CN109782853B

CN109782853B - Push type camera assembly and electronic equipment

Info

Publication number: CN109782853B
Application number: CN201910119078.8A
Authority: CN
Inventors: 姜玉杰
Original assignee: Guangdong Hongqin Communication Technology Co Ltd
Current assignee: Guangdong Hongqin Communication Technology Co Ltd
Priority date: 2019-02-15
Filing date: 2019-02-15
Publication date: 2020-07-10
Anticipated expiration: 2039-02-15
Also published as: CN109782853A

Abstract

The invention discloses a push type camera component, which comprises a mounting shell, a camera module, a first elastic piece, a track plate and a second elastic piece, wherein the top wall of the mounting shell is provided with an opening; the camera module is arranged on the mounting shell and can extend out or retract from the opening, and a side wall of the camera module forms a sliding block; the first elastic piece is arranged between the bottom of the camera module and the bottom wall; the track plate is provided with a downward moving chute, a clamping groove and an upward moving chute, the downward moving chute inclines rightwards from top to bottom, the right side of the clamping groove is communicated to the left side of the bottom of the downward moving chute, a left stopping part is formed on the left side of the clamping groove, an upper stopping part is formed on the upper side of the clamping groove, the bottom of the upward moving chute is positioned on the left side of the left stopping part, and the top of the; the left end of the second elastic piece is connected to the right end of the track plate, and the right end of the second elastic piece is connected to the mounting shell. The invention can prevent hijacking and candid shooting and has the advantages of simple and reliable structure and convenient operation. In addition, the invention also discloses an electronic device.

Description

Push type camera assembly and electronic equipment

Technical Field

The invention relates to the technical field of push type cameras, in particular to a push type camera assembly and electronic equipment.

Background

The cameras of most notebook computers on the market are placed above the screen, due to the fact that the cameras need to be placed in a staggered mode with the inner frame of the screen under the influence of thickness, the frame of the screen above the screen is wide, the trend of pursuing trend of the current screen occupation ratio is extremely high, and visual attractiveness is affected. More importantly, the camera cannot be shielded when not in use, so that the current society has higher risks of hijacking and candid shooting.

Disclosure of Invention

The invention aims to provide a pressing type camera component which can effectively prevent the risks of hijacking and candid shooting when a camera is not used.

Another object of the present invention is to provide an electronic device, which can effectively prevent the risk of hijacking and candid shooting when the camera is not in use.

In order to achieve the above object, the present invention provides a push type camera assembly, including a mounting housing, a camera module, a first elastic element, a track plate and a second elastic element, wherein the mounting housing includes a top wall and a bottom wall which are oppositely arranged, and the top wall is provided with an opening; the camera module is arranged in the mounting shell and can extend out or retract from the opening, and a sliding block is formed on one side wall of the camera module; the first elastic piece is arranged between the bottom of the camera module and the bottom wall; the track plate is arranged facing the side wall of the sliding block formed by the camera module, a track groove matched with the sliding block is formed in the track plate, the track groove comprises a downward moving sliding groove, a clamping groove and an upward moving sliding groove, the downward moving sliding groove is gradually inclined towards the right from top to bottom, the right side of the clamping groove is communicated to the left side of the bottom of the downward moving sliding groove, a left stopping part is formed on the left side of the clamping groove, an upper stopping part is formed on the upper side of the clamping groove, the bottom of the upward moving sliding groove is located on the left side of the left stopping part, and the top of the upward moving sliding groove is communicated with the top of the downward moving; the left end of the second elastic piece is connected to the right end of the track plate, and the right end of the second elastic piece is connected to the mounting shell; when the camera module is stored, the camera module is pressed to enable the sliding block to slide downwards along the downward moving chute, the first elastic piece is compressed downwards, the track plate is gradually pushed leftwards by the sliding block, the second elastic piece is stretched, and when the sliding block slides to a position corresponding to the clamping groove, the restoring force of the second elastic piece drives the track plate to slide rightwards to enable the sliding block to be clamped into the clamping groove; pressing the camera module to enable the sliding block to exceed the left stopping portion downwards, wherein the restoring force of the second elastic piece drives the track plate to continuously slide rightwards so that the sliding block is free from the limitation of the left stopping portion; the upward restoring force of the first elastic piece can enable the sliding block which is free from the limitation of the left stopping portion to slide upwards along the upward moving sliding groove so as to reset to the top of the downward moving sliding groove.

