Foldable assembly type formwork intelligent support frame
The foldable prefabricated intelligent support frame for formwork, designed with threaded connections and reinforcement components, combined with pressure sensors and buzzer alarms, solves the problem that traditional support frames cannot monitor load changes in real time. It enables rapid assembly, enhanced stability, and safety early warning, thereby reducing construction risks.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ZHONGYIFENG CONSTR GRP
- Filing Date
- 2025-07-18
- Publication Date
- 2026-07-14
AI Technical Summary
Traditional formwork support frames lack intelligent monitoring and early warning functions, making it impossible to monitor load changes in real time. This makes it difficult for construction workers to detect potential safety hazards in a timely manner, increasing construction risks.
A foldable prefabricated intelligent support frame for formwork was designed. It adopts threaded connections and reinforcement components, combined with pressure sensors and buzzer alarms, to achieve real-time monitoring and early warning of load.
It enables rapid erection and dismantling of the support frame, improves construction efficiency, enhances stability, provides timely warnings to avoid instability and collapse accidents, and ensures construction safety.
Smart Images

Figure CN224495812U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the technical field of template support frame, and more specifically, it relates to a foldable assembled intelligent template support frame. Background Technology
[0002] In the field of construction engineering, formwork support frames are key facilities to ensure the quality and safety of concrete structure construction. They are widely used in the construction of beams, slabs, columns and other structures in various building projects. Traditional formwork support frames are usually built on site using materials such as steel pipes and fasteners. Although this support method has a certain degree of versatility and flexibility, it has exposed many problems in practical applications.
[0003] Traditional support frames lack intelligent monitoring and early warning functions. During construction, the support frame bears huge loads generated by concrete pouring, etc. If the load exceeds the support frame's bearing capacity, it may lead to serious accidents such as instability and collapse of the support frame. However, since traditional support frames cannot monitor load changes in real time, construction personnel find it difficult to detect potential safety hazards in time, thereby increasing construction risks. Utility Model Content
[0004] To address the aforementioned technical problems, this utility model provides a foldable prefabricated intelligent support frame for formwork, thereby resolving the issue raised in the background section that traditional support frames cannot monitor load changes in real time, making it difficult for construction workers to promptly detect potential safety hazards.
[0005] This utility model of a foldable prefabricated intelligent support frame for templates is achieved through the following specific technical means:
[0006] A foldable prefabricated intelligent support frame for templates includes a base; a support column A is fixedly installed on the top of the base, and a threaded cylinder A is fixedly installed on the top of the support column A, with a threaded column A connected inside the threaded cylinder A via a threaded connection; a support column B is fixedly installed on the top of the threaded column A, and both the support column B and the support column A are hollow structures, with a threaded cylinder B fixedly installed on the top of the support column B; a threaded column B is connected inside the threaded cylinder B via a threaded connection, and a support frame is fixedly installed on the top of the threaded column B; the support frame is U-shaped, and two sets of support frames, support columns A and B are provided;
[0007] A reinforcing component is provided between the two sets of support columns A, and there are two reinforcing components, with another one provided between the two sets of support columns B; an auxiliary structure is fixedly provided between the two sets of support frames.
[0008] In at least some embodiments, through holes are provided inside both sides of the support frame, and locking bolts are movably installed inside the through holes, and the locking bolts and through holes are arranged symmetrically; positioning holes are provided inside both support column A and support column B.
[0009] In at least some embodiments, the reinforcement component includes: a reinforcement base, a positioning post, and a fixing base; the reinforcement base is movably disposed on the outside of the support post A and the support post B, and the reinforcement base is configured as an arc-shaped structure; the positioning post is fixedly disposed inside the reinforcement base and is movably disposed inside the positioning hole; the fixing base is fixedly disposed on the outside of the reinforcement base, and both the fixing base and the reinforcement base are symmetrically arranged in two sets.
