CFG pile foundation cap template
By introducing heat-conducting plates, heat dissipation fins, and air convection structures into the CFG pile foundation cap template, the problem of slow concrete setting caused by poor air permeability was solved, achieving rapid setting and efficient construction.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- BEIJING INT CONSTR GRP
- Filing Date
- 2025-07-23
- Publication Date
- 2026-07-03
AI Technical Summary
The existing CFG pile foundation cap formwork lacks good air permeability, resulting in untimely heat dissipation from the concrete and slow solidification speed.
A CFG pile foundation cap template was designed, which adopts a heat-conducting plate and heat dissipation fin structure, combined with heat dissipation holes, vents and air convection to enhance heat transfer and dissipation efficiency, and simplifies template installation and disassembly through a quick-installation mechanism.
This enabled rapid concrete setting, improved construction efficiency and the reusability of formwork, and ensured the quality and stability of the pile cap.
Smart Images

Figure CN224451610U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of concrete pouring formwork technology, and in particular to a CFG pile foundation cap formwork. Background Technology
[0002] CFG piles are a type of low-strength concrete pile, generally used for reinforcing soft silty foundations. During construction, the CFG piles are first constructed and formed, then the soil between the piles is excavated to expose the CFG pile head. The pile head is then cut, and the pile cap reinforcement is tied. After the tying is completed, the pile cap concrete is poured and the formwork is assembled.
[0003] A search revealed Chinese patent publication number CN221895761U, which discloses a template for casting CFG pile caps. The template includes a template unit comprising two template pieces, each in a semi-circular arc shape and made of steel. The two template pieces are joined end-to-end to form a cylindrical shape. Each template includes a plate body and extending edges. The extending edges include first extending edges along the left and right sides of the plate body, and second extending edges along the upper and lower sides of the plate body, respectively. The extending edges are located on the outer surface of the plate body. Each extending edge has a lifting hole, and the first extending edge has a first connecting hole. Two overlapping first extending edges are detachably connected by first fasteners passing through the two opposite first connecting holes. While the template is not easily deformed during reuse, increasing its reusability, in actual use, due to its lack of good air permeability, it cannot dissipate the heat of the concrete in a timely manner, resulting in slow concrete setting. Utility Model Content
[0004] To overcome the above shortcomings, this utility model provides a CFG pile foundation cap template, which aims to improve the problem in the existing technology that it lacks good air permeability and cannot dissipate the heat of concrete in time, resulting in slow concrete setting speed.
[0005] To achieve the above objectives, the present invention adopts the following technical solution: a CFG pile foundation cap template, comprising two bases, a mold plate fixedly connected to the top of each of the two bases, multiple support plates fixedly connected to adjacent sides of each of the two mold plates, a common heat-conducting plate fixedly connected to the outer wall of each of the multiple support plates, multiple heat dissipation holes opened on the outer wall of each of the two heat-conducting plates, multiple heat dissipation fins fixedly connected to the outer wall of each of the two heat-conducting plates on opposite sides, heat dissipation openings opened on the upper and lower sides of the outer wall of each of the two mold plates, multiple ventilation openings opened on the outer wall of each of the multiple heat dissipation fins, and fixing blocks fixedly connected to the left and right sides of the outer wall of each of the two mold plates, with a quick-installation mechanism provided on the outer wall of the two front fixing blocks.
