An iot host protection apparatus for cloud computing

Abstract

The utility model discloses a kind of Internet of Things host protection devices for cloud computing, including protection shell, the front of protection shell is equipped with placing mouth, detachable front cover is installed in placing mouth, rectangular through-hole is equipped in front cover, the upper and lower surfaces of protection shell are all equipped with multiple evenly distributed waist-shaped through-holes, the upper and lower surfaces of protection shell are all installed with detachable frame, all through-holes on frame and the through-hole on front cover are all fixed with dust filter screen, the rear of protection shell is installed with a pair of exhaust fan;The device is evenly distributed by being equipped with multiple waist-shaped through-holes on the upper and lower surfaces of protection shell, and install frame with dust filter screen, cooperate exhaust fan work again, can make air pass through waist-shaped through-hole circulation and realize heat dissipation, dust filter screen can effectively block dust into the inside of protection shell, avoid dust adhering on Internet of Things host circuit board and electronic component and influence heat dissipation and electrical performance, prolong the service life of host.

Description

Technical Field

[0001] This utility model relates to the field of cloud computing technology, specifically to an Internet of Things (IoT) host protection device for cloud computing. Background Technology

[0002] In the current era of rapid cloud computing development, IoT hosts, as key hubs connecting various IoT devices and cloud computing platforms, are crucial for stable operation. IoT hosts typically need to process and transmit large amounts of data from different IoT devices, placing high demands on computing and communication capabilities. This also causes their hardware components to generate a lot of heat during operation. If heat cannot be dissipated in a timely and effective manner, it can lead to a decline in host performance, accelerated device aging, or even damage, seriously affecting the continuity and reliability of cloud computing services. At the same time, IoT hosts are often deployed in various complex environments and may face interference and damage from external factors such as dust and collisions. Dust entering the host can adhere to circuit boards and electronic components, affecting heat dissipation and electrical performance. Long-term accumulation may lead to faults such as short circuits, while collisions may directly damage the physical structure of the host, resulting in hardware damage.

[0003] Therefore, we have designed an IoT host protection device for cloud computing to solve the above problems. Utility Model Content

[0004] The purpose of this invention is to address the shortcomings of existing technologies by providing an IoT host protection device for cloud computing, thereby solving the problems mentioned in the background.

[0005] To achieve the above objectives, this utility model provides the following technical solution: an IoT host protection device for cloud computing, comprising a protective shell, a placement opening on the front of the protective shell, a removable front cover installed in front of the placement opening, grooves on the bottom edge of the front cover and the bottom edge of the placement opening of the protective shell, and a first soft silicone strip and a second soft silicone strip respectively fixed in these two grooves, the two soft silicone strips being in close contact, a rectangular through hole on the front cover, multiple evenly distributed waist-shaped through holes on the upper and lower surfaces of the protective shell, a removable frame installed on the upper and lower surfaces of the protective shell, dust filters fixed in all the through holes on the frame and the through holes on the front cover, a pair of exhaust fans installed at the rear of the protective shell, four horizontally adjustable positioning plates at the bottom of the inner cavity of the protective shell, and a vertically movable pressure plate at the top of the inner cavity of the protective shell, with silicone pads affixed to the positioning plates and the pressure plates.

[0006] As a preferred technical solution of this utility model, the left and right sides of the front cover are provided with strip-shaped positioning protrusions, and the two sides of the placement opening of the protective shell are provided with positioning grooves that cooperate with the positioning protrusions. A pair of buckles are installed between the two sides of the front cover and the two sides of the protective shell.

[0007] As a preferred technical solution of this utility model, four positioning iron pillars arranged in a rectangular array are fixed on the top and bottom of the protective shell. Positioning holes are opened on the upper and lower frames corresponding to the positions of the positioning iron pillars. A magnet is fixed in each positioning hole and the magnet is attracted to the positioning iron pillar.

[0008] As a preferred technical solution of this utility model, the positioning plate is L-shaped, and two limiting blocks are fixed at the bottom of the positioning plate. The bottom of each of the two limiting blocks is fixed with a first threaded post. The two first threaded posts at the bottom of the positioning plate pass through the waist-shaped through hole at the bottom of the protective shell and are connected to a first nut by threads.