Preferably, the slider includes a left inclined surface and a right inclined surface which are parallel, and a left vertical surface and a right vertical surface which are parallel, the left inclined surface and the right inclined surface are respectively matched with the two inclined side walls of the downward moving chute, and the left vertical surface and the right vertical surface are respectively matched with the two vertical side walls of the upward moving chute.

Preferably, the upward-moving sliding groove includes an inclined groove and a vertical groove, the inclined direction of the inclined groove is the same as the inclined direction of the downward-moving sliding groove, the inclined groove includes a right inclined wall, the vertical groove forms two vertical side walls, the bottom of the vertical groove is communicated with the top of the inclined groove, the upward restoring force of the first elastic member can enable the sliding block, which gets rid of the limitation of the left stopper, to slide obliquely upward along the inclined groove and then slide upward along the vertical groove, and when the sliding block slides upward along the inclined groove, the right inclined surface is matched with the right inclined wall of the inclined groove.

Preferably, the upward restoring force of the first elastic member causes the slider to push the track plate to generate a rightward displacement in the process of sliding along the upward sliding slot so as to compress the second elastic member.

Preferably, the top of the vertical groove is communicated with the top of the downward moving chute through a horizontal chute.

Preferably, an inner angle of a communication portion between the clamping groove and the downward moving chute forms a vertical tangent plane, and when the left inclined plane of the slider downwardly crosses the corresponding inclined side wall of the downward moving chute, the left vertical plane of the slider downwardly slides along the vertical tangent plane to exceed the vertical tangent plane so that the slider is clamped in the clamping groove.

Preferably, the left stopper portion has a vertical stopper surface, and the vertical stopper surface is engaged with the left vertical surface of the slider.

Preferably, the sliding block further comprises a horizontal top surface, the upper stop part is provided with a horizontal stop surface, and the horizontal stop surface is matched with the horizontal top surface of the sliding block; the left stopping portion is provided with a horizontal bottom surface, and the horizontal bottom surface is matched with the horizontal top surface of the sliding block.

In order to achieve another object, the invention provides an electronic device comprising the pressing type camera assembly.

Preferably, the electronic device includes a body and a screen body that are pivotable with each other, and a pivot cover is provided between the body and the screen body as the mounting housing.

Compared with the prior art, when the camera module is stored, the sliding block slides downwards along the downward moving chute by pressing the camera module, the first elastic piece is compressed downwards, the track plate is gradually pushed leftwards by the sliding block, the second elastic piece is stretched, and when the sliding block slides to the position corresponding to the clamping groove, the restoring force of the second elastic piece drives the track plate to slide rightwards to clamp the sliding block into the clamping groove, so that the press type camera module can be retracted into the mounting shell, namely, is in a storage state, and the conditions of being hijacked and being shot illegally can be prevented. When the camera module needs to be used, the camera module is pressed again to enable the sliding block to exceed the left stopping portion downwards, and at the moment, the restoring force of the second elastic piece drives the track plate to continuously slide rightwards to enable the sliding block to get rid of the limitation of the left stopping portion; then the upward restoring force of the first elastic piece can enable the sliding block which gets rid of the limitation of the left stopping portion to slide upwards along the upward moving sliding groove so as to reset to the top of the downward moving sliding groove. Therefore, the push type camera component has the advantages of simple and reliable structure and convenience in operation while preventing hijacking and candid shooting. In addition, when the push type camera assembly is used on electronic equipment similar to a notebook computer, the rotating shaft cover between the screen body and the body can be used as a push type camera assembly mounting shell, namely, the camera module and other structures can be mounted at the rotating shaft cover instead of the screen frame, so that the screen occupation ratio of the screen body is favorably improved.

Drawings

Fig. 1 is a schematic perspective view of an electronic device according to an embodiment of the present invention.

Fig. 2 is a schematic perspective view of a push-type camera assembly according to an embodiment of the present invention.

FIG. 3 is an exploded view of a push-type camera assembly according to an embodiment of the present invention.

Fig. 4 is a schematic perspective view of a camera module according to an embodiment of the invention.

Fig. 5 is an enlarged view of a portion a in fig. 4.

Fig. 6 is a schematic perspective view of a track plate according to an embodiment of the present invention.

