A private cloud encrypted communication module detection device

By using the extrusion plate and support rod structure design, the problem of bolt connection wear is solved, achieving a more stable and uniform connection effect, and improving the ease of installation and disassembly of the private cloud encrypted communication module detection device.

CN224385523UActive Publication Date: 2026-06-19INNER MONGOLIA DAIHAI ELECTRIC POWER GENERATION

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
INNER MONGOLIA DAIHAI ELECTRIC POWER GENERATION
Filing Date
2025-06-24
Publication Date
2026-06-19

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  • Figure CN224385523U_ABST
    Figure CN224385523U_ABST
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Abstract

This utility model discloses a private cloud encrypted communication module testing device, relating to the field of data processing technology. It includes multiple insertion holes on the main body of the communication module testing equipment. A connecting tube is fixedly connected to the inner wall of each insertion hole. Multiple extrusion plates are fixedly installed at equal intervals along the bottom edge of the connecting tube. The extrusion plates are elastic. Multiple support rods, one end of which abuts against the extrusion plates, are also provided inside the connecting tube. The end of the support rod away from the extrusion plates extends towards the connecting tube. A connecting block is also provided inside the connecting tube. The end of the support rod away from the extrusion plates is rotatably connected to the connecting block. In this utility model, when tightening the bolt, the bolt presses against the connecting block, causing the support rod to push the extrusion plates outward, expanding them. The expanded extrusion plates abut against the inner wall of the holes on the platform, thus connecting the main body of the communication module testing equipment. When the extrusion plates are inserted, their diameter is smaller than the hole; they only abut against the hole wall after expansion, reducing wear on the threaded holes.
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Description

Technical Field

[0001] This utility model relates to the field of data processing technology, specifically a detection device for a private cloud encrypted communication module. Background Technology

[0002] The private cloud encrypted communication module testing device is used to test the operating status and security performance of encrypted communication modules in a private cloud environment. It can verify the compliance of encryption algorithms, test the security of key management, monitor the effectiveness of data encryption and decryption during communication, and check whether the module has vulnerabilities or has been attacked. It ensures that the encrypted communication module meets security standards in data transmission and storage, protects the confidentiality, integrity and reliability of private cloud data transmission, and provides technical support for enterprise private cloud communication security.

[0003] Using bolts to secure modules provides reliable mechanical fastening force, and installation and disassembly are very convenient. More importantly, it is low-cost and technologically mature, and adaptable to a variety of installation scenarios. Therefore, it has become a common method for module fixing. The detection device used in the private cloud encrypted communication module is fixed in it by bolts.

[0004] However, simply using bolts for connection has its shortcomings. After frequent disassembly and installation, the threads of the bolts will wear down, affecting the tightness of the connection. Utility Model Content

[0005] The purpose of this invention is to provide a private cloud encrypted communication module detection device to solve the problems mentioned in the background art.

[0006] To solve the above-mentioned technical problems, this utility model provides a private cloud encrypted communication module testing device, including multiple sockets opened on the main body of the communication module testing equipment. A connecting tube is fixedly connected to the inner wall of the socket. Multiple extrusion plates are fixedly installed at equal intervals on the bottom edge of the connecting tube. The extrusion plates are elastic. Multiple support rods with one end abutting against the extrusion plates are also provided inside the connecting tube. The end of the support rod away from the extrusion plate extends towards the connecting tube. A connecting block is also provided inside the connecting tube. The end of the support rod away from the extrusion plate is rotatably connected to the connecting block.

[0007] Furthermore, the inner wall of the connecting pipe is provided with a threaded groove, and there is a gap between the bottom of the threaded groove and the top of the extrusion plate. A support plate is provided at the gap, and a push rod is fixedly installed at the bottom end of the support plate. The bottom end of the push rod abuts against the top of the connecting block.

[0008] Furthermore, the support rod is divided into an extrusion end and a connection end at both ends. A pressure plate is fixedly installed on the outer wall of the extrusion end. An extrusion groove is provided between the extrusion end and the pressure plate. The extrusion end and the pressure plate are elastic. The outer wall of the pressure plate is fixedly connected to the inner wall of the extrusion sheet.