[0006] Through the above technical solution: two bases serve as the foundation support for the entire CFG pile cap template, firmly placed on the construction ground, providing solid and reliable support for the entire template. This ensures that the template will not shift or tilt during concrete pouring, guaranteeing construction stability. The mold plates fixed to the top of each base play a crucial role in shaping the CFG pile cap. Together, they enclose a space consistent with the shape of the pile cap, ensuring that the pile cap forms a compliant shape after concrete pouring. Multiple support plates fixed to adjacent sides of the two mold plates have a dual function: firstly, they greatly enhance the connection strength between the two mold plates, effectively preventing separation under the pressure of concrete; secondly, they provide necessary mounting points for the heat-conducting plate. The heat-conducting plate, connected to the outer walls of multiple support plates, benefits from its excellent thermal conductivity. It can quickly absorb the heat generated by the hydration reaction of concrete in the mold plate and transfer the heat to a larger area. The multiple holes on the outer wall of the heat-conducting plate further expand the surface area for heat transfer, thereby accelerating the speed of heat transfer from the mold plate to the heat-conducting plate. The multiple heat dissipation fins fixed on the side of the heat-conducting plate away from the mold plate significantly increase the contact area with the air, which can quickly dissipate the heat transferred from the heat-conducting plate into the surrounding air. The multiple ventilation openings on the outer wall of the heat dissipation fins accelerate the airflow between the fins, further improving the heat dissipation effect and allowing the heat to be carried away more efficiently. The heat dissipation openings on the upper and lower sides of the outer wall of the mold plate work together with the heat dissipation fins and ventilation openings. Hot air rises due to its lower density and is discharged from the heat dissipation openings, while external cold air enters from the bottom, thus forming air convection, which enhances the heat dissipation process, ensures that the concrete solidifies well at a suitable temperature, and guarantees the quality of the pile cap.
[0007] As a further description of the above technical solution:
[0008] The quick-release mechanism includes two locking blocks. The front sides of the outer walls of the two locking blocks are respectively fixedly connected to the rear sides of the outer walls of the two front fixing blocks. The front sides of the outer walls of the two rear fixing blocks are each provided with a slot. The two locking blocks are slidably connected to the corresponding slots. The inner walls of the two rear fixing blocks are each provided with a reserved groove. The inner walls of the two reserved grooves are each slidably connected with a locking block. The tops of the two locking blocks are each fixedly connected with a spring. The tops of the two springs are each fixedly connected to the corresponding reserved grooves. The tops of the two locking blocks are each fixedly connected with a pull rod. The tops of the two locking blocks are each provided with a reserved hole. The two locking blocks are respectively engaged with the corresponding reserved holes.
[0009] Through the above technical solution: the front sides of the outer walls of the two locking blocks are fixedly connected to the rear sides of the outer walls of the two front fixed blocks, building a key connecting bridge between the quick-installation mechanism and the main body of the template, enabling the quick-installation mechanism to be closely connected to the template. The slots opened on the front sides of the outer walls of the two rear fixed blocks are adapted to the locking blocks, and the locking blocks are precisely inserted into the slots in a sliding connection manner during template installation, which simplifies the operation process and ensures that the connection position is accurate, realizing the initial docking of the front and rear template parts. The reserved grooves on the inner walls of the two rear fixed blocks provide an active area for the locking blocks. The locking blocks slide with the inner walls of the reserved grooves, and the upper end of the spring connected to the top of the locking block is fixed to the top of the reserved groove. The spring gives the locking blocks an upward elastic force, allowing the locking blocks to... The automatic pop-out function creates conditions for locking the template connection. The pull rod fixed to the top of the locking block provides the operator with a point of force to manually operate the locking block. When the template needs to be disassembled, the operator can pull the pull rod to overcome the spring force and make the locking block disengage from the reserved hole, which facilitates the subsequent separation of template components. The reserved hole on the top of the locking block cleverly engages with the pop-out locking block after the template is installed. At this time, under the action of the spring, the locking block is tightly embedded in the reserved hole, firmly locking the front and rear fixing blocks. This ensures that the entire template remains stable and reliable under the action of external construction forces such as concrete pouring, without loosening. This effectively ensures the smooth progress of the CFG pile foundation cap pouring and forming work, and ensures construction quality and efficiency.
[0010] As a further description of the above technical solution:
[0011] Multiple limiting rods are fixedly connected to the left and right sides of the rear end of the outer wall of the front base, and multiple limiting grooves are opened on the left and right sides of the front end of the outer wall of the rear base. The multiple limiting rods are slidably connected to the corresponding limiting grooves.
[0012] The above technical solution allows the limiting rod to slide into the limiting groove, thus enabling the limiting rod to be inserted into the corresponding limiting groove and playing a preliminary connection and fixation role.
[0013] As a further description of the above technical solution:
[0014] The top of both bases is provided with multiple positioning holes, and the inner walls of the multiple positioning holes are slidably connected with bolts.
