Embedded computer all-in-one machine
By introducing a rotatable support frame and worm gear structure into the embedded all-in-one computer, combined with a flexible telescopic frame and snap-fit plate, the problem of fixed display angle is solved, enabling multi-angle adjustment and effective heat dissipation, thus improving operational convenience and equipment stability.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- HUILIAN CLOUD TECH(SHENZHEN) CO LTD
- Filing Date
- 2025-07-25
- Publication Date
- 2026-06-26
Smart Images

Figure CN224417228U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of embedded computer all-in-one technology, and in particular to an embedded computer all-in-one. Background Technology
[0002] Embedded all-in-one computers are application-centric, customizable hardware and software systems. Their hardware is highly integrated into a single board or compact structure (such as CPU, memory, and storage integrated) and embedded in the host device to achieve intelligent control functions. Hardware is customized for specific tasks (such as industrial control / medical image processing), redundant components are removed, and functions are focused through hardware and software co-optimization to ensure long-term stable operation of vehicle and aviation equipment.
[0003] Traditional embedded all-in-one computers typically use snap-fit or bolt connections. However, once installed, the all-in-one computer has a fixed installation angle, making it difficult to rotate the display screen to a certain angle as needed. This can affect the use by operators of different heights. Therefore, an embedded all-in-one computer is proposed to solve the above problems. Utility Model Content
[0004] The purpose of this utility model is to overcome the shortcomings of the prior art and provide an embedded computer all-in-one machine, which effectively solves the deficiencies of the prior art.
[0005] To achieve the above objectives, one embodiment of this utility model provides an embedded all-in-one computer, including a mounting shell. A support frame capable of rotating at a certain angle is installed inside the mounting shell. A worm gear is installed on one side of the middle portion of the support frame. A worm gear meshing with the worm gear is rotatably installed on the side wall of the mounting shell. The top end of the worm gear protrudes upward from the mounting shell, and a knob is installed at its end. Four snap-fit plates are rotatably installed in the middle of the support frame. One end of each of the four snap-fit plates is snapped into the all-in-one computer body. A support spring is installed between the other end of each of the four snap-fit plates and the support frame. A flexible telescopic frame is installed between the side of the all-in-one computer body and the side of the mounting shell.
[0006] Preferably, in any of the above embodiments, the mounting shell has multiple air inlets in the middle of the side away from the computer all-in-one body, and hollow support columns are installed at the four corners of the side of the mounting shell away from the computer all-in-one body. Two fans are installed on the inner wall of the mounting shell near the multiple air inlets. This design facilitates the operation of the fans, allowing external air to enter the interior of the mounting shell through the air inlets and flow towards the heat dissipation fins on the side of the computer all-in-one body to dissipate heat from the computer all-in-one body. In addition, the hollow support columns have a stepped shape at the end away from the mounting shell, which facilitates the fixed connection with external devices by screws. The hollow support columns leave a certain distance between the mounting shell and the external devices, allowing air to enter the interior of the mounting shell through the air inlets.
[0007] Preferably, in any of the above solutions, the mounting shell has through holes on both the top and bottom surfaces near the supporting spring, and the four through holes are fitted with sealing plugs. This solution facilitates the sealing plugs to engage the through holes, thereby achieving the purpose of sealing them. When disassembling the all-in-one computer body, a tool is used to press the end of the buckle plate along the through hole, causing the buckle plate to rotate relative to the support frame and separating the end of the buckle plate from the slot, making it convenient for the operator to disassemble the all-in-one computer body.
[0008] Preferably, in any of the above solutions, the support frame is fitted with limit clips on the side near the buckle plate. A gap is left between the end of each of the four limit clips near the buckle plate and the buckle plate. This design ensures a certain distance between the limit clips and the buckle plate. When the all-in-one computer body is disassembled, the buckle plate rotates under the pushing force of the support spring and abuts against the end of the limit clip, preventing excessive rotation of the buckle plate. Simultaneously, due to the support of the limit clips, when installing the all-in-one computer body, simply press the computer body towards the buckle plate. The inclined surface at the end of the buckle plate slides relative to the outer wall of the all-in-one computer body, thus engaging with the slot.
[0009] Preferably, in any of the above solutions, the outer wall of the all-in-one computer body near the buckle plate has a slot that engages with the ends of the buckle plate. The all-in-one computer body has multiple heat dissipation fins installed near the fan side. This solution facilitates the airflow towards the multiple heat dissipation fins when the fan is powered on, thereby exchanging heat and cooling the all-in-one computer body.
