Wind-resistant reinforced cement pole
The design of the support and fastening mechanisms solved the problem of supporting and fastening cement poles in severe weather, achieving stable connection and improved wind resistance under different environmental conditions.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHANDONG XINFENG ELECTRIC POWER TECHNOLOGY CO LTD
- Filing Date
- 2025-07-28
- Publication Date
- 2026-06-23
Smart Images

Figure CN224396156U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of cement pole technology, and in particular relates to a wind-resistant reinforced cement pole. Background Technology
[0002] Cement poles, as core supporting components for infrastructure such as power transmission and communication networks, are widely used in urban and rural power grids, railway lines, and remote areas. Their application environment often faces complex and changeable weather conditions, especially severe weather such as strong winds and typhoons, which can generate huge lateral loads and overturning moments on the pole structure.
[0003] Existing reinforcement structures for cement poles have significant technical defects. From a fastening performance perspective, traditional reinforcement devices often have fixed fastening positions, lacking adjustable locking mechanisms. Because varying intensities of severe weather cause differences in wind pressure loads at different pole heights, fixed fastening structures cannot adjust locking points according to stress changes. Furthermore, most fastening components rely on single bolt connections, which, due to material rigidity limitations, are prone to loosening under long-term stress, leading to a decrease in fastening effectiveness. From a support stability perspective, existing support structures often have fixed support angles, unable to dynamically adjust the support rods based on ground flatness and wind direction. If the ground has slopes or unevenness, the support rods cannot fully conform to the ground, creating a false support. Simultaneously, the support and fastening structures lack coordinated design; after the support angle is adjusted, it cannot be simultaneously locked by the fastening structure. Under strong winds, support components are prone to displacement, further reducing overall wind resistance. These defects all stem from the rigid, fixed characteristics of the structural design, lacking dynamic adjustment and coordinated locking mechanisms, making the reinforcement effect highly susceptible to environmental changes.
[0004] To address these issues, we provide a wind-resistant reinforced cement pole. Utility Model Content
[0005] The purpose of this utility model is to provide a wind-resistant reinforced cement pole. Through the cooperation of the support mechanism and the fastening mechanism, it solves the problems in the prior art where the fastening structure cannot adjust the locking point according to changes in force, and cannot dynamically adjust the support angle according to the flatness of the ground and the direction of the wind.
[0006] To solve the above-mentioned technical problems, this utility model is achieved through the following technical solution.
[0007] This utility model relates to a wind-resistant reinforced cement pole, comprising a pole body, a support mechanism fixedly connected to the surface of the pole body, and a fastening mechanism movably connected to one side of the support mechanism; the support mechanism includes a fixed plate, on the surface of which evenly distributed brackets are fixedly connected, and a support rod is movably connected to the inner wall of the brackets via a rotating rod, and a support plate is movably connected to the surface of the support rod via a rotating rod; the fastening mechanism includes slots evenly distributed on the surface of the pole body, with elastic blocks engaged in the inner wall of the slots, and a fastening ring fixedly connected to the top of the elastic blocks, with a locking sleeve threaded onto the surface of the fastening ring. The locking sleeve is movably connected to the support plate via a rotating rod. The fixing plate is fixed to the pole body. The bracket is connected to the support rod via the rotating rod. The support plate at the bottom of the support rod is movably connected to the fastening mechanism. The slots of the fastening mechanism are distributed on the surface of the pole. The elastic block is inserted into the slot to achieve initial fixation. The fastening ring is locked by the locking sleeve thread to further strengthen the connection with the pole. At the same time, it drives the support plate to unfold the support rod. The adjustable support and fastening combination design, through the positioning of the fastening ring in different slots, adapts to the reinforcement requirements of different wind levels. The triangular support structure formed by the support rod and the ground improves the pole's wind resistance bending moment. Compared with traditional fixed support, it can flexibly cope with terrain changes and wind fluctuations.
