Electronic device with camera lift adjustment
By using conductive parts with movable and fixed connectors for sliding contact between the camera and the motherboard, the problem of camera failure caused by cable bending is solved, achieving stable signal transmission and reducing the failure rate, thus providing protection and reliability for the camera.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- YANTAI HAOZHENG COMMUNICATION ELECTRONICS CO LTD
- Filing Date
- 2026-03-12
- Publication Date
- 2026-06-05
AI Technical Summary
Existing pop-up cameras are prone to damage from bending of their cables during frequent raising and lowering, resulting in a high failure rate.
The system employs a connection component, including a movable connector and a fixed connector. The signal connection between the camera and the motherboard is achieved through the conductive parts of the movable and fixed plates, avoiding cable bending and maintaining stable signal transmission through the sliding contact of the conductive parts.
It effectively reduces the failure rate of cameras, ensures stable signal transmission, avoids damage to ribbon cables, increases the reliability and stability of camera use, and provides buffer protection.
Smart Images

Figure CN122160453A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of electronic equipment technology, and more particularly to an electronic device with a camera that can be raised and lowered for adjustment. Background Technology
[0002] Currently, many electronic devices are equipped with cameras, such as mobile phones and computers. Some of these cameras are fixed, while others are movable. Among the movable cameras, the most common type is the pop-up camera.
[0003] Currently, the conventional pop-up camera in smartphones basically consists of a lead screw, a connecting seat threaded to the lead screw, and a motor. The camera and the connecting seat are installed together, and the motor drives the lead screw to rotate. When working, simply driving the motor to rotate will drive the lead screw to rotate. The rotation of the lead screw will drive the connecting seat to move along the axis of the lead screw, thereby moving the camera and realizing the lifting and lowering of the camera. The structure is simple and therefore widely used.
[0004] However, the aforementioned pop-up camera still has drawbacks, namely: The signal transmission between the camera and the motherboard inside the electronic device is achieved through a ribbon cable. During the frequent raising and lowering of the camera, this ribbon cable will bend repeatedly. After many repetitions, the ribbon cable is prone to damage due to fatigue, which will cause the camera to become unusable and greatly increase the overall failure rate of the camera. Summary of the Invention
[0005] To alleviate or even solve the above-mentioned defects, one object of the present invention is to provide an electronic device with a liftable and adjustable camera, which can reduce the overall failure rate of liftable cameras on electronic devices.
[0006] The specific plan is as follows: An electronic device with a height-adjustable camera includes: a main body of the electronic device and a camera installed inside the main body. The camera is movably installed inside the main body. A window is opened on the upper surface of the main body, which corresponds to the size of the camera, and the camera can slide out from the window. It also includes a connecting component that connects the camera and the main board of the electronic device, and enables signal connection between the camera and the main board of the electronic device through the connecting component. The connecting component includes a movable connector and a fixed connector. The fixed connector is fixedly connected to the main body and maintains a signal connection with the main board of the electronic device. The movable connector is connected to the camera and can slide synchronously with the camera, maintaining a signal connection with the camera. Simultaneously, the movable connector always contacts the fixed connector and maintains a signal connection when it moves.
[0007] Furthermore, the fixed connector includes a fixed plate, which is fixedly installed inside the main body, and has a number of protrusions on its surface. The number of protrusions is consistent with the number of signal lines in the ribbon cable, and a first conductive element is fixedly embedded on the surface of each protrusion. At the same time, the ribbon cable signal lines on the main board are electrically connected to each of the first conductive elements.
[0008] Furthermore, the movable connector includes a movable plate, on which the camera is fixedly mounted. The surface of the movable plate away from the camera has several recesses, the number of which matches the number of protrusions. A second conductive element is fixedly embedded in the center of each recess. The ribbon cable signal lines on the camera are connected to each of the second conductive elements. The protrusions are slidably mounted within the recesses, and the first conductive element contacts and conducts electricity with the second conductive element. When the first conductive element and the second conductive element are connected, the ribbon cable on the motherboard and the ribbon cable on the camera form a signal connection.