[0010] Preferably, in any of the above solutions, the top and bottom surfaces of the flexible telescopic frame are provided with multiple ventilation slots, and both ends of the flexible telescopic frame are bent inward. In this solution, the multiple ventilation slots facilitate the outward flow of air. The flexible telescopic frame is made of square corrugated rubber tubing, and both ends of the flexible telescopic frame are connected to the mounting shell and the side of the all-in-one computer body by adhesive bonding. By rotating the tilt angle of the all-in-one computer body, the flexible telescopic frame is stably connected to both of them, providing a certain degree of protection for internal support frames and other components.
[0011] This utility model has the following advantages:
[0012] 1. This embedded all-in-one computer features a support frame with four snap-fit plates installed in the middle. These plates engage with slots under the pushing action of support springs. Both ends of the support frame are rotatably connected to the mounting housing. A worm gear at one end of the support frame meshes with a worm. Rotating a knob causes the worm and worm gear to rotate relative to each other, thereby driving the support frame and the all-in-one computer body to rotate at a certain angle, changing their tilt angle to facilitate viewing by operators of different heights. This effectively solves the problems existing in the prior art. Furthermore, the overall structure is simple, the design is reasonable, and it is easy to promote and use.
[0013] 2. This embedded all-in-one computer features a mounting shell with a flexible telescopic frame installed between it and the all-in-one computer body. When the all-in-one computer body tilts or rotates at a certain angle, the flexible telescopic frame extends or shortens to compensate for the gap between the mounting shell and the all-in-one computer body, ensuring overall aesthetics. Two through holes are provided on the top and bottom surfaces of the mounting shell, each containing a sealing plug. Removing the sealing plug and pressing the end of the snap-fit plate with a tool separates the snap-fit plate from the slot, facilitating the removal of the all-in-one computer body and enabling convenient operation.
[0014] 3. This embedded all-in-one computer features a flexible telescopic frame with multiple ventilation slots on both the top and bottom surfaces. Two powered fans drive external air to flow into the all-in-one computer body and out through the ventilation slots, facilitating heat dissipation for the all-in-one computer body. Attached Figure Description
[0015] Figure 1 This is a first-view structural diagram of the entire utility model;
[0016] Figure 2 This is a second-view structural diagram of the entire utility model;
[0017] Figure 3This is a cross-sectional view of the overall structure of this utility model;
[0018] Figure 4 This is a schematic diagram of the outer shell structure of this utility model;
[0019] Figure 5 This is a schematic diagram of the support frame structure of this utility model;
[0020] Figure 6 This is a schematic diagram of the main body structure of the all-in-one computer of this utility model;
[0021] Figure 7 This is a schematic diagram of the flexible telescopic frame structure of this utility model.
[0022] In the diagram: 1-Mounting shell, 2-Flexible telescopic frame, 3-Computer all-in-one body, 4-Ventilation slot, 5-Sealing plug, 7-Knob, 9-Air inlet, 10-Hollow support column, 11-Fan, 12-Support frame, 13-Support spring, 14-Snap plate, 15-Limiting clip, 16-Worm gear, 17-Worm wheel, 18-Slot. Detailed Implementation
[0023] The present invention will be further described below with reference to the accompanying drawings, but the scope of protection of the present invention is not limited to the following description.
[0024] like Figures 1 to 7 As shown, an embedded all-in-one computer includes a mounting shell 1. Inside the mounting shell 1 is a support frame 12 that can rotate at a certain angle. A worm gear 17 is mounted on one side of the middle of the support frame 12. A worm 16, meshing with the worm gear 17, is rotatably mounted on the side wall of the mounting shell 1. The top of the worm 16 protrudes upward from the mounting shell 1, and a knob 7 is mounted at its end. Four latching plates 14 are rotatably mounted in the middle of the support frame 12. One end of each of the four latching plates 14 is engaged with the all-in-one computer body 3, which is located close to the mounting shell 1. The outer wall is provided with bevels, and support springs 13 are installed between the other ends of the four buckle plates 14 and the support frame 12. A flexible telescopic frame 2 is installed between the side of the computer all-in-one body 3 and the side of the mounting shell 1. The middle part of the support frame 12 is square in shape, and limit rings are installed at its four corners and the ends of the buckle plates 14. The limit rings facilitate the installation position of the support springs 13, so that the support springs 13 can stably support the ends of the buckle plates 14, and at the same time push the other end of the buckle plates 14 to stably engage with the slots 18, thereby improving the connection stability.