[0010] In at least some embodiments, the reinforcement assembly further includes: a tensioning barrel, a tensioning screw, and a knob; the tensioning barrel is rotatably disposed inside a set of fixed seats; the tensioning screw is rotatably disposed inside another set of fixed seats, and the tensioning screw is threadedly connected to the inside of the tensioning barrel; the knob is fixedly disposed outside the tensioning barrel.
[0011] In at least some embodiments, the auxiliary structure includes: a supporting top plate, threaded holes, a folding seat A, a folding seat B, and a connecting shaft; the supporting top plate is movably disposed inside the support frame, and two sets of supporting top plates are provided; the threaded holes are opened inside both sides of the supporting top plate, and locking bolts are provided inside the threaded holes through threaded connections; the folding seat A is fixedly disposed at the bottom of one set of supporting top plates; the folding seat B is fixedly disposed at the bottom of the other set of supporting top plates; the connecting shaft is fixedly disposed inside the folding seat A, and the connecting shaft is rotatably disposed inside the folding seat B.
[0012] In at least some embodiments, the auxiliary structure further includes: a pressure sensor, a control module, and a buzzer alarm; the pressure sensor is fixedly disposed inside the top side of the supporting top plate, and the upper surface of the pressure sensor is flush with the upper surface of the supporting top plate; the control module is fixedly disposed at the bottom of the supporting top plate, and the control module and the pressure sensor are electrically connected; the buzzer alarm is fixedly disposed at the bottom of the supporting top plate, and the buzzer alarm and the control module are electrically connected.
[0013] Compared with the prior art, the present invention has the following beneficial effects:
[0014] 1. In this utility model, the components are combined in a convenient way through threaded connections, movable settings, etc.; at the construction site, construction personnel do not need to perform complicated steel pipe splicing and fastening operations. They only need to assemble the base, support column A, support column B, support frame and other components in sequence according to the preset connection method to quickly complete the construction of the intelligent support frame; similarly, during disassembly, the components can be quickly separated, which greatly shortens the construction preparation and finishing time, improves construction efficiency, and is especially suitable for projects with tight schedules.
[0015] 2. In this utility model, the supporting top plate has a foldable feature. When not in use, the two sets of supporting top plates can be folded through the folding seat A and the connecting shaft to reduce their storage area. This not only facilitates the transportation and storage of the intelligent support frame and reduces transportation costs, but also allows for the reasonable storage of more intelligent support frames in the limited space of the construction site.
[0016] 3. In this utility model, the reinforcing components set between the two sets of support columns A and between the two sets of support columns B effectively enhance the overall stability of the intelligent support frame; the reinforcing base adopts an arc-shaped structure, which can better fit the outer side of support column A and support column B, and the connection between the reinforcing base and support column A and support column B is ensured by the cooperation of the positioning column and positioning hole; the combination design of the tensioning cylinder, tensioning screw and knob can further tighten the two sets of reinforcing bases, making support column A and support column B more stable and preventing the support frame from shaking or deforming when bearing load.
[0017] 4. In this utility model, the pressure sensor installed in the auxiliary structure can monitor the load borne by the supporting top plate in real time and transmit the monitoring data to the control module. The control module analyzes and judges the data transmitted by the pressure sensor. When the load exceeds the preset safety threshold, the control module will immediately trigger the buzzer alarm to issue an alarm signal, reminding the construction personnel to take timely measures, such as reducing the load and reinforcing the support frame, to avoid safety accidents such as instability and collapse of the support frame due to overload, effectively ensuring the safety of the construction personnel and the smooth progress of the project. Attached Figure Description
[0018] Figure 1 This is a schematic diagram of the overall structure of this utility model.
[0019] Figure 2 This is a structural schematic diagram of support column A and support column B of this utility model.
[0020] Figure 3 This is a structural schematic diagram of the reinforcement component of this utility model.
[0021] Figure 4 This is a schematic diagram of the lower surface structure of the support frame of this utility model.
[0022] Figure 5 This is a schematic diagram of the auxiliary structure of this utility model.
[0023] Figure 6 This is a schematic diagram of the folding structure of the two sets of supporting top plates of this utility model.