[0009] As a preferred technical solution of this utility model, a through hole is provided at the top center of the protective shell, and a second nut is fixed at the through hole. A second threaded post is connected to the second nut by a thread. The pressure plate is connected to the bottom end of the second threaded post by a universal joint, and a knob is fixed at the top end of the second threaded post.

[0010] As a preferred technical solution of this utility model, the protective shell is made of aluminum alloy, and a controller for controlling the operation of the exhaust fan is provided on the outside of the protective shell.

[0011] As a preferred technical solution of this utility model, an IoT host is placed inside the protective shell, four positioning plates are respectively supported at the four edges of the bottom of the IoT host shell, and a pressure plate is pressed on the top of the IoT host shell.

[0012] Compared with existing technologies, this utility model provides an IoT host protection device for cloud computing, which has the following beneficial effects:

[0013] 1. This IoT host protection device for cloud computing uses multiple evenly distributed waist-shaped through holes on the top and bottom sides of the protective shell, and a frame with a dust filter installed. Combined with the operation of the exhaust fan, air can circulate through the waist-shaped through holes to achieve heat dissipation. The dust filter can effectively block dust from entering the interior of the protective shell, preventing dust from adhering to the IoT host circuit board and electronic components, affecting heat dissipation and electrical performance, and extending the service life of the host. The front cover also has through holes and a dust filter installed, which can further enhance air circulation, improve heat dissipation, and ensure stable operation of the host in a good environment.

[0014] 2. This IoT host protection device for cloud computing avoids direct damage to the host from collisions by setting a protective shell on the outside of the IoT host. By setting a horizontally adjustable positioning plate at the bottom of the inner cavity of the protective shell, the position of the positioning plate can be flexibly adjusted according to the different sizes of IoT hosts, so that it can be precisely supported at the four edges of the bottom of the host shell, providing stable support for the host. By setting a vertically movable pressure plate at the top of the inner cavity of the protective shell, the pressure plate can be smoothly pressed on the top of the host shell, realizing the stable fixation of the host inside the protective shell. Both the pressure plate and the positioning plate are covered with silicone pads, which can not only play a shock absorption role, but also prevent scratches on the host shell and reduce damage to the host from collisions. Attached Figure Description

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

[0016] Figure 2 This is an exploded view of the overall structure of this utility model;

[0017] Figure 3 This is a schematic diagram of the bottom structure of the protective shell of this utility model;

[0018] Figure 4 This is a schematic diagram of the internal structure of the protective shell of this utility model;

[0019] Figure 5 This is a schematic diagram of the front cover structure of this utility model;

[0020] Figure 6 This is a schematic diagram of the positioning plate structure of this utility model.

[0021] Reference numerals: 1. Protective shell; 2. Front cover; 3. Frame; 4. Dust filter; 5. Exhaust fan; 6. First soft silicone strip; 7. Second soft silicone strip; 8. Positioning plate; 9. Pressure plate; 10. Silicone pad; 11. Positioning protrusion; 12. Buckle; 13. Positioning iron post; 14. Magnet; 15. Limiting block; 16. First threaded post; 17. First nut; 18. Second nut; 19. Second threaded post; 20. Knob. Detailed Implementation

[0022] 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.