Fig. 7 is a schematic diagram illustrating a state change of a push-type camera assembly when the camera module is switched from an extended state to a retracted state according to an embodiment of the present invention.

Fig. 8 is a schematic diagram illustrating a state change of a push-type camera assembly when the camera module is switched from the storage state to the extension state according to the embodiment of the present invention.

Detailed Description

The following detailed description is given with reference to the accompanying drawings for illustrating the contents, structural features, and objects and effects of the present invention.

In the description of the present invention, it is to be understood that the terms "top," "bottom," "upper," "lower," "left," "right," and the like are used in the orientations indicated in the drawings only for convenience in describing the present invention, and do not indicate or imply that the referenced devices or elements must be in a particular orientation and, therefore, are not to be considered limiting of the scope of the present invention. In addition, the sliding block or the sliding fingers of the camera module which slide leftwards or rightwards relatively slide.

Referring to fig. 1 to 8, the present invention discloses a push type camera assembly 100 disposed on an electronic device 1, including a mounting housing 10, a camera module 30, a first elastic element 50, a track plate 60 and a second elastic element 80, wherein the mounting housing 10 includes a top wall 11 and a bottom wall 12 disposed oppositely, the top wall 11 is provided with an opening 13; the camera module 30 is arranged in the mounting shell 10 and can extend out or retract from the opening 13, and a slide block 40 is formed on one side wall of the camera module 30; the first elastic element 50 is arranged between the bottom of the camera module 30 and the bottom wall 12; the track plate 60 faces the side wall of the camera module 30 forming the sliding block 40, the track plate 60 is provided with a track groove 61 matched with the sliding block 40, the track groove 61 comprises a downward moving sliding groove 62, a clamping groove 63 and an upward moving sliding groove 64, the downward moving sliding groove 62 is gradually inclined rightward from top to bottom, the right side of the clamping groove 63 is communicated to the left side of the bottom of the downward moving sliding groove 62, the left side of the clamping groove 63 is provided with a left stopping portion 65, the upper side of the clamping groove 63 is provided with an upper stopping portion 66, the bottom of the upward moving sliding groove 64 is positioned on the left side of the left stopping portion 65, and the top of; the left end of the second elastic member 80 is connected to the right end of the rail plate 60, and the right end of the second elastic member 80 is connected to the mounting case 10; when the camera module 30 is accommodated, the camera module 30 is pressed to enable the sliding block 40 to slide downwards along the downwards moving chute 62, the first elastic element 50 is compressed downwards, the track plate 60 is gradually pushed leftwards by the sliding block 40, the second elastic element 80 is stretched, and when the sliding block 40 slides to a position corresponding to the clamping groove 63, the restoring force of the second elastic element 80 drives the track plate 60 to slide rightwards to enable the sliding block 40 to be clamped into the clamping groove 63; then, the camera module 30 is pressed to make the sliding block 40 go beyond the left stopping portion 65, and the restoring force of the second elastic member 80 drives the track plate 60 to slide rightward continuously to make the sliding block 40 get rid of the limitation of the left stopping portion 65; the upward restoring force of the first elastic member 50 may cause the slider 40, which is free from the restriction of the left stopper 65, to slide upward along the upward moving chute 64 to be restored to the top of the downward moving chute 62.

It should be noted that the mounting housing 10 may be a single member, or may be composed of two or more members, which is not limited herein; the catching groove 63 is not limited to be directly communicated with the bottom of the downward moving chute 62; in the preferred embodiment of the present invention, when the camera module 30 needs to be switched from the storage state to the use state, the camera module 30 can be returned to the use state through the cooperation of the first elastic member 50 and the second elastic member 80 by only one downward pressing, which, of course, does not exclude the technical solution that the user needs to perform other operations.

Through the above design, when the camera module 30 is stored in the push type camera assembly 100 of the present invention, the slider 40 slides downwards along the downward moving chute 62 by pressing the camera module 30, the first elastic element 50 is compressed downwards, the track plate 60 is gradually pushed leftwards by the slider 40, the second elastic element 80 is stretched, when the slider 40 slides to the position corresponding to the slot 63, the restoring force of the second elastic element 80 drives the track plate 60 to slide rightwards to clamp the slider 40 into the slot 63, so that the push type camera assembly 100 can be retracted into the mounting housing 10, i.e. in the storage state, thereby preventing the camera assembly from being hijacked and being taken secretly. When the camera module 30 needs to be used, the camera module 30 is pressed again to make the sliding block 40 go beyond the left stopping portion 65, and at this time, the restoring force of the second elastic member 80 drives the track plate 60 to continuously slide rightward to make the sliding block 40 get rid of the limitation of the left stopping portion 65; then, the upward restoring force of the first elastic member 50 makes the sliding block 40, which is out of the restriction of the left stopper 65, slide upward along the upward sliding groove 64 to return to the top of the downward sliding groove 62. As can be seen from the above, the push-type camera assembly 100 of the present invention has the advantages of simple structure, reliability and convenient operation while preventing hijacking and candid shooting.