[0009] Furthermore, both the protrusion and the recess are trapezoidal, and the first conductive element and the second conductive element are respectively fixedly covered on the outer surface of the protrusion and the inner surface of the recess.
[0010] Furthermore, a first ribbon cable socket is fixedly installed on the fixing plate. The ribbon cable on the motherboard can be inserted into the first ribbon cable socket and electrically connected to it. Several first conductive plates are connected to the first ribbon cable socket and are fixedly connected to the fixing plate. The number of first conductive plates is the same as the number of protrusions, and they are electrically connected to each of the first conductive components.
[0011] Furthermore, a second ribbon cable socket is fixedly installed on the movable plate. The ribbon cable on the camera can be inserted into the second ribbon cable socket and electrically connected to it. Several second conductive pieces are connected to the second ribbon cable socket and are fixedly attached to the movable plate. The number of second conductive pieces is the same as the number of recesses, and they are electrically connected to each of the second conductive pieces.
[0012] Furthermore, the camera also includes a drive assembly, which includes a motor, a lead screw, and a connecting seat. The motor is fixedly installed inside the main body, the lead screw is rotatably installed inside the main body and coaxially connected to the motor output shaft, and the connecting seat is threaded onto the lead screw and fixedly connected to the camera. The drive assembly also includes a guide rod and a guide rail. The guide rod and the guide rail are both fixedly connected to the main body and are respectively distributed on both sides of the camera. The connecting seat has a through hole in the middle and slides on the guide rod through the through hole. The side of the connecting seat has a sliding groove and slides on the guide rail.
[0013] Furthermore, the connecting assembly also includes a pressure member connected between the movable plate and the main body. When the camera slides completely out or into the main body, the pressure member will press against the movable plate and make the first conductive member and the second conductive member fit tightly together.
[0014] Furthermore, the pressure component includes a movable block and a fixed block. The movable block is fixedly connected to the movable plate, and the fixed block is fixedly installed inside the main body. There are two sets of fixed blocks, which are distributed on both sides of the movable block. The opposing surfaces of the fixed block and the movable block are wedge-shaped surfaces. When the camera tends to slide completely out of or into the main body, the wedge-shaped surfaces of the movable block and the fixed block come into contact. The contact between the wedge-shaped surfaces of the fixed block and the movable block will push the movable plate to press against the fixed plate.
[0015] Furthermore, the pressure component also includes a fixed cover and a movable cover. The fixed cover is fixedly installed inside the main body, covers the fixed plate and is in close contact with the surface of the fixed plate. The movable cover is connected to the camera and moves synchronously with the camera. At the same time, the movable cover covers the movable plate and can slide on the surface of the fixed cover.
[0016] The beneficial effects of this invention are: This invention achieves signal connection between the camera and the motherboard inside the electronic device through a connecting component, which can effectively avoid camera damage caused by bending of the ribbon cable, thereby effectively reducing the failure rate of the camera. Furthermore, the movable plate and the fixed plate in the connecting component will automatically increase the contact force between them when the camera slides into place, so as to automatically maintain the stability of the camera during use. It is more reliable than ribbon cable connection. In addition, when the movable plate moves and presses against the fixed plate with the camera, since the camera is about to slide into place, it will also slow down and buffer the movement of the camera, so as to avoid impact caused by sudden stopping or movement of the camera, thus protecting the camera. Attached Figure Description
[0017] The accompanying drawings are provided to further illustrate the invention and form part of the specification. They are used in conjunction with embodiments of the invention to explain the invention and do not constitute a limitation thereof. In the drawings: Figure 1 This is a first-view perspective schematic diagram of the three-dimensional structure of an electronic device with an adjustable camera, as proposed in this invention. Figure 2 This invention proposes an electronic device with an adjustable camera height. Figure 1 Enlarged diagram of point A in the middle.
[0018] Figure 3 This is a second-view schematic diagram of a three-dimensional structure of an electronic device with an adjustable camera, as proposed in this invention.
[0019] Figure 4 This is a schematic diagram of the internal structure of an electronic device connection component with an adjustable camera, as proposed in this invention.