[0008] The present invention is further configured such that the fastening ring surface is provided with through grooves for use with the elastic locking block, the through grooves are distributed in a circumferential shape, and there are four through grooves. The four circumferential through grooves on the fastening ring surface provide a telescopic channel for the elastic locking block, ensuring that the elastic locking block can be accurately locked into the locking groove of the pole body.
[0009] The present invention is further configured such that a handwheel is fixedly connected to the surface of the locking sleeve, and the surface of the handwheel is provided with anti-slip texture. The handwheel on the surface of the locking sleeve is easy to rotate manually, and the anti-slip texture increases the friction of the hand, ensuring stable force application when wet outdoors or wearing gloves, so as to achieve precise compression of the locking sleeve onto the fastening ring and improve the efficiency of emergency reinforcement in severe weather.
[0010] The present invention is further configured such that a threaded groove is provided at the bottom of the support rod, and a telescopic rod is threadedly connected to the inner wall of the threaded groove. The threaded groove at the bottom of the support rod is threadedly connected to the telescopic rod. By rotating the telescopic rod, the overall length of the support rod can be adjusted to adapt to different ground heights or slopes, avoid support gaps caused by uneven ground, and ensure the rigid connection of the triangular support.
[0011] The present invention is further configured such that a turntable is fixedly connected to the surface of the telescopic rod, and the surface of the turntable is provided with evenly distributed anti-slip grooves. The turntable on the surface of the telescopic rod is easy to grip and rotate, and the anti-slip grooves increase the friction between the hand and the turntable, making the telescopic rod extension and retraction adjustment in the threaded groove more precise and effortless, and improving the safety of operation.
[0012] The present invention is further configured such that a mounting plate is movably connected to the bottom of the telescopic rod via a rotating rod, and the top of the mounting plate has evenly distributed mounting holes. The mounting plate at the bottom of the telescopic rod is connected to the ground expansion bolts through the mounting holes, so as to transfer the supporting force of the support rod to the ground and prevent the support rod from slipping under the action of wind. It is suitable for soft soil or typhoon-prone areas.
[0013] The present invention has the following beneficial effects.
[0014] 1. The handwheel of this utility model drives the locking sleeve to rotate in the forward or reverse direction, which can realize the locking and unlocking of the fastening ring. With the cooperation of the elastic block and the engagement of the slots at different heights, the fastening position can be adjusted according to the changes in the force on the pole under severe weather conditions, accurately adapting to the fastening requirements under different wind forces and force angles. Even under strong wind impact, it can maintain the stability of the connection and provide a force-bearing foundation for the subsequent support structure.
[0015] 2. When the fastening ring of this utility model moves, it simultaneously drives the support plate and support rod to unfold. It can adjust the angle between the support rod and the ground according to the weather intensity, and can flexibly adapt to different ground flatness and support height requirements. The resulting triangular support structure can evenly distribute the external forces such as wind force borne by the pole to the ground, greatly improving the overturning resistance of the support. Attached Figure Description
[0016] To more clearly illustrate the technical solutions of the embodiments of this utility model, the accompanying drawings used in the description of the embodiments will be briefly introduced below.
[0017] Figure 1 This is a three-dimensional diagram of a wind-resistant reinforced cement pole.
[0018] Figure 2 This is a structural diagram of the fastening mechanism in a wind-resistant reinforced cement pole.
[0019] Figure 3 This is a structural diagram of the support mechanism in a wind-resistant reinforced cement pole.
[0020] Figure 4 This is a structural diagram of a telescopic pole in a wind-resistant reinforced cement pole.
[0021] Figure 5 This is a cross-sectional view of an overall type of wind-resistant reinforced cement pole.
[0022] In the attached diagram: 1. Pole body; 2. Support mechanism; 3. Fastening mechanism; 21. Fixing plate; 22. Bracket; 23. Support rod; 24. Support plate; 31. Slot; 32. Elastic block; 33. Fastening ring; 34. Locking sleeve; 4. Handwheel; 5. Telescopic rod; 6. Turntable; 7. Mounting plate; 8. Mounting hole. Detailed Implementation
[0023] The technical solutions of the present utility model will be described below with reference to the accompanying drawings. The described embodiments are only some embodiments of the present utility model, and not all embodiments.