Referring to fig. 4 to 8, in some embodiments, the sliding block 40 includes a left inclined surface 41 and a right inclined surface 42 which are parallel to each other, and a left vertical surface 43 and a right vertical surface 44 which are parallel to each other, the left inclined surface 41 and the right inclined surface 42 are respectively engaged with two inclined side walls of the downward moving chute 62, and the left vertical surface 43 and the right vertical surface 44 are respectively engaged with two vertical side walls of the upward moving chute 64; with this design, the slider 40 can slide more reliably in the rail groove 61. Of course, the design of the slider 40 and the track groove 61 is not limited to this specific scheme.

In some embodiments, the upward-moving chute 64 includes an inclined groove 67 and a vertical groove 68, the inclined direction of the inclined groove 67 is the same as the inclined direction of the downward-moving chute 62, the inclined groove 67 includes a right inclined wall 69, the vertical groove 68 forms two vertical side walls, the bottom of the vertical groove 68 is communicated with the top of the inclined groove 67, the upward restoring force of the first elastic member 50 can make the slider 40, which is free from the limitation of the left stopper 65, slide obliquely upward along the inclined groove 67 and then slide upward along the vertical groove 68, and when the slider 40 slides upward along the inclined groove 67, the right inclined surface 42 is engaged with the right inclined wall 69 of the inclined groove 67; by this design, the reliability of the sliding of the slider 40 is further enhanced. Of course, the design of the upward moving chute 64 is not limited to this particular scheme.

In some embodiments, the upward restoring force of the first elastic member 50 causes the slider 40 to push the track plate 60 to displace rightward during sliding along the upward moving chute 64 to compress the second elastic member 80; with this design, the slider 40 can be restored to the right to the top of the downshifting chute 62 with the elastic force release of the second elastic member 80, while the smoothness of the sliding of the slider 40 is further enhanced. In a specific embodiment, the upward restoring force of the first elastic member 50 causes the slider 40 to push the track plate 60 to the right during sliding along the inclined groove 67 to compress the second elastic member 80 to the right. Of course, during the upward sliding of the sliding block 40 on the upward sliding slot 64, it is not limited that the track board 60 is pushed to the right, for example, in some embodiments, the tops of the upward sliding slot 64 and the downward sliding slot 62 are overlapped, and when the sliding block 40 slides to the top of the upward sliding slot 64, the top of the downward sliding slot 62 is located.

In some embodiments, the top of the vertical slot 68 communicates with the top of the downshifting chute 62 through a horizontal chute 70. When the sliding block 40 moves up to the top of the vertical groove 68, the sliding block 40 is horizontally restored to the right to the top of the downward sliding groove 62 along the horizontal sliding groove 70 by releasing the elastic force of the second elastic member 80.

In some embodiments, an inner angle of the connection between the locking groove 63 and the downward moving chute 62 forms a vertical cut surface 71, and after the left inclined surface 41 of the slider 40 passes downward over the corresponding inclined side wall of the downward moving chute 62, the left vertical surface 43 of the slider 40 slides downward along the vertical cut surface 71 to exceed the vertical cut surface 71 so that the slider 40 is locked in the locking groove 63; by this design, the smoothness and reliability of the sliding of the slider 40 are further enhanced.

In some embodiments, the left stop 65 has a vertical stop face 72, the vertical stop face 72 cooperating with the left vertical face 43 of the slider 40; with this design, the stability of the camera module 30 in the housed state is facilitated.