[0020] Figure 5 This invention proposes an electronic device with an adjustable camera height. Figure 4 Enlarged structural diagram at point B.
[0021] Figure 6 This invention proposes an electronic device with an adjustable camera height. Figure 5 Enlarged structural diagram at point B1.
[0022] Figure 7 This is a schematic diagram of the third-view structure of a three-dimensional electronic device with an adjustable camera, as proposed in this invention.
[0023] Figure 8 This invention proposes an electronic device with an adjustable camera height. Figure 7 Enlarged structural diagram at point C.
[0024] Figure 9 This invention proposes an electronic device with an adjustable camera height. Figure 8 Enlarged structural diagram at point C1.
[0025] Figure 10 This is a second-view schematic diagram of the internal structure of an electronic device connection component with an adjustable camera, as proposed in this invention.
[0026] Figure 11 This invention proposes an electronic device with an adjustable camera height. Figure 10 Enlarged structural diagram at point D.
[0027] Figure 12 This is a three-dimensional structural diagram of an electronic device connection component with an adjustable camera, as proposed in this invention.
[0028] Figure 13 This invention proposes an electronic device with an adjustable camera height. Figure 12 Enlarged structural diagram at point E in the middle.
[0029] In the picture: 1. Main body; 11. Window; 2. Camera; 21. Drive assembly; 211. Motor; 212. Lead screw; 213. Connecting seat; 214. Guide rod; 215. Guide rail; 3. Connecting assembly; 31. Movable connector; 311. Movable plate; 312. Recess; 313. Second conductive component; 314. Second ribbon cable socket; 315. Second conductive sheet; 32. Fixed connector; 321. Fixed plate; 322. Protrusion; 323. First conductive component; 324. First ribbon cable socket; 325. First conductive sheet; 33. Pressure component; 331. Movable block; 332. Fixed block; 333. Fixed cover; 334. Movable cover. Detailed Implementation
[0030] The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic diagrams, illustrating only the basic structure of the invention, and therefore only show the components relevant to the invention.
[0031] refer to Figure 1-13 This invention provides an electronic device with a height-adjustable camera, comprising: a main body 1 of the electronic device and a camera 2 installed within the main body 1. The camera 2 is movably installed within the main body 1. A window 11 is provided on the upper surface of the main body 1, which corresponds to the size of the camera 2, and the camera 2 can slide out from the window 11 to achieve height adjustment. In addition, the electronic device provided by this invention also includes a connecting component 3, which connects the camera 2 and the main board of the electronic device, and realizes the signal connection between the camera 2 and the main board of the electronic device through the connecting component 3. The connecting component 3 includes a movable connector 31 and a fixed connector 32. The fixed connector 32 is fixedly connected to the main body 1 and maintains a signal connection with the main board of the electronic device. The movable connector 31 is connected to the camera 2 and can slide synchronously with the camera 2, and maintains a signal connection with the camera 2. At the same time, the movable connector 31 is always in contact with the fixed connector 32 and maintains a signal connection when it is moving.
[0032] During use, when the camera 2 moves, it will drive the movable connector 31 to move synchronously. The movable connector 31 maintains contact and signal connection with the fixed connector 32. At the same time, the fixed connector 32 also maintains signal connection with the motherboard inside the electronic device. Therefore, it can be ensured that the camera 2 and the motherboard inside the electronic device can achieve signal connection, ensuring that the camera 2 can operate stably. In this process, there is no need to bend the ribbon cable to maintain the signal connection during the movement of the camera 2, thereby avoiding damage to the camera 2 caused by the ribbon cable and effectively reducing the failure rate of the camera 2.
[0033] The fixed connector 32 includes a fixed plate 321, which is fixedly installed inside the main body 1 and has a plurality of protrusions 322 on its surface. The number of protrusions 322 is consistent with the number of signal lines in the ribbon cable, and a first conductive element 323 is fixedly embedded on the surface of each protrusion 322. At the same time, the ribbon cable signal lines on the motherboard are electrically connected to each of the first conductive elements 323. The first conductive elements 323 can be made of metal or graphite in the form of a thin sheet. Thus, by simply splitting the ribbon cable on the motherboard (the ribbon cable is formed by multiple wires arranged side by side and fixed, which is the prior art and will not be described in detail in this invention; the splitting in this invention refers to separating the multiple wires one by one), each of the internal signal lines can be electrically connected to a first conductive element 323. The connection can be made to the first conductive element 323 by means of welding or crimping. In this way, the ribbon cable on the motherboard connected to the camera 2 is electrically connected to the first conductive element 323 on the fixed plate 321.