[0025] One side of the middle of the buckle plate 14 is rotatably connected to the middle of the support frame 12 by a pin. The buckle plate 14 is pushed by the elastic force of the support spring 13. The four buckle plates 14 are provided with an angle at the end away from the support frame 12, which facilitates sliding along the outer wall of the computer all-in-one body 3 and engaging with the slot 18, making it convenient for operators to install the computer all-in-one body 3.
[0026] Multiple air inlets 9 are provided in the middle of the side of the mounting shell 1 away from the computer all-in-one body 3. Hollow support columns 10 are installed at the four corners of the side of the mounting shell 1 away from the computer all-in-one body 3. Two fans 11 are installed on the inner wall of the mounting shell 1 near the multiple air inlets 9. As an optional technical solution of this utility model, this facilitates the operation of the fans 11, allowing external air to enter the interior of the mounting shell 1 through the air inlets 9 and flow towards the heat dissipation fins on the side of the computer all-in-one body 3 to dissipate heat from the computer all-in-one body 3. In addition, the hollow support column 10 has a stepped shape at the end away from the mounting shell 1, which facilitates the fixed connection with external devices by screws. The hollow support column 10 leaves a certain distance between the mounting shell 1 and the external devices, allowing air to enter the interior of the mounting shell 1 through the air inlets 9.
[0027] The mounting shell 1 has through holes on its top and bottom surfaces near the support spring 13, and the four through holes are fitted with sealing plugs 5. As an optional technical solution of this utility model, this makes it easy for the sealing plugs 5 to engage with the through holes and achieve the purpose of sealing the through holes. When disassembling the computer all-in-one body 3, a tool is used to press the end of the buckle plate 14 along the through hole, so that the buckle plate 14 and the support frame 12 rotate relative to each other and the end of the buckle plate 14 separates from the buckle groove 18, making it convenient for the operator to disassemble the computer all-in-one body 3.
[0028] Limiting clips 15 are installed on the side of the support frame 12 near the clip plate 14. There is a gap between the end of the four limiting clips 15 near the clip plate 14 and the clip plate 14. As an optional technical solution of this utility model, this makes it easy to leave a certain distance between the limiting clips 15 and the clip plate 14. When the computer all-in-one body 3 is disassembled, the clip plate 14 is pushed by the support spring 13 and rotates, and abuts against the end of the limiting clip 15, so as to prevent the clip plate 14 from rotating excessively. At the same time, due to the support of the limiting clips 15, when installing the computer all-in-one body 3, it is only necessary to press the computer all-in-one body 3 towards the clip plate 14. The inclined surface at the end of the clip plate 14 slides relative to the outer wall of the computer all-in-one body 3, thereby engaging with the slot 18.
[0029] The computer all-in-one body 3 has a slot 18 on the outer wall near the buckle plate 14, which is engaged with the ends of the buckle plate 14. Multiple heat dissipation fins are installed on the side of the computer all-in-one body 3 near the fan 11. As an optional technical solution of this utility model, this facilitates the airflow to the multiple heat dissipation fins when the fan 11 is powered on, and then heat exchange occurs to dissipate heat from the computer all-in-one body 3.
[0030] Multiple ventilation slots 4 are provided on the top and bottom surfaces of the flexible telescopic frame 2. Both ends of the flexible telescopic frame 2 are bent inward. As an optional technical solution of this utility model, the multiple ventilation slots 4 facilitate the outward flow of air. The flexible telescopic frame 2 is made of square corrugated rubber tubing. The two ends of the flexible telescopic frame 2 are connected to the side of the mounting shell 1 and the computer all-in-one body 3 by adhesive. By rotating the tilt angle of the computer all-in-one body 3, the flexible telescopic frame 2 is stably connected to both of them, providing a certain degree of protection for internal support frame 12 and other parts.
[0031] This type of embedded all-in-one computer requires the following steps to use:
[0032] 1) When in use, rotate knob 7 to drive the worm gear 16 and worm wheel 17 to rotate relative to each other, which in turn drives the support frame 12 and mounting shell 1 to rotate relative to each other.