[0023] Example 1: Please refer to Figures 1-6An IoT host protection device for cloud computing is disclosed. Its protective shell 1 is made of aluminum alloy, with a placement opening on the front. The IoT host can be inserted into the protective shell 1 through the placement opening. A quick-removable front cover 2 is installed in front of the placement opening. Grooves are respectively formed at the bottom edge of the front cover 2 and the bottom edge of the placement opening on the protective shell 1, and a first soft silicone strip 6 and a second soft silicone strip 7 are respectively fixed therein. In use, the network cable connecting the IoT host can pass through the grooves in the protective shell 1 and the front cover 2. The two soft silicone strips not only clamp the network cable to prevent the connector from loosening when the cable is pulled, but also fill the gap between the grooves and the network cable, minimizing external interference. Dust enters the interior of the protective shell 1 through the groove. A rectangular through hole is opened on the front cover 2. Multiple evenly distributed waist-shaped through holes are opened on the top and bottom surfaces of the protective shell 1. A frame 3 that can be quickly disassembled is installed on both the top and bottom surfaces of the protective shell 1. Dust filters 4 are fixed to all through holes on the frame 3 and the through holes on the front cover 2. The dust filters 4 prevent dust from entering the interior of the protective shell 1 through the placement opening on the front and the waist-shaped through holes on the top and bottom surfaces. A pair of exhaust fans 5 are installed at the rear of the protective shell 1. A controller for controlling the operation of the exhaust fans 5 is set on the outside of the fans, which can adjust the exhaust intensity as needed. Four horizontally adjustable positioning plates 8 are set at the bottom of the inner cavity of the protective shell 1. The positioning plates 8 are L-shaped, and two limit blocks 15 are fixed at the bottom of the plates. The bottom of the limit blocks 15 is fixed with the first One threaded post 16 and two first threaded posts 16 pass through the oblong through hole at the bottom of the protective shell 1 and are connected to the first nut 17 by threads. By loosening the first nut 17, the positioning plate 8 can be moved horizontally to a suitable position, and then the first nut 17 can be tightened to fix it. The four positioning plates 8 cooperate with each other to determine the horizontal position of the IoT host inside the protective shell 1, preventing the IoT host from moving horizontally inside the protective shell 1. A scale mark can be set next to the oblong through hole at the bottom of the protective shell 1 so that the position of the positioning plate 8 can be accurately moved according to the bottom size of the IoT host shell and with reference to the scale mark. A through hole is opened at the center of the top of the protective shell 1 and a second nut 18 is fixed therein. The second nut 18 is connected to the second threaded post 19 by threads. Pressure plate 9 The second threaded post 19 is connected to the bottom end via a universal joint. A knob 20 is fixed to the top end of the second threaded post 19. By rotating the knob 20, the second threaded post 19 can move up and down within the second nut 18, thereby driving the pressure plate 9 to move up and down. When the pressure plate 9 presses on the IoT host, it cooperates with the positioning plate 8 to restrict the up and down movement of the IoT host within the protective shell 1. The thread on the second threaded post 19 is a trapezoidal thread. The trapezoidal thread post has a certain self-locking ability. When the second threaded post 19 stops rotating, it will not move up and down due to external force. Both the positioning plate 8 and the pressure plate 9 are covered with silicone pads 10. The silicone pads 10 can not only play a role in shock absorption, but also prevent the positioning plate 8 and the pressure plate 9 from scratching the IoT host.

[0024] Before installing the IoT host, first adjust the positions of the four positioning plates 8 according to the size of the host. When installing the host, place the IoT host with the interface facing forward and insert it into the protective shell 1 through the placement port. The four positioning plates 8 are respectively supported at the four edges of the bottom of the IoT host shell. Then rotate the knob 20 to press the pressure plate 9 onto the top of the IoT host shell, completing the fixation of the host. Next, connect various network cables to the IoT host through connectors, and then place the network cables in front of the second soft silicone strip 7. Then quickly install the front cover 2 in front of the placement port of the protective shell 1, and then quickly install the two frames 3 on the top and bottom of the protective shell 1 to complete the installation of the device. During the use of the IoT host, the protective shell 1 can play a good protective role for the host, preventing... If the host is damaged by direct external force, the aluminum alloy protective shell 1 can also shield electromagnetic interference, preventing electromagnetic waves generated by other external devices from interfering with the signal transmission of the IoT host. The silicone pads 10 on the positioning plate 8 and pressure plate 9 can effectively absorb shock and reduce the impact of vibration on the host. When the host needs to be cooled, the exhaust fan 5 is connected to the power supply and then started by the controller. After the exhaust fan 5 is started, the air inside the protective shell 1 can be exhausted through the exhaust fan 5, and the outside air can enter through the placement port and waist-shaped through hole on the protective shell 1, thus forming an air duct to remove the heat dissipated by the IoT host. The dust filter 4 on the front cover 2 and frame 3 can prevent dust in the air from entering the interior of the protective shell 1.

[0025] Example 2: Based on Example 1, this example further explains the quick installation method of the front cover 2. The front cover 2 is provided with strip-shaped positioning protrusions 11 on both sides. The protective shell 1 has corresponding positioning grooves on both sides of the placement opening. When installing the front cover 2, the positioning protrusions 11 are embedded into the positioning grooves to achieve the initial positioning of the front cover 2. A pair of buckles 12 are installed between the two sides of the front cover 2 and the two sides of the protective shell 1. Buckles 12 can be fastened to quickly fix the front cover 2 to the protective shell 1. When it is necessary to clean or replace the dust filter 4 on the front cover 2, or to connect or disconnect the network cable on the IoT host, simply open the buckles 12 to remove the front cover 2 together with the dust filter 4. The operation is simple and quick.