[0009] Furthermore, the top of the extrusion sheet is provided with an inclined surface, and there is a gap between the inclined surface and the connecting tube.

[0010] Furthermore, a rotating rod is fixedly installed on the outer wall of the connecting end, the rotating rod passes through the connecting block, and the connecting block is rotatably connected to the outer wall of the rotating rod.

[0011] Furthermore, the extrusion end is arc-shaped, and there is a gap between the outer arc surface of the extrusion end and the outer wall of the pressure plate.

[0012] Compared with the prior art, the beneficial effects of this utility model are:

[0013] 1. In this utility model, when tightening the bolt, the bolt squeezes the connecting block, which drives the support rod to push the squeezing plate, causing it to expand outward. The squeezing plate expands outward and abuts against the inner wall of the hole on the platform, realizing the connection of the main body of the communication module detection equipment. When the squeezing plate is inserted, the diameter is smaller than the hole, and it abuts against the hole wall only after it expands outward, reducing wear on the threaded hole.

[0014] 2. In this utility model, when the extrusion end is close to the extrusion plate, the top pressure support rod will cause the extrusion end to abut against the pressure plate, expand the extrusion area, make the thrust transmission more uniform, and avoid local stress deformation and wear of the extrusion plate. When the extrusion end is close to the inner wall of the pressure plate, the elastic deformation of the extrusion groove will reduce the instantaneous impact force, reduce the impact load, and improve the structural stability. Attached Figure Description

[0015] Figure 1 This is a schematic diagram of the external structure of the present utility model;

[0016] Figure 2 This is a cross-sectional structural diagram of the present invention;

[0017] Figure 3 This is a schematic diagram of the internal structure of the connecting pipe in this utility model;

[0018] Figure 4 for Figure 3 Enlarged view of the structure at point A in the middle;

[0019] Figure 5 for Figure 3 Enlarged view of the structure at point B;

[0020] Figure 6 This is a schematic diagram of the connection structure between the connecting block and the connecting end in this utility model.

[0021] In the diagram: 1. Main body of the communication module testing equipment;

[0022] 2. Insertion hole; 3. Connecting tube; 4. Extrusion plate; 5. Inclined surface; 6. Support plate; 7. Push rod; 8. Support rod; 9. Extrusion groove; 10. Pressure plate; 11. Extrusion end; 12. Connecting block; 13. Rotating rod; 14. Connecting end. Detailed Implementation

[0023] 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.

[0024] This utility model provides a technical solution:

[0025] See Figures 1-6 As shown, a private cloud encrypted communication module testing device includes multiple sockets 2 opened on the main body 1 of the communication module testing device. A connecting tube 3 is fixedly connected to the inner wall of the socket 2. Multiple extrusion plates 4 are fixedly installed at equal intervals on the bottom edge of the connecting tube 3. The extrusion plates 4 are elastic. Multiple support rods 8 are also provided inside the connecting tube 3, with one end abutting against the extrusion plate 4. The end of the support rod 8 away from the extrusion plate 4 extends towards the connecting tube 3. A connecting block 12 is also provided inside the connecting tube 3. The end of the support rod 8 away from the extrusion plate 4 is rotatably connected to the connecting block 12.

[0026] The main body 1 of the communication module testing equipment typically includes a signal acquisition module, an encryption algorithm verification unit, a key management testing component, a communication protocol analyzer, a security vulnerability scanning engine, and a data storage and analysis module. The signal acquisition module is used to capture encrypted communication data, the encryption algorithm verification unit detects the algorithm strength and compliance, and the key management testing component verifies the security of key generation, storage, and distribution.

[0027] The communication protocol analyzer parses the protocol integrity during transmission, the security vulnerability scanning engine investigates potential risks, and the data storage and analysis module records the detection results and generates reports. These components work together to ensure that the private cloud encrypted communication module is compliant with algorithms, secure with keys, reliable in transmission, and free from vulnerabilities, thus ensuring the confidentiality and integrity of data in encrypted communication. The main body of the communication module detection device 1 is usually fixed in a standard rack in the private cloud data center, which facilitates cable connection with servers, network devices, etc. in the rack, and also facilitates centralized management and heat dissipation.