[0034] The movable connector 31 includes a movable plate 311, on which the camera 2 is fixedly mounted. The surface of the movable plate 311 away from the camera 2 is machined with a number of recesses 312, and the number of recesses 312 is the same as the number of protrusions 322. At the same time, a second conductive element 313 is fixedly embedded in the middle of each recess 312. The ribbon cable signal line on the camera 2 is connected to each of the second conductive elements 313. The protrusions 322 are slidably mounted in the recesses 312, and the first conductive element 323 contacts and conducts with the second conductive element 313. When the first conductive element 323 conducts with the second conductive element 313, the ribbon cable on the motherboard and the ribbon cable on the camera 2 form a signal connection.
[0035] The second conductive element 313 can be made of the same material and have the same design as the first conductive element 323. Then, the ribbon cable on the camera 2 is split (the splitting here is the same as the splitting of the motherboard ribbon cable), so that each signal line inside is soldered or crimped to each second conductive element 313 to achieve electrical conduction. In this way, since the protrusion 322 slides in the recess 312 and the first conductive element 323 is in contact with the second conductive element 313, signal transmission between the motherboard and the signal line can be realized. In this way, when the camera 2 moves, it will drive the movable plate 311 to move relative to the fixed plate 321, but the movable plate 311 is always in contact with the fixed plate 321, and the first conductive element 323 is in contact with the second conductive element 313. This can ensure stable signal transmission between the camera 2 and the motherboard, and avoid the ribbon cable bending, effectively reducing the failure rate of the camera 2.
[0036] It is important to note that the ribbon cable signal lines connected to the first conductive element 323 and the second conductive element 313 must correspond one-to-one to avoid signal transmission errors.
[0037] A first ribbon cable socket 324 is fixedly installed on the fixing plate 321. The ribbon cable on the motherboard can be inserted into the first ribbon cable socket 324 and electrically connected to it. Several first conductive pieces 325 are connected to the first ribbon cable socket 324 and are fixedly connected to the fixing plate 321. The number of first conductive pieces 325 is the same as the number of protrusions 322, and they are electrically connected to each of the first conductive parts 323. In this way, installation and maintenance can be greatly facilitated. During installation, the ribbon cable on the motherboard can be inserted into the first ribbon cable socket 324 to achieve connection. During maintenance, the two can be directly separated, and the motherboard or the fixing plate 321 can be maintained separately, avoiding the inconvenience caused by pulling the ribbon cable.
[0038] A second ribbon cable socket 314 is fixedly installed on the movable plate 311. The ribbon cable on the camera 2 can be inserted into the second ribbon cable socket 314 and electrically connected to it. Several second conductive pieces 315 are connected to the second ribbon cable socket 314 and are fixedly attached to the movable plate 311. The number of second conductive pieces 315 is the same as the number of recesses 312, and they are electrically connected to each of the second conductive parts 313 respectively.
[0039] Thus, simply plugging the ribbon cable on camera 2 into the second ribbon cable socket 314 will connect camera 2 to the movable board 311, allowing them to be separated during maintenance for greater convenience.
[0040] The camera 2 also includes a drive assembly 21, which includes a motor 211, a lead screw 212, and a connecting seat 213. The motor 211 is fixedly installed inside the main body 1, the lead screw 212 is rotatably installed inside the main body 1 and coaxially connected to the output shaft of the motor 211, and the connecting seat 213 is threaded onto the lead screw 212 and fixedly connected to the camera 2. The drive assembly 21 also includes a guide rod 214 and a guide rail 215. The guide rod 214 and the guide rail 215 are both fixedly connected to the main body 1 and are respectively distributed on both sides of the camera 2. The connecting seat 213 has a through hole in the middle and slides on the guide rod 214 through the through hole. The side of the connecting seat 213 has a sliding groove and is slidably locked onto the guide rail 215.