[0015] The above technical solution involves positioning holes on the top of the two bases, which cooperate with the sliding connection bolts to accurately position and fix the bases during installation.
[0016] As a further description of the above technical solution:
[0017] Both of the pull rods have a pull ring slidably connected to their tops, and the surfaces of both pull rings are smoothed.
[0018] The above technical solution involves sliding connections between the tops of the two pull rods and smooth-surfaced pull rings, allowing operators to easily grasp the pull rings and pull the rods to disassemble the quick-release mechanism.
[0019] As a further description of the above technical solution:
[0020] Each of the multiple positioning holes has a washer fixedly connected to its inner wall, and the multiple bolts pass through the corresponding washer.
[0021] The above technical solution involves using a gasket to protect the bolt and prevent it from directly contacting the locating hole, thus avoiding wear on the bolt surface.
[0022] As a further description of the above technical solution:
[0023] The inner walls of the two mold plates are provided with the same sealing ring, and the outer walls of the sealing ring are respectively attached to the two mold plates and the heat-conducting plate.
[0024] The above technical solution involves sealing rings on the inner walls of the two mold plates, which fit together with the mold plates and heat-conducting plates to prevent concrete slurry leakage and ensure the quality of pile cap forming.
[0025] As a further description of the above technical solution:
[0026] Both bases are fixedly connected to a sealing gasket at their bottom, and the bottoms of the sealing gaskets are treated with anti-slip material.
[0027] Through the above technical solution, the sealing gasket can ensure that the base and the mounting surface fit tightly, and fill the gap between the base and the mounting surface with its high resilience.
[0028] This utility model has the following beneficial effects:
[0029] 1. In this utility model, two bases cooperate with the top mold plate to stably support and shape the pile cap. The support plate connects to the mold plate and provides an installation position for the heat-conducting plate. The heat-conducting plate and its holes quickly absorb and transfer heat. The heat dissipation fins and vents increase the heat dissipation area and air circulation, accelerating heat dissipation. The heat dissipation vents work together to form air convection. The quick-installation mechanism and fixing block facilitate installation and disassembly. Through the cooperation of these structures, efficient heat dissipation is achieved, improving the problems of poor air permeability, untimely heat dissipation, and slow concrete curing in the prior art.
[0030] 2. In this utility model, during installation, the locking block is slidably inserted into the slot, and the locking block engages with the reserved hole under the action of the spring, so that the template is stably connected and can withstand the external force of construction. During disassembly, the pull rod is pulled to drive the locking block out of the reserved hole, and the locking block is pulled out to separate the fixing block, which facilitates the cleaning, transportation and reuse of the template, greatly improving construction efficiency and the convenience of template use. Attached Figure Description
[0031] Figure 1 This is a perspective view of a CFG pile foundation cap template proposed in this utility model;
[0032] Figure 2 This is a front view of a CFG pile foundation cap template proposed in this utility model;
[0033] Figure 3 This is a partial structural breakdown diagram of a CFG pile foundation cap template proposed in this utility model;
[0034] Figure 4 This is a schematic diagram of a quick-assembly mechanism for a CFG pile foundation cap template proposed in this utility model;
[0035] Figure 5 This is a schematic diagram of the positioning holes for a CFG pile foundation cap template proposed in this utility model.