[0033] 2) The support frame 12 drives the all-in-one computer body 3 to rotate at a certain angle, changing its tilt state, making it easier for users of different heights to operate and use it;
[0034] 3) The two fans 11 are powered on and run simultaneously, driving external air into the interior of the mounting shell 1 through multiple air inlets 9 and blowing it onto the heat dissipation fins of the all-in-one computer body 3 to dissipate heat from the all-in-one computer body 3.
[0035] 4) Air flows outward from multiple ventilation slots 4.
[0036] In summary, during use, the support frame 12 has four latching plates 14 installed in its middle. These four latching plates 14 engage with the latching slots 18 under the pushing action of the support spring 13. Both ends of the support frame 12 are rotatably connected to the mounting shell 1. A worm gear 17 at one end of the support frame 12 meshes with a worm 16. Rotating the knob 7 causes the worm 16 and worm gear 17 to rotate relative to each other, thus driving the support frame 12 and the all-in-one computer body 3 to rotate at a certain angle, changing their tilt angle. This facilitates viewing for operators of different heights, effectively solving the problems existing in the prior art. Furthermore, the overall structure is simple, the design is reasonable, and it is easy to promote and use. Additionally, by setting up the mounting shell 1, a flexible telescopic frame 2 is installed between it and the all-in-one computer body 3, thus allowing the all-in-one computer body 3 to... When tilted and rotated at a certain angle, the flexible telescopic frame 2 extends or shortens to compensate for the gap between the mounting shell 1 and the all-in-one computer body 3, ensuring the overall aesthetics. Two through holes are opened on the top and bottom surfaces of the mounting shell 1, and sealing plugs 5 are installed inside each hole. The sealing plugs 5 are removed, and the end of the buckle plate 14 is pressed with a tool to separate the buckle plate 14 from the buckle slot 18, making it easy to remove the all-in-one computer body 3 and facilitate the operation of the operator. Finally, by setting up the flexible telescopic frame 2, and by opening multiple ventilation slots 12 on the top and bottom surfaces of the flexible telescopic frame 2, two fans 11 are powered on to drive the external air to flow into the all-in-one computer body 3 and out through the multiple ventilation slots 12, which facilitates the heat dissipation of the all-in-one computer body 3.
[0037] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. An embedded all-in-one computer, characterized in that: The system includes a mounting shell (1), inside which a support frame (12) capable of rotating at a certain angle is installed. A worm gear (17) is installed on one side of the middle part of the support frame (12). A worm (16) meshing with the worm gear (17) is rotatably installed on the side wall of the mounting shell (1). The top end of the worm (16) protrudes upward from the mounting shell (1), and a knob (7) is installed at its end. Four snap-fit plates (14) are rotatably installed in the middle part of the support frame (12). One end of the four snap-fit plates (14) is snapped together with the computer all-in-one body (3). The other end of the four snap-fit plates (14) is connected to the support frame (12) with a support spring (13). A flexible telescopic frame (2) is installed between the side of the computer all-in-one body (3) and the side of the mounting shell (1).
2. An embedded all-in-one computer according to claim 1, characterized in that: The mounting shell (1) has multiple air inlets (9) in the middle of the side away from the computer all-in-one body (3). Hollow support columns (10) are installed at the four corners of the side of the mounting shell (1) away from the computer all-in-one body (3). Two fans (11) are installed on the inner wall of the mounting shell (1) near the multiple air inlets (9).
3. An embedded all-in-one computer according to claim 2, characterized in that: The mounting shell (1) has through holes on its top and bottom surfaces near the support spring (13), and the four through holes are fitted with sealing plugs (5).
4. An embedded all-in-one computer according to claim 3, characterized in that: The support frame (12) is fitted with limit clips (15) on the side near the buckle plate (14), and there is a gap between the end of the four limit clips (15) near the buckle plate (14) and the buckle plate (14).
5. An embedded all-in-one computer according to claim 4, characterized in that: The computer all-in-one body (3) has a slot (18) on the outer wall near the buckle plate (14), which is engaged with the end of the buckle plate (14). The computer all-in-one body (3) has multiple heat dissipation fins installed on the side near the fan (11).
6. An embedded all-in-one computer according to claim 5, characterized in that: The top and bottom surfaces of the flexible telescopic frame (2) are provided with multiple ventilation slots (4), and both ends of the flexible telescopic frame (2) are bent inward.