[0041] Thus, simply starting the motor 211 will drive the lead screw 212 to rotate, and the rotation of the lead screw 212 will cause the connecting seat 213 to slide, thereby moving the camera 2. The guide rail 215 and the guide rod 214 are two guiding structures that can ensure the smooth sliding of the camera 2.
[0042] In the above solution, during the movement of the movable plate 311, a gap may exist between the first conductive element 323 and the second conductive element 313, which may lead to poor contact between the two and affect signal transmission. Further optimization is needed to address this issue. The connecting component 3 also includes a pressure member 33, which is connected between the movable plate 311 and the main body 1. When the camera 2 slides completely out or into the main body 1, the pressure member 33 will press the movable plate 311 and make the first conductive member 323 and the second conductive member 313 stick together. The pressure member 33 includes a movable block 331 and a fixed block 332. The movable block 331 is fixedly connected to the movable plate 311, and the fixed block 332 is fixedly installed in the main body 1. There are two sets of fixed blocks 332, which are distributed on both sides of the movable block 331. The opposing surfaces of the fixed block 332 and the movable block 331 are wedge-shaped surfaces. When the camera 2 tends to slide completely out or into the main body 1, the wedge-shaped surfaces of the movable block 331 and the fixed block 332 come into contact, and the contact between the wedge-shaped surfaces of the fixed block 332 and the movable block 331 will push the movable plate 311 to stick to the fixed plate 321.
[0043] Thus, as the movable plate 311 moves with the camera 2, it will synchronously drive the movable block 331 to move. When the camera 2 is about to completely slide out of the main body 1 of the electronic device, the wedge surface of the movable block 331 will contact the wedge surface of the fixed block 332, and under the action of the component force generated by the wedge surface, the movable plate 311 will be pressed to move downward toward the fixed plate 321 (this movement is achieved by the elastic bending of the movable plate 311). This will increase the pressure between the movable plate 311 and the fixed plate 321, thereby ensuring that the first conductive element 323 and the second conductive element 313 are in close contact, effectively ensuring the stability of signal transmission.
[0044] Furthermore, the wedge-shaped contact between the movable block 331 and the fixed block 332 will slow down the movement of the movable plate 311, providing a certain buffer during the stopping process of the camera 2, and preventing the camera 2 from suddenly stopping or moving and impacting its internal parts, thus protecting the camera 2.
[0045] The pressure component 33 also includes a fixed cover 333 and a movable cover 334. The fixed cover 333 is fixedly installed inside the main body 1, covers the fixed plate 321 and is in close contact with the surface of the fixed plate 321. The movable cover 334 is connected to the camera 2 and moves synchronously with the camera 2. At the same time, the movable cover 334 covers the movable plate 311 and can slide on the surface of the fixed cover 333.
[0046] Thus, the fixed cover 333 can limit the fixed plate 321, preventing the fixed plate 321 from bending or even being damaged during the process of the movable plate 311 pressing against the fixed plate 321. The movable cover 334 can cover the movable plate 311 when it moves, and at the same time prevent other objects from entering between the movable plate 311 and the fixed plate 321, thus providing further protection.
[0047] It should be noted that the movable plate 311 needs to be made of a material with a certain degree of elastic deformation, such as acrylic or PCB board, to ensure that the movable plate 311 can be bent to move closer to the fixed plate 321.
[0048] In the above scheme, misalignment or offset may occur during the mutual movement of the first conductive element 323 and the second conductive element 313. Further optimization is needed to address this: Both the protrusion 322 and the recess 312 are trapezoidal, and the first conductive element 323 and the second conductive element 313 are respectively fixedly covered on the outer surface of the protrusion 322 and the inner surface of the recess 312.
[0049] In this way, compared with a single plane, the contact area can be increased, ensuring the stability of signal transmission. At the same time, it can also have a good guiding effect. In addition, it can maintain good alignment between the movable plate 311 and the fixed plate 321, avoiding misalignment between the movable plate 311 and the fixed plate 321, and also greatly facilitating installation.