[0024] Example 1
[0025] Please see Figure 1-5 This utility model is a wind-resistant reinforced cement pole, including a pole body 1, a support mechanism 2 fixedly connected to the surface of the pole body 1, and a fastening mechanism 3 movably connected to one side of the support mechanism 2; the support mechanism 2 includes a fixed plate 21, a uniformly distributed bracket 22 fixedly connected to the surface of the fixed plate 21, a support rod 23 movably connected to the inner wall of the bracket 22 via a rotating rod, and a support plate 24 movably connected to the surface of the support rod 23 via a rotating rod; the fastening mechanism 3 includes a slot 31, the slots 31 are evenly distributed on the surface of the pole body 1, an elastic block 32 is engaged in the inner wall of the slot 31, a fastening ring 33 is fixedly connected to the top of the elastic block 32, a locking sleeve 34 is threadedly connected to the surface of the fastening ring 33, and the surface of the fastening ring 33, located above the locking sleeve 34, is movably connected to the support plate 24 via a rotating rod.
[0026] Specifically: the fixing plate 21 is fixed to the pole body 1, the bracket 22 is connected to the support rod 23 through the rotating rod, the support plate 24 at the bottom of the support rod 23 is movably connected to the fastening mechanism 3, the slots 31 of the fastening mechanism 3 are distributed on the surface of the pole, the elastic block 32 is inserted into the slot 31 to achieve initial fixation, the fastening ring 33 is threaded through the locking sleeve 34 to further strengthen the connection with the pole, and at the same time drive the support plate 24 to unfold the support rod 23. The adjustable support and fastening combination design, through the positioning of the fastening ring 33 in different slots 31, adapts to the reinforcement requirements of different wind levels. The triangular support structure formed by the support rod 23 and the ground improves the pole's wind resistance bending moment. Compared with traditional fixed support, it can flexibly cope with terrain changes and wind fluctuations.
[0027] Example 2
[0028] Please see Figure 1-5 Based on Embodiment 1, the fastening ring 33 has a through groove on its surface that is used in conjunction with the elastic locking block 32. The through grooves are distributed in a circular shape and there are four through grooves. A handwheel 4 is fixedly connected to the surface of the locking sleeve 34. The surface of the handwheel 4 is provided with anti-slip texture. A threaded groove is provided at the bottom of the support rod 23. A telescopic rod 5 is threadedly connected to the inner wall of the threaded groove. A turntable 6 is fixedly connected to the surface of the telescopic rod 5. The surface of the turntable 6 is provided with evenly distributed anti-slip grooves. The bottom of the telescopic rod 5 is movably connected to the mounting plate 7 through the rotating rod. The top of the mounting plate 7 is provided with evenly distributed mounting holes 8.
[0029] Specifically: the four circumferential grooves on the surface of the fastening ring 33 provide a telescopic channel for the elastic locking block 32, ensuring that the elastic locking block 32 can accurately engage with the locking groove 31 of the pole body 1; the handwheel 4 on the surface of the locking sleeve 34 facilitates manual rotation operation, and the anti-slip texture increases hand friction, ensuring stable force application even in wet outdoor conditions or when wearing gloves, achieving precise compression of the fastening ring 33 by the locking sleeve 34, improving the efficiency of emergency reinforcement in severe weather; the threaded groove at the bottom of the support rod 23 is threadedly connected to the telescopic rod 5, and the support rod 23 can be adjusted by rotating the telescopic rod 5. The telescopic rod 5 has a body length that adapts to different ground heights or slopes, avoiding support gaps caused by uneven ground and ensuring a rigid connection of the triangular support. The turntable 6 on the surface of the telescopic rod 5 is easy to grip and rotate, and the anti-slip groove increases the friction between the hand and the turntable 6, making the telescopic rod 5 more precise and effortless to adjust in the threaded groove, thus improving operational safety. The mounting plate 7 at the bottom of the telescopic rod 5 is connected to the ground expansion bolts through the mounting holes 8, transferring the supporting force of the support rod 23 to the ground and preventing the support rod 23 from slipping under wind force. It is suitable for soft soil or typhoon-prone areas.