In some embodiments, the slider 40 further comprises a horizontal top surface 45, the upper stop portion 66 has a horizontal stop surface 73, the horizontal stop surface 73 cooperates with the horizontal top surface 45 of the slider 40; the left stop 65 has a horizontal bottom surface 74, the horizontal bottom surface 74 cooperating with the horizontal top surface 45 of the slider 40. With this design, when the slider 40 slides to a position corresponding to the slot 63, the slider 40 slides leftwards along the horizontal stop surface 73 and is positioned in the slot 63, thereby facilitating the reliability of the sliding of the slider 40 and the stability of the camera module 30 in the storage state; when the slider 40 is moved downward beyond the left stopper 65, i.e. left-wards along the horizontal bottom surface 74 to beyond the horizontal bottom surface 74, the reliability of the sliding movement of the slider 40 is further enhanced.

Referring to fig. 2 and 6, in some embodiments, the rail plate 60 includes a body plate portion 75 forming the rail groove 61 and a connecting plate portion 76 vertically connected to a right end of the body plate portion 75, and the connecting plate portion 76 is connected to a left end of the second elastic member 80.

Referring to fig. 2 and 6, in some embodiments, the track plate 60 is convexly provided with a lateral guide post 77 extending in the left-right direction, the mounting housing 10 is convexly provided with two lateral guide plates 14 disposed at an interval, a lateral guide slot 15 is formed between the two lateral guide plates 14, and the lateral guide slot 15 cooperates with the lateral guide post 77 to limit the track plate 60 from moving in the left-right direction.

Referring to fig. 1, the present invention further discloses an electronic apparatus 1 including the pressing type camera assembly 100 according to the above embodiment.

In some embodiments, the electronic device 1 includes a body 91 and a screen body 92, which are pivotable with each other, and a pivot cover is provided between the body 91 and the screen body 92 as the mounting housing 10. Through the design, the camera module 30 and other structures do not need to be installed at the screen frame, and the screen occupation ratio of the screen body is favorably improved.

Referring to fig. 1 to 3, in some embodiments, the mounting housing 10 is a rotating shaft cover of a notebook computer, one side of the mounting housing 10 facing away from the main body 91 is open, a mounting plate 16 is formed at a transverse middle portion of the mounting housing 10, and the mounting plate 16 is connected to a right end of the second elastic element 80; specifically, the two lateral guides 14 are formed by inwardly protruding sidewalls of the mounting case 10 facing the body 91. Through this design, camera module 30, etc. need not install to screen frame department, is favorable to promoting the screen of screen body 92 to account for than.

The working process of the embodiment shown in the drawings is described as an example only; are only for the purpose of facilitating understanding of the present invention and should not be construed as limiting the present invention.

When the camera module 30 is in the extended state, the slide block 40 is positioned at the top of the downward moving chute 62; when the camera module 30 needs to be stored, the camera module 30 is pressed downwards, so that the sliding block 40 slides downwards along the downward moving chute 62, and the first elastic piece 50 is compressed downwards, meanwhile, the track plate 60 is gradually pushed leftwards by the sliding block 40, and the second elastic piece 80 is stretched by the leftward movement of the track plate 60; after the left inclined surface 41 of the slider 40 downwardly crosses the corresponding inclined side wall of the downward moving chute 62, the left vertical surface 43 of the slider 40 downwardly slides along the vertical tangent plane 71 to exceed the vertical tangent plane 71 so that the slider 40 is clamped into the clamping groove 63 along the horizontal stop surface 73 under the action of the restoring force of the second elastic member 80, and at this time, the left vertical surface 43 of the slider 40 abuts against the vertical stop surface 72; thus, the camera module 30 is completely housed. When the camera module 30 needs to be used, the camera module 30 is pressed again to make the sliding block 40 exceed the vertical stop surface 72, and at this time, the restoring force of the second elastic member 80 drives the track plate 60 to slide rightward continuously so that the sliding block 40 slides along the horizontal bottom surface 74 to get rid of the limitation of the left stop portion 65; then the upward restoring force of the first elastic member 50 can make the sliding block 40, which is free from the limitation of the left stopping portion 65, slide upwards along the inclined groove 67, in the process, the second elastic member 80 is compressed rightwards and then slides upwards to the vertical groove 68; when the sliding block 40 slides to the top of the vertical slot 68, the elastic force of the second elastic member 80 is released to push the track plate 60 leftward, so that the sliding block 40 slides along the horizontal sliding slot 70 to the top of the downward sliding slot 62, and thus the camera module 30 is in an extended state.

The above disclosure is only a preferred embodiment of the present invention, which is convenient for those skilled in the art to understand and implement, and certainly not to limit the scope of the present invention, therefore, the present invention is not limited by the claims and their equivalents.