[0036] Legend:
[0037] 1. Base; 2. Quick-release mechanism; 201. Locking block; 202. Slot; 203. Reserved slot; 204. Locking block; 205. Spring; 206. Pull rod; 207. Reserved hole; 3. Mold plate; 4. Support plate; 5. Heat-conducting plate; 6. Heat dissipation holes; 7. Heat dissipation fins; 8. Heat dissipation vent; 9. Ventilation vent; 10. Fixing block; 11. Limiting rod; 12. Limiting groove; 13. Positioning hole; 14. Bolt; 15. Pull ring; 16. Sealing ring; 17. Gasket; 18. Sealing pad. Detailed Implementation
[0038] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0039] Reference Figure 1 , Figure 2 and Figure 3This utility model provides an embodiment of a CFG pile cap template, comprising two bases 1 to provide stable support for the entire CFG pile cap template. A mold plate 3 is fixedly connected to the top of each of the two bases 1 for shaping the pile cap. Multiple support plates 4 are fixedly connected to adjacent sides of the two mold plates 3 to enhance the connection strength between the mold plates 3. A common heat-conducting plate 5 is fixedly connected to the outer wall of each of the multiple support plates 4, which can quickly absorb the heat generated by the concrete inside the mold plate 3. Multiple heat dissipation holes 6 are provided on the outer wall of each of the two heat-conducting plates 5 to quickly absorb the heat generated by the concrete inside the mold plate 3. The heat generated is dissipated by multiple heat dissipation fins 7 fixedly connected to the outer walls of the two heat conduction plates 5 on opposite sides to increase the contact area with air. Heat dissipation vents 8 are opened on the upper and lower sides of the outer walls of the two mold plates 3. Multiple ventilation openings 9 are opened on the outer walls of the multiple heat dissipation fins 7. The heat dissipation vents 8, heat dissipation fins 7, and ventilation openings 9 work together to form air convection and enhance heat dissipation. Fixing blocks 10 are fixedly connected to the left and right sides of the outer walls of the two mold plates 3. With the quick-installation mechanism 2 on the outer walls of the two front fixing blocks 10, the template can be quickly assembled and disassembled. The quick-installation mechanism 2 is provided on the outer walls of the two front fixing blocks 10.
[0040] Specifically, the two bases 1 serve as the basic support structure, firmly placed on the construction ground to provide reliable support for the entire formwork, ensuring that the formwork will not shift or tip over during concrete pouring. The mold plate 3 fixedly connected to the top of each base 1 is a key component in shaping the CFG pile cap. Together, they enclose a space that conforms to the shape of the pile cap, ensuring that the pile cap of the specified shape can be formed after the concrete is poured. Multiple support plates 4 fixed on the adjacent side of the two mold plates 3 not only enhance the connection strength between the two mold plates 3 and prevent the mold plates 3 from separating under concrete pressure, but also provide an installation attachment point for the heat-conducting plate 5. The heat-conducting plate 5, which is connected to the outer wall of the multiple support plates 4, has good heat conduction performance. It can quickly absorb the heat generated by the hydration reaction of the concrete inside the mold plate 3 and conduct it through... The heat transfer plate 5 transfers heat to a larger area through its own heat transfer. The multiple heat dissipation holes 6 on the outer wall of the heat transfer plate 5 further increase the surface area for heat transfer, accelerating the speed at which heat is transferred from the mold plate 3 to the heat transfer plate 5. The multiple heat dissipation fins 7 fixed on the side of the heat transfer plate 5 away from the mold plate 3 significantly increase the contact area with the air. These heat dissipation fins 7 quickly dissipate the heat transferred from the heat transfer plate 5 into the surrounding air. The multiple ventilation holes 9 on the outer wall of the heat dissipation fins 7 accelerate the flow of air between the fins, further improving the heat dissipation effect and allowing the heat to be carried away more efficiently. The heat dissipation holes 8 on the upper and lower sides of the outer wall of the mold plate 3 work together with the heat dissipation fins 7 and ventilation holes 9. Hot air rises due to its lower density and is discharged from the heat dissipation holes 8, while external cold air enters from the bottom, forming air convection and enhancing the heat dissipation process.