[0028] Traditional communication module testing equipment has a socket 2 on the main body 1, and bolts are directly screwed into the socket 2 to fix the main body 1. In this paper, a connecting tube 3 is fixed inside the socket 2, and bolts can still be screwed into the connecting tube 3 to... Figure 3 From the perspective of the bolt, as the bottom of the bolt gradually moves downward, the bolt continues to move downward and presses against the connecting block 12, causing the connecting block 12 to move downward as well. Then the connecting block 12 will drive the end of the support rod 8 away from the pressing plate 4 to move downward together. Then the right end of the support rod 8 will push the pressing plate 4, pushing the pressing plate 4 outward, causing multiple pressing plates 4 to expand outward.

[0029] In its initial state, the main body 1 of the communication module testing equipment is placed in a location that needs to be fixed, such as a platform on a server rack. The platform also has holes for bolt insertion. The holes for bolt insertion on the platform are aligned vertically with the insertion hole 2. Then, the main body 1 of the communication module testing equipment is placed close to the surface of the platform. The extrusion plate 4 will be inserted into the hole on the platform. Then, the bolt is screwed into the connecting pipe 3, causing the extrusion plate 4 to expand outward. Then, the extrusion plate 4 can be tightly pressed against the hole on the platform to achieve the connection effect and complete the fixing of the main body 1 of the communication module testing equipment.

[0030] When the extrusion plate 4 is inserted into the hole on the platform, the diameter of the circle formed by multiple extrusion plates 4 is smaller than the diameter of the hole. Therefore, excessive friction will not occur when the extrusion plate 4 is inserted. Only after the extrusion plate 4 expands outward will it come into contact with the inner wall of the hole. This will prevent excessive wear on the threaded wire in the threaded hole.

[0031] See Figure 3 The inner wall of the connecting pipe 3 is also provided with a threaded groove. There is a gap between the bottom of the threaded groove and the top of the extrusion plate 4. A support plate 6 is provided in the gap. A push rod 7 is fixedly installed at the bottom of the support plate 6. The bottom of the push rod 7 abuts against the top of the connecting block 12.

[0032] The connecting pipe 3 can be threaded to the bolt by opening a threaded groove. Then, the bolt is screwed into the connecting pipe 3, which will abut and squeeze the support plate 6. The support plate 6 drives the push rod 7 to squeeze the connecting block 12, causing the connecting block 12 to move downward.

[0033] See Figures 5-6 The support rod 8 is divided into an extrusion end 11 and a connection end 14 at both ends. A pressure plate 10 is fixedly installed on the outer wall of the extrusion end 11. An extrusion groove 9 is provided between the extrusion end 11 and the pressure plate 10. The extrusion end 11 and the pressure plate 10 are elastic. The outer wall of the pressure plate 10 is fixedly connected to the inner wall of the extrusion sheet 4.

[0034] The extrusion end 11 is close to the extrusion plate 4. When the support rod 8 pushes against the extrusion plate 4, the extrusion end 11 will approach the pressure plate 10 and come into contact with the pressure plate 10. The side of the extrusion end 11 that comes into contact with the pressure plate 10 and the area where the extrusion end 11 is connected to the pressure plate 10 together increase the area of ​​the extrusion plate 4, so as to avoid the plate from deforming, wearing or being damaged due to excessive local force concentration. At the same time, the expansion of the area of ​​the pressure plate 10 can make the thrust transmission more uniform.

[0035] As the extrusion end 11 approaches the inner wall of the pressure plate 10, the extrusion groove 9 will deform. The elastic deformation at the connection between the extrusion end 11 and the pressure plate 10 will reduce the force of the extrusion end 11 hitting the pressure plate 10 instantaneously, thereby reducing the impact load and improving stability.