[0024] In the diagram, the correspondence between component names and drawing numbers is as follows:
[0025] 1. Base; 101. Support column A; 102. Threaded cylinder A; 103. Threaded column A; 104. Support column B; 105. Threaded cylinder B; 106. Threaded column B; 107. Support frame; 108. Through hole; 109. Locking bolt; 1010. Positioning hole;
[0026] 2. Reinforcing components; 201. Reinforcing base; 202. Positioning post; 203. Fixing base; 204. Tensioning screw; 205. Tensioning screw; 206. Knob;
[0027] 3. Auxiliary structure; 301. Support top plate; 302. Threaded hole; 303. Folding seat A; 304. Folding seat B; 305. Connecting shaft; 306. Pressure sensor; 307. Control module; 308. Buzzer alarm. Detailed Implementation
[0028] The embodiments of this utility model will be described in further detail below with reference to the accompanying drawings and examples.
[0029] Example 1: As shown in the attached document Figure 1 To be continued Figure 6 As shown:
[0030] This utility model provides a foldable prefabricated template intelligent support frame, including a base 1; a support column A101 is fixedly installed on the top of the base 1, and a threaded cylinder A102 is fixedly installed on the top of the support column A101, and a threaded column A103 is installed inside the threaded cylinder A102 via a threaded connection; a support column B104 is fixedly installed on the top of the threaded column A103, and both the support column B104 and the support column A101 are hollow structures, and a threaded cylinder B105 is fixedly installed on the top of the support column B104; a threaded column B106 is installed inside the threaded cylinder B105 via a threaded connection, and a support frame 107 is fixedly installed on the top of the threaded column B106; the support frame 107 is U-shaped, and two sets of support frame 107, support column A101, and support column B104 are provided;
[0031] In this embodiment, a reinforcing component 2 is provided between the two sets of support columns A101, and there are two reinforcing components 2, with another one provided between the two sets of support columns B104; an auxiliary structure 3 is fixedly provided between the two sets of support frames 107; through holes 108 are opened inside both sides of the support frame 107, and locking bolts 109 are movably installed inside the through holes 108, and the locking bolts 109 and the through holes 108 are symmetrically arranged; positioning holes 1010 are opened inside both support columns A101 and support columns B104; the specific function is that the components are combined in a convenient way through threaded connection, movable setting, etc.; at the construction site, the construction personnel do not need to perform complicated steel pipe splicing and fastening operations, but only need to assemble the base 1, support column A101, support column B104, support frame 107 and other components in sequence according to the preset connection method to quickly complete the construction of the intelligent support frame.
[0032] Example 2: As shown in the attached document Figure 1 With appendix Figure 3 As shown: Based on Embodiment 1, the reinforcement component 2 includes: a reinforcement base 201, a positioning post 202, a fixing base 203, a tensioning screw 204, a tensioning screw 205, and a knob 206; the reinforcement base 201 is movably disposed on the outside of the support post A101 and the support post B104, and the reinforcement base 201 is configured with an arc-shaped structure; the positioning post 202 is fixedly disposed inside the reinforcement base 201, and the positioning post 202 is movably disposed inside the positioning hole 1010; the fixing base 203 is fixedly disposed on the outside of the reinforcement base 201, and the fixing base 203 is fixedly disposed on the outside of the reinforcement base 201, and the fixing base 203 is fixedly disposed on the outside of the reinforcement base 201, and the fixing base 203 is fixedly disposed on the outside of the reinforcement base 201, and the fixing base 203 is fixedly disposed on the outside of the support post A101 and the fixing base 206 ... The fixed base 203 and the reinforcing base 201 are both arranged in two symmetrical sets; the tensioning screw cylinder 204 is rotatably disposed inside one set of fixed bases 203; the tensioning screw 205 is rotatably disposed inside the other set of fixed bases 203, and the tensioning screw 205 is disposed inside the tensioning screw cylinder 204 through a threaded connection; the knob 206 is fixedly disposed on the outside of the tensioning screw cylinder 204; its specific function is: the reinforcing component 2 disposed between the two sets of support columns A101 and between the two sets of support columns B104 effectively enhances the overall stability of the intelligent support frame.