[0050] Therefore, the complete workflow is as follows: First, the motor 211 is started, which drives the lead screw 212 to rotate. The rotation of the lead screw 212 causes the connecting seat 213 to slide, thereby moving the camera 2. During the movement of the camera 2, the movable plate 311 moves relative to the fixed plate 321, but the movable plate 311 always remains in contact with the fixed plate 321, ensuring that the first conductive element 323 and the second conductive element 313 are in contact. This ensures stable signal transmission between the camera 2 and the motherboard. The entire process eliminates the need for cable bending to achieve signal transmission, thus avoiding cable bending and effectively reducing the failure rate of the camera 2. Furthermore, as the movable plate 311 moves with the camera 2, it synchronously moves... When the movable block 331 moves, and the camera 2 is about to slide completely out of the main body 1 of the electronic device, the wedge surface of the movable block 331 will contact the wedge surface of the fixed block 332 and move towards the fixed plate 321 under its guidance. This will increase the pressure between the movable plate 311 and the fixed plate 321, thereby ensuring that the first conductive element 323 and the second conductive element 313 are in close contact, thus further ensuring the stability of signal transmission. Moreover, the contact between the wedge surfaces of the movable block 331 and the fixed block 332 will also slow down the movement of the movable plate 311, so that the camera 2 has a certain buffer during the stopping process, avoiding the impact on the internal parts of the camera 2 if the camera 2 stops or moves suddenly, thus playing a protective role for the camera 2.
[0051] In summary, this invention achieves signal connection between the camera 2 and the motherboard inside the electronic device through the connecting component 3, which can effectively avoid damage to the camera 2 caused by bending of the ribbon cable, thereby effectively reducing the failure rate of the camera 2. Furthermore, the movable plate 311 and the fixed plate 321 in the connecting component 3 will automatically increase the contact force between them when the camera 2 slides into place, so as to automatically maintain the stability of the camera 2 during use. This is more reliable than ribbon cable connection. In addition, when the movable plate 311 moves and presses against the fixed plate 321 with the camera 2, since the camera 2 is about to slide into place, it will also slow down and buffer the movement of the camera 2, so as to avoid the camera 2 from suddenly stopping or moving and causing impact, thus protecting the camera 2.
[0052] The above description is only a preferred embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in the present invention, based on the technical solution and inventive concept of the present invention, should be covered within the scope of protection of the present invention.
Claims
1. An electronic device with a height-adjustable camera, comprising: The electronic device has a main body (1) and a camera (2) installed inside the main body (1). The camera (2) is movably installed inside the main body (1). A window (11) is provided on the upper surface of the main body (1), which corresponds to the size of the camera (2), and the camera (2) can slide out from the window (11). The feature is that it further includes a connecting component (3), which is connected between the camera (2) and the motherboard of the electronic device, and the signal connection between the camera (2) and the motherboard of the electronic device is realized through the connecting component (3). The connecting component (3) includes a movable connector (31) and a fixed connector (32). The fixed connector (32) is fixedly connected to the main body (1) and maintains a signal connection with the motherboard of the electronic device. The movable connector (31) is connected to the camera (2) and can slide synchronously with the camera (2). The movable connector (31) maintains a signal connection with the camera (2). At the same time, when the movable connector (31) is moving, it is always in contact with the fixed connector (32) and maintains a signal connection.
2. The electronic device with an adjustable camera according to claim 1, characterized in that, The fixed connector (32) includes a fixed plate (321), which is fixedly installed in the main body (1) and has a number of protrusions (322) on its surface. The number of protrusions (322) is consistent with the number of signal lines in the ribbon cable, and a first conductive element (323) is fixedly embedded on the surface of each protrusion (322). At the same time, the ribbon cable signal lines on the main board are electrically connected to each of the first conductive elements (323).