[0036] See Figure 4 The top of the extrusion sheet 4 is also provided with a bevel 5, and there is a gap between the bevel 5 and the connecting pipe 3.

[0037] When the extrusion plate 4 expands outward, the gap will open, and the inclined surface 5 will also move away from the bottom of the connecting tube 3. After the extrusion plate 4 rebounds, the inclined surface 5 will move closer to the bottom of the connecting tube 3. The opening and closing of the gap increases the range of the extrusion plate 4's outward expansion. After the extrusion plate 4 wears, the range of the extrusion plate 4's outward expansion can be gradually increased, so that the extrusion plate 4 continues to contact the inner wall of the hole on the platform.

[0038] See Figure 6 A rotating rod 13 is fixedly installed on the outer wall of the connecting end 14. The rotating rod 13 passes through the connecting block 12, and the connecting block 12 is rotatably connected to the outer wall of the rotating rod 13.

[0039] The connecting block 12 is rotatably connected to the connecting end 14 via the rotating rod 13. When the connecting block 12 is squeezed and moves downward, the connecting block 12 will rotate along the outer wall of the rotating rod 13 to achieve a change in angle.

[0040] See Figure 5 The extrusion end 11 is arc-shaped, and there is a gap between the outer arc surface of the extrusion end 11 and the outer wall of the pressure plate 10.

[0041] The gap between the extrusion end 11 and the pressure plate 10 ensures that when the extrusion end 11 needs to push the extrusion sheet 4, it will not immediately hit the pressure plate 10. Instead, the extrusion end 11 will move within the gap after the connection between the extrusion end 11 and the pressure plate 10 deforms, and then it will come into contact with the pressure plate 10. This buffers the force of the extrusion end 11 hitting the pressure plate 10.

Claims

1. A private cloud encrypted communication module detection device, comprising multiple sockets (2) opened on the main body (1) of the communication module detection device, characterized in that, The inner wall of the insertion hole (2) is fixedly connected to a connecting tube (3). Multiple extrusion plates (4) are fixedly installed at equal intervals on the bottom edge of the connecting tube (3). The extrusion plates (4) are elastic. Multiple support rods (8) with one end abutting against the extrusion plates (4) are also provided inside the connecting tube (3). The end of the support rod (8) away from the extrusion plates (4) extends toward the connecting tube (3). A connecting block (12) is also provided inside the connecting tube (3). The end of the support rod (8) away from the extrusion plates (4) is rotatably connected to the connecting block (12).

2. The private cloud encrypted communication module detection device as described in claim 1, characterized in that: The inner wall of the connecting pipe (3) is also provided with a threaded groove. There is a gap between the bottom of the threaded groove and the top of the extrusion plate (4). A support plate (6) is provided in the gap. A push rod (7) is fixedly installed at the bottom of the support plate (6). The bottom of the push rod (7) abuts against the top of the connecting block (12).

3. The private cloud encrypted communication module detection device as described in claim 2, characterized in that: The support rod (8) is divided into an extrusion end (11) and a connection end (14) at both ends. A pressure plate (10) is fixedly installed on the outer wall of the extrusion end (11). An extrusion groove (9) is provided between the extrusion end (11) and the pressure plate (10). The extrusion end (11) and the pressure plate (10) are elastic. The outer wall of the pressure plate (10) is fixedly connected to the inner wall of the extrusion sheet (4).

4. The private cloud encrypted communication module detection device as described in claim 3, characterized in that: The top of the extrusion sheet (4) is also provided with a slope (5), and there is a gap between the slope (5) and the connecting pipe (3).

5. The private cloud encrypted communication module detection device as described in claim 4, characterized in that: A rotating rod (13) is fixedly installed on the outer wall of the connecting end (14). The rotating rod (13) passes through the connecting block (12), and the connecting block (12) is rotatably connected to the outer wall of the rotating rod (13).

6. The private cloud encrypted communication module detection device as described in claim 5, characterized in that: The extrusion end (11) is arc-shaped, and there is a gap between the outer arc surface of the extrusion end (11) and the outer wall of the pressure plate (10).