[0033] Example 3: As shown in the attached document Figure 5 With appendix Figure 6As shown: Based on Embodiments 1 and 2, the auxiliary structure 3 includes: a supporting top plate 301, threaded holes 302, folding seats A 303 and B 304, a connecting shaft 305, a pressure sensor 306, a control module 307, and a buzzer alarm 308; the supporting top plate 301 is movably disposed inside the support frame 107, and two sets of supporting top plates 301 are provided; the threaded holes 302 are opened inside both sides of the supporting top plate 301, and locking bolts 109 are provided inside the threaded holes 302 through threaded connections; the folding seat A 303 is fixedly disposed at the bottom of one set of supporting top plates 301; the folding seat B 304 is fixedly disposed at the bottom of the other set of supporting top plates 301; the connecting shaft 305 is fixedly disposed inside the folding seat A 303, and the connecting shaft 305 is rotatably disposed inside the folding seat B 304; the pressure sensor 306 is fixedly disposed on the supporting top plate 301. The pressure sensor 306 is installed inside the top side of the top plate 301, and its upper surface is flush with the upper surface of the supporting top plate 301. The control module 307 is fixedly installed at the bottom of the supporting top plate 301, and the control module 307 and the pressure sensor 306 are electrically connected. The buzzer alarm 308 is fixedly installed at the bottom of the supporting top plate 301, and the buzzer alarm 308 and the control module 307 are electrically connected. Its specific function is as follows: the pressure sensor 306 installed in the auxiliary structure 3 can monitor the load borne by the supporting top plate 301 in real time and transmit the monitoring data to the control module 307. The control module 307 analyzes and judges the data transmitted by the pressure sensor 306. When the load exceeds the preset safety threshold, the control module 307 will immediately trigger the buzzer alarm 308 to issue an alarm signal to remind the construction personnel to take timely measures.
[0034] The specific usage and function of this embodiment are as follows:
[0035] In this invention, the base 1 is placed stably in the predetermined construction position to ensure the ground is firm and flat. The support column A101 and support column B104 are fixedly connected via threaded cylinder A102 and threaded post A103. Then, the support frame 107 is fixed via threaded post B106 and threaded cylinder B105. A set of arc-shaped reinforcing seats 201 are fitted over the outside of a set of support columns A101, aligning the positioning post 202 inside the reinforcing seat 201 with the positioning hole 1 inside the support column A101. 010. Gently push the reinforcing base 201 to insert the positioning post 202 into the positioning hole 1010, ensuring that the reinforcing base 201 and the support post A101 are initially positioned; then rotate the tensioning screw 204 by the knob 206. The tensioning screw 204 drives the other set of reinforcing bases 201 to move through the tensioning screw 205, so that the reinforcing base 201 is in contact with the other set of support posts A101, thus fixing the reinforcing component 2 between the two sets of support posts A101; install the reinforcing component 2 on the outside of the two sets of support posts B104 in the same way. The component 2 is fixed to enhance the stability of support columns A101 and B104. The support top plate 301 is placed inside the support frame 107, and the locking bolt 109 is passed through the through hole 108 and screwed into the threaded hole 302 to fix the support top plate 301. During construction processes such as concrete pouring, the pressure sensor 306 in the auxiliary structure 3 will monitor the load borne by the support top plate 301 in real time and transmit the monitoring data to the control module 307. The control module 307 will analyze and judge the received data, and the construction personnel can check the load status at any time through the connected display device such as the display screen. When the load exceeds the preset safety threshold, the control module 307 will immediately trigger the buzzer alarm 308 to issue an alarm signal. After hearing the alarm, the construction personnel should immediately stop the current construction operation, check the stress status of the intelligent support frame, and take corresponding measures. The two sets of support top plates 301 can be folded through the folding seat A303, folding seat B304 and connecting shaft 305 to reduce their space occupation.
