A cable storage structure in a monitoring device
By using cable management components and a winding frame structure to neatly organize the internal cables of the monitoring equipment, the problem of messy and tangled cables is solved, and the heat dissipation performance and maintenance efficiency of the equipment are improved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SUINING XINMEIRUN ELECTRONICS CO LTD
- Filing Date
- 2025-07-21
- Publication Date
- 2026-06-26
AI Technical Summary
Tangled and messy cables inside monitoring equipment can lead to poor heat dissipation, increase maintenance difficulty and time costs, and easily damage cables or interfaces.
The cable is initially straightened by the cable straightening assembly and the angle is adjusted by the hinge structure of the shaft frame and shaft block. The orderly storage of the cable is achieved by the rotation of the winding frame and winding roller.
It effectively avoids messy and tangled cables, improves the heat dissipation performance of equipment, extends service life, and reduces maintenance difficulty and time costs.
Smart Images

Figure CN224411077U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of monitoring equipment, and in particular to an internal cable storage structure for monitoring equipment. Background Technology
[0002] Currently, with the continuous development of surveillance technology, surveillance equipment has been widely used in various fields such as security, transportation, and industry. Surveillance equipment typically requires the connection of numerous cables, such as power cords, signal cables, and data cables. If these cables are not properly organized, they will become tangled and disorderly inside the equipment.
[0003] Tangled and messy cables can lead to poor heat dissipation inside equipment, affecting the normal operation of electronic components and shortening the equipment's lifespan. During equipment maintenance and repair, it's difficult to quickly and accurately locate the cables that need attention, increasing maintenance difficulty and time costs. Furthermore, during cable insertion and removal, tangling can easily cause cable damage or loose connections.
[0004] Based on this, we propose an internal cable management structure for monitoring equipment. Utility Model Content
[0005] To address the problem of messy and tangled cables in existing monitoring equipment, this utility model provides an internal cable management structure for monitoring equipment.
[0006] This utility model is achieved using the following technical solution: an internal cable storage structure for monitoring equipment, comprising a storage mechanism body, a cable straightening assembly, and a winding frame; wherein, the cable straightening assembly includes a mounting frame, a cable straightening frame, a cable clamp cavity, a shaft frame, a shaft block, and a connecting seat; the cable straightening frame is fixedly connected to the surface of the mounting frame; the cable straightening frame has a cable clamp cavity for accommodating cables; the shaft frame is fixedly connected to the surface of the mounting frame, the shaft frame and the shaft block are hinged by a pin, the connecting seat is fixedly connected to the outer side of the shaft block, and the winding frame is fixedly connected to the outer side of the connecting seat.
[0007] The winding frame is rectangular, with a first cable exit hole and a second cable exit hole at each end. A mounting base is fixedly connected to the surface of the winding frame, and a winding roller is movably connected to the outside of the mounting base. A handle is fixedly mounted on the surface of the winding roller. The handle is used to drive the winding roller to rotate; the first and second cable exit holes are used for cable entry and exit.
[0008] As a further optimization of this utility model, the main body of the storage mechanism is installed inside the monitoring equipment. The connection structure between the storage mechanism and the cable winding assembly and the winding frame ensures the stable installation of the entire storage structure inside the equipment, adapts to the spatial environment inside the monitoring equipment, and realizes effective storage and management of cables inside the equipment.
[0009] As a further optimization of this utility model, the cable first passes through the clamp cavity in the cable straightening assembly. The clamp cavity is opened by the cable straightening frame, which is fixed on the mounting frame. During this process, the clamp cavity plays a preliminary straightening role on the cable, keeping the cable in a relatively neat state, preparing it for subsequent winding.
[0010] As a further optimization of this utility model, when it is necessary to adapt to cables with different orientations, the cable winding assembly can be angled through the hinge structure of the shaft frame and the shaft block to ensure that the cable can smoothly enter the winding frame.
[0011] As a further optimization of this utility model, the winding frame is rectangular, with a mounting base fixed to its surface. A winding roller is movably connected to the outside of the mounting base, and a handle is fixed to the surface of the winding roller. Turning the handle causes the winding roller to rotate on the mounting base, thereby winding up the cable entering the winding frame.
[0012] As a further optimization of this utility model, the wound cable exits through the second outlet hole of the winding frame, completing the entire storage process. Because the cable straightening assembly and the winding frame are positioned relative to each other, and the connection between the various structures ensures smooth cable routing, the cable can be stored in an orderly manner, avoiding the problem of messy tangling.
[0013] Compared with the prior art, the beneficial effects of this utility model are as follows:
[0014] 1. This utility model, through the setting of the cable clamp cavity by the cable straightening component, can initially straighten the cable, keep the cable in a neat state, prepare for subsequent winding, and effectively avoid cable mess.