[0041] Reference Figure 1 , Figure 3 and Figure 4 The quick-installation mechanism 2 includes two locking blocks 201, which form the basis for connecting the quick-installation mechanism 2 to the template body. The front sides of the outer walls of the two locking blocks 201 are fixedly connected to the rear sides of the outer walls of the two front fixing blocks 10. The front sides of the outer walls of the two rear fixing blocks 10 are each provided with a slot 202. The two locking blocks 201 are slidably connected to the corresponding slots 202. The slots 202 correspond to the locking blocks 201. During installation, the locking blocks 201 can slide into the slots 202 to ensure accurate connection and initial docking of the front and rear template components. The inner walls of the two rear fixing blocks 10 are each provided with a reserved groove 203. The inner walls of the two reserved grooves 203 are slidably connected with locking blocks 204, providing movement space for the locking blocks 204. Springs 205 are fixedly connected to the top of each of the two locking blocks 204. The upper end of each locking block 204 is fixed to the top of the reserved slot 203. Springs 205 provide upward elastic force to the locking blocks 204, enabling them to automatically pop out. The tops of the two springs 205 are fixedly connected to the corresponding reserved slots 203. Pull rods 206 are fixedly connected to the tops of the two locking blocks 204. Pull rods 206 are fixedly connected to the locking blocks 204. Therefore, pulling pull rods 206 can drive the locking blocks 204 to move. When pulling pull rods 206, it is necessary to overcome the elastic force of springs 205 so that the locking blocks 204 can disengage from the reserved holes 207 and retract into the reserved slots 203. The tops of the two locking blocks 201 are provided with reserved holes 207. The two locking blocks 204 are respectively locked into the corresponding reserved holes 207.
[0042] Specifically, the front outer walls of the two locking blocks 201 are fixedly connected to the rear outer walls of the two front fixing blocks 10, respectively. This connection provides the quick-assembly mechanism 2 with a connection point to the template body. The slots 202 on the front outer walls of the two rear fixing blocks 10 correspond to the locking blocks 201, and the two are slidably connected. During template installation, the locking blocks 201 can be precisely inserted along the slots 202. This design not only facilitates operation but also ensures the accuracy of the connection position, initially connecting the front and rear template parts. The reserved grooves 203 on the inner walls of the two rear fixing blocks 10 provide movement space for the locking blocks 204. The locking blocks 204 are slidably connected to the inner walls of the reserved grooves 203, and the springs 205 fixedly connected to their tops are also fixed to the top of the reserved grooves 203. The springs 205 provide upward support for the locking blocks 204. The elastic force enables it to pop out automatically. The pull rod 206 fixedly connected to the top of the locking block 204 provides the operator with a point of force to manually control the locking block 204. When it is necessary to disassemble the template, the operator pulls the pull rod 206 to overcome the elastic force of the spring 205, so that the locking block 204 can be disengaged from the reserved hole 207, which facilitates the subsequent separation of template components. The reserved hole 207 opened at the top of the locking block 201 engages with the popped-out locking block 204 after the template is installed in place. At this time, the locking block 204 is tightly embedded in the reserved hole 207 under the action of the spring 205, which firmly locks the front and rear fixing blocks 10 together, ensuring that the entire template will not loosen due to external forces during the concrete pouring and other construction processes, thus ensuring the stability and reliability of the template structure and successfully completing the pouring and forming of the CFG pile cap.
[0043] Reference Figure 1 , Figure 2 and Figure 4 Multiple limiting rods 11 are fixedly connected to the left and right sides of the rear end of the outer wall of the front base 1. Multiple limiting grooves 12 are opened on the left and right sides of the front end of the outer wall of the rear base 1. The multiple limiting rods 11 are slidably connected to the corresponding limiting grooves 12 to initially connect the two bases 1. Multiple positioning holes 13 are opened on the top of the two bases 1 to accurately position and fix the bases 1 during installation. Bolts 14 are slidably connected to the inner walls of the multiple positioning holes 13. Pull rings 15 are slidably connected to the top of the two pull rods 206. The surfaces of the two pull rings 15 are smoothed to facilitate the operator to grip and pull the pull rods 206.
[0044] Specifically, the limiting rod 11 is slidably connected to the limiting groove 12, so that the limiting rod 11 can be inserted into the corresponding limiting groove 12, which plays a role in initial connection and fixation. The positioning holes 13 on the top of the two bases 1 cooperate with the slidingly connected bolts 14 to accurately position and fix the bases 1 during installation. The top of the two pull rods 206 is slidably connected to the smooth pull rings 15, which makes it convenient for the operator to grasp and pull the pull rods 206 to realize the disassembly operation of the quick-installation mechanism 2.