[0030] The working principle of this utility model is as follows: When encountering severe weather conditions, turning the handwheel 4 causes the locking sleeve 34 to rotate, releasing the locking sleeve 34 from locking the fastening ring 33. At this time, the elastic block 32 returns to its original state and no longer squeezes and fixes the slot 31. Depending on the weather conditions, the fastening mechanism 3 is moved upward to the corresponding slot 31. Then, the handwheel 4 is rotated in the opposite direction to drive the locking sleeve 34 to rotate on the threaded surface of the fastening ring 33. During the downward movement of the locking sleeve 34, it squeezes the fastening ring 33, making the elastic block 32 and the slot 31 more tightly engaged. After the fastening ring 33 is fixed to the pole body 1, the fastening ring 33 moves upward, causing the support plate 24 to open. The support plate 24 unfolds outward, causing the support rod 23 to unfold outward at a certain angle to the ground. Then, the turntable 6 is rotated to cause the telescopic rod 5 to rotate and extend in the threaded groove, thereby adjusting the overall length of the support rod 23 until the mounting plate 7 is completely in contact with the ground. At this time, the support rod 23, the pole body 1 and the ground form a stable triangular support structure. Through the fixed limit of the fastening mechanism 3 and the length adjustment of the support mechanism 2, the wind resistance of the pole body 1 is reinforced.
[0031] The preferred embodiments of the present utility model disclosed above are only used to help illustrate the present utility model. The preferred embodiments do not describe all the details in detail, nor do they limit the present utility model to the specific implementation methods described. The present specification selects and specifically describes these embodiments in order to better explain the principle and practical application of the present utility model, so that those skilled in the art can better understand and utilize the present utility model.
Claims
1. A wind-resistant reinforced cement pole, comprising a pole body (1), characterized in that: A support mechanism (2) is fixedly connected to the surface of the pole body (1), and a fastening mechanism (3) is movably connected to one side of the support mechanism (2); The support mechanism (2) includes a fixed plate (21), on which a uniformly distributed bracket (22) is fixedly connected. A support rod (23) is movably connected to the inner wall of the bracket (22) via a rotating rod. A support plate (24) is movably connected to the surface of the support rod (23) via a rotating rod. The fastening mechanism (3) includes a slot (31) which is evenly distributed on the surface of the pole body (1). An elastic block (32) is engaged in the inner wall of the slot (31). A fastening ring (33) is fixedly connected to the top of the elastic block (32). A locking sleeve (34) is threadedly connected to the surface of the fastening ring (33). The surface of the fastening ring (33) and above the locking sleeve (34) is movably connected to the support plate (24) through a rotating rod.
2. The wind-resistant reinforced cement pole according to claim 1, characterized in that: The fastening ring (33) has a through groove on its surface for use with the elastic locking block (32). The through groove is distributed in a circular shape and there are four through grooves.
3. The wind-resistant reinforced cement pole according to claim 1, characterized in that: A handwheel (4) is fixedly connected to the surface of the locking sleeve (34), and the surface of the handwheel (4) is provided with anti-slip texture.
4. The wind-resistant reinforced cement pole according to claim 1, characterized in that: The bottom of the support rod (23) is provided with a threaded groove, and the inner wall of the threaded groove is threaded with a telescopic rod (5).
5. A wind-resistant reinforced cement pole according to claim 4, characterized in that: The telescopic rod (5) is fixedly connected to a turntable (6), and the turntable (6) has evenly distributed anti-slip grooves on its surface.
6. A wind-resistant reinforced cement pole according to claim 4, characterized in that: The bottom of the telescopic rod (5) is movably connected to the mounting plate (7) via a rotating rod, and the top of the mounting plate (7) is provided with evenly distributed mounting holes (8).