[0015] 2. With the help of the hinged structure of the shaft frame and the shaft block, the cable winding assembly can be angled to adapt to cables with different directions, ensuring that the cable enters the winding frame smoothly and improving the adaptability of the equipment to the cable direction.
[0016] 3. This utility model utilizes the cooperation of a winding frame, a winding roller, and a handle. Turning the handle can drive the winding roller to rotate and wind up the cable, achieving orderly cable storage, solving the problem of poor heat dissipation caused by messy cable tangling, and extending the service life of the equipment.
[0017] 4. Through the reasonable arrangement and connection of various structures, the cable passes through the clamp cavity, enters the winding frame through the first outlet hole, and exits through the second outlet hole after winding, so that the cable can run smoothly, which facilitates equipment maintenance and repair, and reduces maintenance difficulty and time cost. Attached Figure Description
[0018] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0019] Figure 2 This utility model Figure 1 Second-person perspective illustration;
[0020] Figure 3 This utility model Figure 2 Schematic diagram of the cross-section of the middle section.
[0021] Explanation of key symbols:
[0022] 1. Main body of the storage mechanism; 2. Cable winding assembly; 21. Mounting frame; 22. Cable winding frame; 23. Cable clamp cavity; 24. Shaft frame; 25. Shaft block; 26. Connecting seat; 3. Rewinding frame; 31. First cable exit hole; 32. Second cable exit hole; 33. Mounting seat; 34. Rewinding roller; 35. Handle. Detailed Implementation
[0023] The present invention will be further described below with reference to the accompanying drawings and specific embodiments. It should be noted that, without conflict, the various embodiments or technical features described below can be arbitrarily combined to form new embodiments. Example 1:
[0024] Please combine Figures 1-3 This embodiment proposes an internal cable storage structure for monitoring equipment, including a storage mechanism body 1, a cable straightening component 2, and a winding frame 3. The storage mechanism body 1 is installed inside the monitoring equipment, and the connection structure between it and the cable straightening component 2 and the winding frame 3 ensures the stable installation of the entire storage structure inside the equipment. It can adapt to the spatial environment inside the monitoring equipment and achieve effective storage and management of cables inside the equipment.
[0025] The cable straightening assembly 2 includes a mounting frame 21, a cable straightening frame 22, a cable clamp cavity 23, a shaft frame 24, a shaft block 25, and a connecting seat 26. The cable straightening frame 22 is fixedly connected to the surface of the mounting frame 21. The cable straightening frame 22 has a cable clamp cavity 23 for accommodating cables. The shaft frame 24 is fixedly connected to the surface of the mounting frame 21. The shaft frame 24 and the shaft block 25 are hinged together by a pin. The connecting seat 26 is fixedly connected to the outer side of the shaft block 25. The winding frame 3 is fixedly connected to the outer side of the connecting seat 26.
[0026] In the specific technical solution, the cable first passes through the cable clamp cavity 23 in the cable straightening assembly 2. The cable clamp cavity 23 is opened by the cable straightening frame 22, which is fixed on the mounting frame 21. During this process, the cable clamp cavity 23 plays a preliminary straightening role on the cable, keeping the cable in a relatively neat state, preparing it for subsequent winding.
[0027] A further technical solution involves fixing the shaft bracket 24 to the mounting bracket 21, and hinged the shaft bracket 24 and the shaft block 25 via a pin. A connecting seat 26 is connected to the outside of the shaft block 25, and the connecting seat 26 is fixed to the winding frame 3. Therefore, when it is necessary to accommodate cables with different orientations, the cable straightening assembly 2 can adjust its angle through the hinged structure of the shaft bracket 24 and the shaft block 25 to ensure that the cable can smoothly enter the winding frame 3.
[0028] The winding frame 3 is rectangular. A first cable exit hole 31 and a second cable exit hole 32 are respectively opened at both ends of the winding frame 3. A mounting base 33 is fixedly connected to the surface of the winding frame 3. A winding roller 34 is movably connected to the outer side of the mounting base 33. A handle 35 is fixedly installed on the surface of the winding roller 34. The handle 35 is used to drive the winding roller 34 to rotate; the first cable exit hole 31 and the second cable exit hole 32 are used for cable entry and exit.
[0029] The specific technical solution involves the straightened cable exiting the clamp cavity 23 and then entering the winding frame 3 through the first exit hole 31. The winding frame 3 is rectangular, with a mounting base 33 fixed to its surface. A winding roller 34 is movably connected to the outside of the mounting base 33, and a handle 35 is fixed to the surface of the winding roller 34. Rotating the handle 35 causes the winding roller 34 to rotate on the mounting base 33, thereby winding up the cable that has entered the winding frame 3.