[0045] Reference Figure 1 , Figure 3 and Figure 5 The inner walls of multiple positioning holes 13 are all fixedly connected with gaskets 17 to prevent the bolts 14 from wearing out. Multiple bolts 14 pass through the corresponding gaskets 17. The inner walls of the two mold plates 3 are provided with the same sealing ring 16 to prevent concrete slurry leakage. The outer walls of the sealing ring 16 are respectively attached to the two mold plates 3 and the heat-conducting plate 5. The bottoms of the two bases 1 are all fixedly connected with sealing gaskets 18, and the bottoms of multiple sealing gaskets 18 are all treated with anti-slip treatment.
[0046] Specifically, the gaskets 17 inside the multiple positioning holes 13 can prevent the ends of the bolts 14 from directly contacting the base 1, protect the bolts 14, and prevent the bolts 14 from being severely worn. The sealing rings 16 on the inner walls of the two mold plates 3 fit with the mold plates 3 and the heat-conducting plate 5, which can prevent concrete slurry leakage and ensure the quality of the pile cap forming. The sealing gaskets 18 can fill the gap between the base 1 and the mounting surface to prevent concrete leakage during pouring.
[0047] Working Principle: Two bases 1 serve as the basic support structure, stably supporting the components above. A mold plate 3, fixedly connected to the top, is used to shape the CFG pile cap. Multiple support plates 4, fixed to adjacent sides of the mold plate 3, strengthen the connection between the mold plates 3 and provide an installation base for the heat-conducting plate 5. The heat-conducting plate 5 is a key component for heat transfer; it is fixedly connected to the multiple support plates 4 and can quickly absorb the heat generated by the concrete inside the mold plate 3. Multiple heat dissipation holes 6 on the outer wall of the heat-conducting plate 5 increase the heat exchange area and accelerate heat transfer from the mold plate 3 to the heat-conducting plate 5. Multiple heat dissipation fins 7, fixed to the side of the outer wall of the heat-conducting plate 5 away from each other, further increase the heat dissipation area. The design of the heat dissipation fins 7... The design effectively dissipates the heat absorbed by the heat-conducting plate 5 into the surrounding air. Multiple ventilation openings 9 on the heat dissipation fins 7 allow air to circulate better between the fins, carrying away heat and greatly improving heat dissipation efficiency. The heat dissipation openings 8 on the upper and lower sides of the outer wall of the mold plate 3 work together with the heat dissipation fins 7 and ventilation openings 9. Hot air rises and is discharged through the heat dissipation openings 8, while external cold air enters from the bottom, forming air convection and accelerating heat dissipation. The fixing blocks 10 fixed on the left and right sides of the outer wall of the mold plate 3 and the quick-installation mechanism 2 set on the outer wall of the two fixing blocks 10 on the front side not only facilitate the installation and disassembly of the template and improve construction efficiency, but also ensure the tightness of the entire structure after the template is assembled and installed, avoiding uneven heat dissipation due to gaps.
[0048] The two locking blocks 201 are placed at the connection positions of the two front fixing blocks 10 and the two rear fixing blocks 10, respectively. Since the locking blocks 201 are fixed to the rear side of the outer wall of the front fixing block 10, during installation, it is only necessary to align them with the slot 202 on the front side of the outer wall of the rear fixing block 10, push the front fixing block 10, and let the locking blocks 201 slide into the slot 202. This step initially connects the front and rear parts of the template. During this process, the slot 202 provides guidance for the locking blocks 201 to ensure the accuracy of the connection position. As the locking blocks 201 are gradually inserted, the top of the locking blocks 201 approaches the reserved groove 203 on the inner wall of the rear fixing block 10. At this time, the locking block 204, which is subjected to the upward elastic force of the spring 205 in the reserved groove 203, will automatically fall into the reserved hole 207 opened on the top of the locking blocks 201 when the locking blocks 201 reach the appropriate position. Here, the spring 205 provides a continuous upward force to the locking block 204, making It can engage with the reserved hole 207 in a timely manner. After the locking block 204 successfully engages with the reserved hole 207, a stable connection is formed between the front and rear fixing blocks 10, so that the two mold plates 3 are tightly connected through the quick-installation mechanism 2 to complete the template installation, ensuring the structural stability of the template during use and being able to withstand external forces during construction processes such as concrete pouring. During disassembly, the operator grasps the pull rod 206, which is fixedly connected to the locking block 204. Therefore, pulling the pull rod 206 can drive the locking block 204 to move. When the pull rod 206 is driven, the elastic force of the spring 205 needs to be overcome so that the locking block 204 can disengage from the reserved hole 207 and retract into the reserved groove 203. After the locking block 204 disengages from the reserved hole 207, the locking state between the locking block 201 and the rear fixing block 10 is released. At this time, the locking block 201 can be pulled out from the slot 202, thereby separating the front and rear fixing blocks 10 and realizing the disassembly of the template, which is convenient for subsequent cleaning, transportation or reuse of the template.