3. The electronic device with an adjustable camera according to claim 2, characterized in that, The movable connector (31) includes a movable plate (311), and the camera (2) is fixedly mounted on the movable plate (311). The surface of the movable plate (311) away from the camera (2) is processed with a number of recesses (312), and the number of recesses (312) is the same as the number of protrusions (322). At the same time, a second conductive element (313) is fixedly embedded in the middle of each recess (312). The ribbon cable signal line on the camera (2) is connected to each of the second conductive elements (313). The protrusion (322) is slidably mounted in the recess (312), and the first conductive element (323) contacts and conducts with the second conductive element (313). When the first conductive element (323) and the second conductive element (313) are connected, the ribbon cable on the motherboard and the ribbon cable on the camera (2) form a signal connection.
4. The electronic device with an adjustable camera according to claim 3, characterized in that, Both the protrusion (322) and the recess (312) are trapezoidal, and the first conductive element (323) and the second conductive element (313) are respectively fixedly covered on the outer surface of the protrusion (322) and the inner surface of the recess (312).
5. An electronic device with a height-adjustable camera according to claim 2, characterized in that, A first ribbon cable socket (324) is fixedly installed on the fixing plate (321). The ribbon cable on the main board can be inserted into the first ribbon cable socket (324) and electrically connected to it. A number of first conductive pieces (325) are connected to the first ribbon cable socket (324), which are fixedly connected to the fixing plate (321). The number of first conductive pieces (325) is the same as the number of protrusions (322), and they are electrically connected to each first conductive component (323).
6. The electronic device with an adjustable camera according to claim 3, characterized in that, The second ribbon cable socket (314) is fixedly installed on the movable plate (311). The ribbon cable on the camera (2) can be inserted into the second ribbon cable socket (314) and electrically connected to it. Several second conductive pieces (315) are connected to the second ribbon cable socket (314), which are fixedly attached to the movable plate (311). The number of second conductive pieces (315) is the same as the number of recesses (312), and they are electrically connected to each of the second conductive parts (313).
7. The electronic device with a height-adjustable camera according to claim 1, characterized in that, The camera (2) also includes a drive assembly (21), which includes a motor (211), a lead screw (212), and a connecting seat (213). The motor (211) is fixedly installed inside the main body (1), the lead screw (212) is rotatably installed inside the main body (1) and coaxially connected with the output shaft of the motor (211). The connecting seat (213) is threaded onto the lead screw (212) and fixedly connected to the camera (2). The drive assembly (21) also includes a guide rod (214) and a guide rail (215). The guide rod (214) and the guide rail (215) are both fixedly connected to the main body (1) and are respectively distributed on both sides of the camera (2). The connecting seat (213) has a through hole in the middle and slides on the guide rod (214) through the through hole. The connecting seat (213) has a sliding groove on its side and slides on the guide rail (215).
8. An electronic device with an adjustable camera according to claim 3, characterized in that, The connecting component (3) also includes a pressure member (33), which is connected between the movable plate (311) and the main body (1). When the camera (2) slides out or in completely from the main body (1), the pressure member (33) will press the movable plate (311) and make the first conductive member (323) and the second conductive member (313) stick together.
9. An electronic device with a height-adjustable camera according to claim 8, characterized in that, The pressure component (33) includes a movable block (331) and a fixed block (332). The movable block (331) is fixedly connected to the movable plate (311). The fixed block (332) is fixedly installed inside the main body (1). There are two sets of fixed blocks (332), which are distributed on both sides of the movable block (331). The surfaces of the fixed block (332) and the movable block (331) are wedge-shaped. When the camera (2) tends to slide completely out of or into the main body (1), the wedge-shaped surfaces of the movable block (331) and the fixed block (332) come into contact. The contact between the fixed block (332) and the wedge-shaped surfaces of the movable block (331) will push the movable plate (311) to press against the fixed plate (321).
10. An electronic device with a height-adjustable camera according to claim 9, characterized in that, The pressure component (33) also includes a fixed cover (333) and a movable cover (334). The fixed cover (333) is fixedly installed inside the main body (1), covers the fixed plate (321) and is in close contact with the surface of the fixed plate (321). The movable cover (334) is connected to the camera and moves synchronously with the camera (2). At the same time, the movable cover (334) covers the movable plate (311) and can slide on the surface of the fixed cover (333).