Claims

1. A push type camera assembly is characterized by comprising

The mounting shell comprises a top wall and a bottom wall which are oppositely arranged, and the top wall is provided with an opening;

the camera module is arranged in the mounting shell and can extend out or retract from the opening, and a sliding block is formed on one side wall of the camera module;

the first elastic piece is arranged between the bottom of the camera module and the bottom wall;

the track plate is arranged facing the side wall of the sliding block formed by the camera module, a track groove matched with the sliding block is formed in the track plate, the track groove comprises a downward moving sliding groove, a clamping groove and an upward moving sliding groove, the downward moving sliding groove gradually inclines towards the right from top to bottom, the right side of the clamping groove is communicated to the left side of the bottom of the downward moving sliding groove, a left stopping portion is formed on the left side of the clamping groove, an upper stopping portion is formed on the upper side of the clamping groove, the bottom of the upward moving sliding groove is located on the left side of the left stopping portion, and the top of the upward moving sliding groove is communicated with the top of the downward moving sliding groove; and

a second elastic member, a left end of which is connected to a right end of the rail plate, and a right end of which is connected to the mounting case;

when the camera module is stored, the camera module is pressed to enable the sliding block to slide downwards along the downward moving chute, the first elastic piece is compressed downwards, the track plate is gradually pushed leftwards by the sliding block, the second elastic piece is stretched, and when the sliding block slides to a position corresponding to the clamping groove, the restoring force of the second elastic piece drives the track plate to slide rightwards to enable the sliding block to be clamped into the clamping groove; pressing the camera module to enable the sliding block to exceed the left stopping portion downwards, wherein the restoring force of the second elastic piece drives the track plate to continuously slide rightwards so that the sliding block is free from the limitation of the left stopping portion; the upward restoring force of the first elastic piece can enable the sliding block which is free from the limitation of the left stopping portion to slide upwards along the upward moving sliding groove so as to reset to the top of the downward moving sliding groove.

2. The push type camera assembly of claim 1, wherein the slider comprises parallel left and right inclined surfaces that respectively engage with two inclined sidewalls of the down-moving chute, and parallel left and right vertical surfaces that respectively engage with two vertical sidewalls of the up-moving chute.

3. The push type camera assembly of claim 2, wherein the upward-moving sliding groove comprises an inclined groove and a vertical groove, the inclined direction of the inclined groove is consistent with the inclined direction of the downward-moving sliding groove, the inclined groove comprises a right inclined wall, the vertical groove forms two vertical side walls, the bottom of the vertical groove is communicated with the top of the inclined groove, the upward restoring force of the first elastic member enables the slider, which is free from the limitation of the left stopper, to slide obliquely upward along the inclined groove and then slide upward along the vertical groove, and when the slider slides upward along the inclined groove, the right inclined surface is matched with the right inclined wall of the inclined groove.

4. The push type camera assembly of claim 3, wherein the upward restoring force of the first elastic member causes the slider to push the rail plate to displace rightward during sliding along the upward sliding slot to compress the second elastic member.

5. The push type camera assembly of claim 4, wherein a top of the vertical slot communicates with a top of the downshifting chute through a horizontal chute.

6. The push type camera assembly as claimed in claim 2, wherein an inner angle of a connection between the locking groove and the downward moving chute forms a vertical cut surface, and when the left inclined surface of the slider moves downward beyond the corresponding inclined sidewall of the downward moving chute, the left vertical surface of the slider slides downward along the vertical cut surface to be beyond the vertical cut surface so that the slider is locked in the locking groove.

7. The push type camera assembly of claim 2, wherein the left stop has a vertical stop surface that mates with a left vertical surface of the slider.

8. The push type camera assembly of claim 2, wherein the slider further comprises a horizontal top surface, the upper stop has a horizontal stop surface, and the horizontal stop surface mates with the horizontal top surface of the slider; the left stopping portion is provided with a horizontal bottom surface, and the horizontal bottom surface is matched with the horizontal top surface of the sliding block.

9. An electronic device comprising a push-type camera assembly, the push-type camera assembly as recited in any one of claims 1 to 8.

10. The electronic device according to claim 9, wherein the electronic device comprises a body and a screen body which are pivotable with each other, and a pivot cover as the mounting case is provided between the body and the screen body.