[0049] Finally, it should be noted that the above are merely preferred embodiments of the present utility model and are not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.
Claims
1. A CFG pile foundation cap template, comprising two bases (1), characterized in that: The top of each of the two bases (1) is fixedly connected to a mold plate (3), and a plurality of support plates (4) are fixedly connected to adjacent sides of each of the two mold plates (3). The outer walls of the plurality of support plates (4) are fixedly connected to the same heat-conducting plate (5). The outer walls of the two heat-conducting plates (5) are provided with a plurality of heat dissipation holes (6). The outer walls of the two heat-conducting plates (5) are fixedly connected to a plurality of heat dissipation fins (7) on opposite sides. The upper and lower sides of the outer walls of the two mold plates (3) are provided with heat dissipation openings (8). The outer walls of the plurality of heat dissipation fins (7) are provided with a plurality of ventilation openings (9). The left and right sides of the outer walls of the two mold plates (3) are fixedly connected to fixing blocks (10). The outer walls of the two front fixing blocks (10) are provided with quick-installation mechanisms (2).
2. A CFG pile cap form according to claim 1, characterised in that: The quick-release mechanism (2) includes two locking blocks (201). The front sides of the outer walls of the two locking blocks (201) are respectively fixedly connected to the rear sides of the outer walls of the two front fixing blocks (10). The front sides of the outer walls of the two rear fixing blocks (10) are each provided with a slot (202). The two locking blocks (201) are respectively slidably connected to the corresponding slots (202). The inner walls of the two rear fixing blocks (10) are each provided with a reserved groove (203). The inner walls of each are slidably connected with a locking block (204), and the top of each locking block (204) is fixedly connected with a spring (205). The top of each spring (205) is fixedly connected to the corresponding reserved slot (203). The top of each locking block (204) is fixedly connected with a pull rod (206). The top of each locking block (201) is provided with a reserved hole (207), and the two locking blocks (204) are respectively engaged with the corresponding reserved hole (207).
3. The CFG pile cap formwork according to claim 1, wherein: Multiple limiting rods (11) are fixedly connected to the left and right sides of the rear end of the outer wall of the front base (1), and multiple limiting grooves (12) are opened on the left and right sides of the front end of the outer wall of the rear base (1). The multiple limiting rods (11) are slidably connected to the corresponding limiting grooves (12).
4. The CFG pile cap formwork according to claim 1, wherein: The top of each of the two bases (1) is provided with multiple positioning holes (13), and the inner walls of the multiple positioning holes (13) are slidably connected with bolts (14).
5. The CFG pile cap formwork according to claim 2, wherein: Both of the pull rods (206) have a pull ring (15) slidably connected to their tops, and the surfaces of both pull rings (15) are smoothed.
6. A CFG pile cap form according to claim 4, wherein: The inner walls of the multiple positioning holes (13) are fixedly connected with gaskets (17), and the multiple bolts (14) pass through the corresponding gaskets (17).
7. The CFG pile cap formwork according to claim 1, wherein: The inner walls of the two mold plates (3) are provided with the same sealing ring (16), and the outer walls of the sealing ring (16) are respectively attached to the two mold plates (3) and the heat-conducting plate (5).
8. The CFG pile cap formwork according to claim 1, wherein: Both bases (1) are fixedly connected to a sealing gasket (18) at their bottoms, and the bottoms of the multiple sealing gaskets (18) are treated with anti-slip treatment.