[0030] More specifically, the wound cable exits through the second outlet hole 32 of the winding frame 3, completing the entire storage process. Because the cable straightening assembly 2 and the winding frame 3 are positioned opposite each other, and the connections between the various structures ensure smooth cable routing, the cable can be stored in an orderly manner, avoiding the problem of tangled mess.
[0031] Working principle
[0032] Cable straightening stage:
[0033] The cable first passes through the cable clamp cavity 23 in the cable straightening assembly 2. The cable clamp cavity 23 is opened by the cable straightening frame 22, which is fixed on the mounting frame 21. During this process, the cable clamp cavity 23 plays a preliminary straightening role on the cable, keeping the cable in a relatively neat state, preparing it for subsequent winding.
[0034] Adjustment of the angle of the wire straightening assembly:
[0035] Since the spindle bracket 24 is fixed on the mounting bracket 21, and the spindle bracket 24 and the spindle block 25 are hinged by a pin, and the outer side of the spindle block 25 is connected to the connecting seat 26, which is fixed to the winding frame 3, the cable straightening assembly 2 can be angled through the hinge structure between the spindle bracket 24 and the spindle block 25 to ensure that the cable can smoothly enter the winding frame 3 when it is necessary to accommodate cables with different orientations.
[0036] Cable winding stage:
[0037] After being straightened, the cable exits from the clamp cavity 23 and enters the winding frame 3 through the first exit hole 31. The winding frame 3 is rectangular, with a mounting base 33 fixed to its surface. A winding roller 34 is movably connected to the outside of the mounting base 33, and a handle 35 is fixed to the surface of the winding roller 34. Turning the handle 35 causes the winding roller 34 to rotate on the mounting base 33, thereby winding up the cable that has entered the winding frame 3.
[0038] Cable routing and organization:
[0039] After being wound up, the cable exits through the second outlet hole 32 of the winding frame 3, completing the entire storage process. Because the cable straightening assembly 2 and the winding frame 3 are positioned opposite each other, and the connection between the various structures ensures the smooth flow of the cable, the cable can be stored in an orderly manner, avoiding the problem of messy tangling.
[0040] Overall installation and adaptation:
[0041] The main body 1 of the storage mechanism is installed inside the monitoring equipment. The connection structure between it and the cable winding assembly 2 and the winding frame 3 ensures the stable installation of the entire storage structure inside the equipment. It can adapt to the spatial environment inside the monitoring equipment and achieve effective storage and management of cables inside the equipment.
[0042] The above embodiments are merely preferred embodiments of this utility model and should not be construed as limiting the scope of protection of this utility model. Any non-substantial changes and substitutions made by those skilled in the art based on this utility model shall fall within the scope of protection claimed by this utility model.
Claims
1. A monitoring device internal cable storage structure, characterized by, It includes the main body of the storage mechanism (1), the cord winding assembly (2), and the winding frame (3); The cable straightening assembly (2) includes a mounting frame (21), a cable straightening frame (22), a cable clamp cavity (23), a shaft frame (24), a shaft block (25), and a connecting seat (26). The mounting frame (21) is fixedly connected to the cable straightening frame (22). The cable straightening frame (22) is provided with a cable clamp cavity (23), which is used to accommodate cables. The mounting frame (21) is fixedly connected to the shaft frame (24), and the shaft frame (24) and the shaft block (25) are hinged by a pin. The outer side of the shaft block (25) is fixedly connected to the connecting seat (26), and the outer side of the connecting seat (26) is fixedly connected to the winding frame (3).
2. The cable storage structure of claim 1, wherein, The winding frame (3) is rectangular. The two ends of the winding frame (3) are respectively provided with a first wire outlet hole (31) and a second wire outlet hole (32). The surface of the winding frame (3) is fixedly connected to a mounting base (33). The outer side of the mounting base (33) is movably connected to a winding roller (34). The surface of the winding roller (34) is fixedly installed with a handle (35).
3. The internal cable management structure of a monitoring device as described in claim 2, characterized in that, The handle (35) is used to drive the winding roller (34) to rotate; the first outlet hole (31) and the second outlet hole (32) are used for the entry and exit of the cable.
4. The internal cable management structure of a monitoring device as described in claim 2, characterized in that, The cable winding assembly (2) and the winding frame (3) are positioned opposite each other. After the cable passes through the cable clamp cavity (23), it enters the winding frame (3) through the first cable exit hole (31), and after being wound by the winding roller (34), it passes through the second cable exit hole (32), thus realizing the orderly storage of the cable.
5. The internal cable management structure of a monitoring device as described in claim 1, characterized in that, The main body (1) of the storage mechanism is installed inside the monitoring equipment.