[0026] Example 3: Based on Example 1, this example further explains the quick installation method of frame 3. Four positioning iron posts 13 arranged in a rectangular array are fixed on the top and bottom of the protective shell 1. Positioning holes are opened on both the upper and lower frames 3 at the positions corresponding to the positioning iron posts 13, and a magnet 14 is fixed in each positioning hole. When installing frame 3, the positioning holes are aligned with the positioning iron posts 13, and the magnets 14 are attracted to the positioning iron posts 13, thereby realizing the quick installation and disassembly of frame 3, which makes it convenient for operators to clean or replace the dust filter screen 4 on frame 3.

[0027] Finally, it should be noted that the above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model. Although the 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 this utility model should be included within the protection scope of this utility model.

Claims

1. An IoT host protection device for cloud computing, comprising a protective shell (1), characterized in that: The protective shell (1) has a placement opening at the front, and a removable front cover (2) is installed in front of the placement opening. The bottom edge of the front cover (2) and the bottom edge of the placement opening of the protective shell (1) are both provided with grooves, and the first soft silicone strip (6) and the second soft silicone strip (7) are fixed in the two grooves respectively. The two soft silicone strips are in close contact. The front cover (2) has a rectangular through hole. The upper and lower sides of the protective shell (1) have multiple evenly distributed waist-shaped through holes. The upper and lower sides of the protective shell (1) are both provided with a removable frame (3). All through holes on the frame (3) and through holes on the front cover (2) are fixed with dust filters (4). A pair of exhaust fans (5) are installed at the back of the protective shell (1). The bottom of the inner cavity of the protective shell (1) is provided with four positioning plates (8) that can be horizontally adjusted. The top of the inner cavity of the protective shell (1) is provided with a pressure plate (9) that can be moved up and down. The positioning plates (8) and the pressure plate (9) are both covered with silicone pads (10).

2. The IoT host protection device for cloud computing according to claim 1, characterized in that: The front cover (2) is provided with strip-shaped positioning protrusions (11) on both the left and right sides. The protective shell (1) has positioning grooves on both sides corresponding to the two positioning protrusions (11) to cooperate with the positioning protrusions (11). A pair of buckles (12) are installed between the two sides of the front cover (2) and the two sides of the protective shell (1).

3. The IoT host protection device for cloud computing according to claim 1, characterized in that: The protective shell (1) has four positioning iron posts (13) arranged in a rectangular array on its top and bottom. Positioning holes are opened on the upper and lower frames (3) corresponding to the positions of the positioning iron posts (13). A magnet (14) is fixed in each positioning hole and the magnet (14) is attracted to the positioning iron post (13).

4. The IoT host protection device for cloud computing according to claim 1, characterized in that: The positioning plate (8) is L-shaped. Two limiting blocks (15) are fixed at the bottom of the positioning plate (8). The bottom of each limiting block (15) is fixed with a first threaded post (16). The two first threaded posts (16) at the bottom of the positioning plate (8) pass through the waist-shaped through hole at the bottom of the protective shell (1) and are connected to a first nut (17) by threads.

5. The IoT host protection device for cloud computing according to claim 1, characterized in that: The protective shell (1) has a through hole at the top center and a second nut (18) is fixed at the through hole. A second threaded post (19) is connected to the second nut (18) by a thread. The pressure plate (9) is connected to the bottom end of the second threaded post (19) by a universal joint. A knob (20) is fixed to the top end of the second threaded post (19).

6. The IoT host protection device for cloud computing according to claim 1, characterized in that: The protective shell (1) is made of aluminum alloy, and a controller for controlling the operation of the exhaust fan (5) is provided on the outside of the protective shell (1).

7. The IoT host protection device for cloud computing according to claim 1, characterized in that: The protective shell (1) contains an IoT host, and four positioning plates (8) are respectively supported at the four edges of the bottom of the IoT host shell, and a pressure plate (9) is pressed on the top of the IoT host shell.

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