Claims
1. A foldable, prefabricated intelligent support frame for templates, characterized in that: include: Base (1); a support column A (101) is fixedly installed on the top of the base (1), and a threaded cylinder A (102) is fixedly installed on the top of the support column A (101), and a threaded column A (103) is installed inside the threaded cylinder A (102) by a threaded connection; a support column B (104) is fixedly installed on the top of the threaded column A (103), and both the support column B (104) and the support column A (101) are hollow structures, and a threaded cylinder B (105) is fixedly installed on the top of the support column B (104); a threaded column B (106) is installed inside the threaded cylinder B (105) by a threaded connection, and a support frame (107) is fixedly installed on the top of the threaded column B (106); the support frame (107) is U-shaped, and two sets of support frame (107), support column A (101), and support column B (104) are provided; A reinforcing component (2) is provided between the two sets of support columns A (101), and there are two reinforcing components (2), with the other one located between the two sets of support columns B (104); an auxiliary structure (3) is fixedly provided between the two sets of support frames (107).
2. The foldable prefabricated intelligent support frame for templates according to claim 1, characterized in that: The support frame (107) has through holes (108) on both sides, and locking bolts (109) are movably installed inside the through holes (108). The locking bolts (109) and the through holes (108) are symmetrically arranged. The support column A (101) and the support column B (104) both have positioning holes (1010).
3. The foldable prefabricated intelligent support frame for templates according to claim 2, characterized in that: The reinforcement component (2) includes: a reinforcement base (201), a positioning post (202), and a fixing base (203); the reinforcement base (201) is movably disposed on the outside of the support post A (101) and the support post B (104), and the reinforcement base (201) is configured as an arc-shaped structure; the positioning post (202) is fixedly disposed inside the reinforcement base (201), and the positioning post (202) is movably disposed inside the positioning hole (1010); the fixing base (203) is fixedly disposed on the outside of the reinforcement base (201), and the fixing base (203) and the reinforcement base (201) are both symmetrically arranged in two sets.
4. The foldable prefabricated intelligent support frame for templates according to claim 3, characterized in that: The reinforcement component (2) further includes: a tensioning screw barrel (204), a tensioning screw rod (205), and a knob (206); the tensioning screw barrel (204) is rotatably disposed inside a set of fixed seats (203); the tensioning screw rod (205) is rotatably disposed inside another set of fixed seats (203), and the tensioning screw rod (205) is disposed inside the tensioning screw barrel (204) by a threaded connection; the knob (206) is fixedly disposed on the outside of the tensioning screw barrel (204).
5. The foldable prefabricated intelligent support frame for templates according to claim 2, characterized in that: The auxiliary structure (3) includes: a support top plate (301), a threaded hole (302), a folding seat A (303), a folding seat B (304), and a connecting shaft (305); the support top plate (301) is movably disposed inside the support frame (107), and the support top plate (301) is provided with two sets; the threaded hole (302) is opened inside both sides of the support top plate (301), and the threaded hole (302) is provided with a locking bolt (109) by threaded connection; the folding seat A (303) is fixedly disposed at the bottom of one set of support top plates (301); the folding seat B (304) is fixedly disposed at the bottom of another set of support top plates (301); the connecting shaft (305) is fixedly disposed inside the folding seat A (303), and the connecting shaft (305) is rotatably disposed inside the folding seat B (304).
6. The foldable prefabricated intelligent support frame for templates according to claim 5, characterized in that: The auxiliary structure (3) further includes: a pressure sensor (306), a control module (307), and a buzzer alarm (308); the pressure sensor (306) is fixedly installed inside the top side of the supporting top plate (301), and the upper surface of the pressure sensor (306) is flush with the upper surface of the supporting top plate (301); the control module (307) is fixedly installed at the bottom of the supporting top plate (301), and the control module (307) and the pressure sensor (306) are electrically connected; the buzzer alarm (308) is fixedly installed at the bottom of the supporting top plate (301), and the buzzer alarm (308) and the control module (307) are electrically connected.