing and adjusting. The second fixing bolt 606 is placed through the fixing hole 605. The second locking nut 607 works on the same principle as the first locking nut 602, used to fix and adjust the protective plate 608. Depending on the amount of transported materials stacked, if the materials are stacked high, the protective plate 608 is rotated out to increase the protection height; if the materials are small, the protective placement slot 604 is sufficient.
[0032] See Figure 3 and Figure 5As shown, both of the running tracks 7 include a semi-circular track 701, the semi-circular track 701 having a T-shaped groove 702, the semi-circular track 701 being connected to a T-shaped locking block 703, the T-shaped groove 702 being slightly larger than the T-shaped locking block 703, and the multiple support mechanisms 8 each including a through plate 801, the through plate 801 having two sliding grooves 802, each of the two sliding grooves 802 being provided with a through support rod 803, each of the two through support rods 803 being provided with multiple limiting support blocks 805, each through support rod 803 being connected to a damping rod 804, the two sliding grooves 802 being a combination of circular and rectangular grooves, the through support rod 803 and the multiple limiting support blocks 805 sliding longitudinally inside the sliding groove 802;
[0033] In use, the circular upper part of the semicircular track 701 and the concave design of the wheel 9 limit the wheel 9 during operation, improving the stability of the wheel 9 during transportation. The T-shaped groove 702 and the T-shaped locking block 703 simplify the connection of the two semicircular tracks 701 and increase the connection speed. The through plate 801 directly passes through the lower part of the semicircular track 701, connecting the running track 7 and the support mechanism 8 together. The two sliding grooves 802 provide space for the two through support rods 803. Multiple limiting support blocks 805 are combined in pairs and set on the upper and lower sides of the through support rod 803 respectively. They work with the sliding grooves 802 to limit the through support rod 803. The damping rod 804 provides convenience for the operator to rotate the entire through support rod 803.
[0034] Using the above structure, when using this product, firstly, the staff surveys the site and places the running track 7 and support mechanism 8 in a suitable position. Then, multiple semicircular tracks 701 are spliced together through the T-shaped groove 702 and the protruding T-shaped locking block 703. At this time, the staff holds the damping rod 804 and rotates the through support rod 803, so that the limiting support block 805 on the outside of the through support rod 803 contacts the bottom side of the through plate 801, forming a limiting and support, which facilitates the transportation of materials by the support plate 1 through the wheels 9, without being limited by the site and environment. After the staff places the material on the support plate 1, when the material is long, the distance between the two support plates 1 can be reduced by the extension plate 2. Adjustments are made, and the holes of the fixed perforated plate 4 are penetrated by the limit bolt 5 to restrict the two support plates 1 so that they cannot be pulled apart, thus completing the length adjustment of the support plates. After the materials are stacked, the protection mechanism 6 can be rotated or unfolded at multiple angles according to the angle of the materials to improve the protection effect of the stacked materials. As for the method of using the protection mechanism 6, the angles of the rotating rod 603, the protection placement groove 604 and the protection plate 608 are adjusted by the first locking nut 602 and the second locking nut 607 respectively. By holding the rod 609 with the second fixing bolt 606 as the fulcrum and rotating it, the protection plate 608 is rotated out of the protection placement groove 604 to protect the stacked materials and prevent the materials from falling during transportation.
[0035] The above description is merely a specific embodiment of this utility model, but the protection scope of this utility model is not limited thereto. Any variations or substitutions that can be easily conceived by those skilled in the art within the technical scope disclosed in this utility model should be included within the protection scope of this utility model. Therefore, the protection scope of this utility model should be determined by the protection scope of the claims.
Claims
1. A rapid material transfer auxiliary device within a template support system, characterized in that, include: Two support plates (1) and two running tracks (7), an extension plate (2) and a fixed opening plate (4) are provided between the two support plates (1), a limit bolt (5) is provided through one of the two support plates (1), and two protection mechanisms (6) are provided on both support plates (1). Both of the running tracks (7) are provided with two support mechanisms (8), both of the support plates (1) are provided with two wheels (9), both of the support plates (1) are connected to limit plates (3), both of the running tracks (7) include a semi-circular track (701), and multiple of the protection mechanisms (6) include a protection placement groove (604).
2. The internal material rapid transfer auxiliary device of the formwork support system according to claim 1, characterized in that: The semicircular track (701) has a T-shaped groove (702), and the semicircular track (701) is connected to a T-shaped block (703). The T-shaped groove (702) is slightly larger than the T-shaped block (703).
3. The internal material rapid transfer auxiliary device of the formwork support system according to claim 1, characterized in that: The protective placement slot (604) is connected to a rotating rod (603), and the rotating rod (603) is rotatably connected to a first fixing bolt (601), and the first fixing bolt (601) is connected to a first locking nut (602).
4. The internal material rapid transfer auxiliary device of the formwork support system according to claim 3, characterized in that: The protective placement groove (604) is provided with a fixing hole (605), the fixing hole (605) is connected to a second fixing bolt (606), and the second fixing bolt (606) is connected to a second locking nut (607).
5. The auxiliary device for rapid material transfer within a template support system according to claim 4, characterized in that: The second fixing bolt (606) is provided with a protective plate (608), the protective plate (608) is connected to a hand handle (609), and the protective plate (608) is slidably disposed inside the protective placement groove (604).
6. The internal material fast transfer auxiliary device of a formwork support system according to claim 1, characterized in that: Each of the multiple support mechanisms (8) includes a through plate (801), the through plate (801) having two grooves (802), and each of the two grooves (802) being provided with a through support rod (803).
7. The internal material fast transfer auxiliary device of a formwork support system according to claim 6, characterized in that: Both of the through support rods (803) are provided with multiple limiting support blocks (805), and each of the through support rods (803) is connected to a damping rod (804).
8. The internal material fast transfer auxiliary device of a formwork support system according to claim 7, characterized in that: The two grooves (802) are a combination of circular and rectangular grooves, and the through support rod (803) and multiple limiting support blocks (805) slide longitudinally inside the grooves (802).
9. The internal material fast transfer auxiliary device of the formwork support system according to claim 1, characterized in that: The two limiting plates (3) are respectively set at the edges of the two support plates (1).
10. The internal material fast transfer auxiliary device of a formwork support system according to claim 1, characterized in that: The multiple wheels (9) are concave.