CN113645333A - Sliding cover structure for mobile communication equipment - Google Patents

Abstract

The invention discloses a sliding closure structure for a mobile communication device, which relates to the field of communication devices and comprises a supporting mechanism and a communication device, and further comprises a first sliding mechanism, a second sliding mechanism, an adjusting mechanism and a balancing weight, wherein the supporting mechanism is arranged on one side of the first sliding mechanism in a sliding manner, the first sliding mechanism is arranged on one side of the second sliding mechanism in a sliding manner, the adjusting mechanism is movably arranged on one side of the bottom of the second sliding mechanism, and the supporting mechanism slides along one side of the first sliding mechanism. Above-mentioned scheme is offered along the surface of neck bush through setting up the second wedge spout and is the circumference form, and at the rotation in-process, first wedge spout and second wedge spout are put at the central point and are crossed and drive the subtend piece and be the state of returning to the positive, rotate the driven shaft, and subtend piece is more than or equal to 180 degrees rotations, and then drives supporting mechanism, communication equipment, first slide mechanism and second slide mechanism and carries out more than or equal to degree's rotation, accomplishes the angle modulation to communication equipment.

Description

Sliding cover structure for mobile communication equipment

Technical Field

The invention relates to the technical field of communication equipment, in particular to a sliding cover structure for mobile communication equipment.

Background

The communication equipment is divided into wired communication equipment and wireless communication equipment, the wired communication means that the communication equipment needs to be connected through cables during transmission, namely, a mode of transmitting information by using transmission media such as overhead cables, coaxial cables, optical fibers and audio cables is adopted, the wireless communication means that the communication does not need physical connecting wires, namely, a communication mode of exchanging information by using the characteristic that electromagnetic wave signals can be transmitted in free space, the wireless communication equipment has the greatest advantage of environment, does not need to be limited by wires, has certain mobility, can communicate through wireless connection in a mobile state, and is low in construction difficulty and cost.

Common wireless devices include satellites, radio stations, wireless televisions (on buses or subways), wireless local area networks, mobile phones (mobile phones) and the like, the demands of people are higher and higher along with the development of times, but many carrier devices for mobile communication can only perform push-pull actions and do not need people, and due to the fact that the carrier devices are easy to deform and damage due to materials, the devices are easy to damage after multiple push-pull actions are performed.

In addition, some current equipment are at angle regulation's in-process, through the position of establishing of inserting of manual regulation locating pin to realize the angle change, long-time fixed or angle turn to and cause the card of junction easily to pause, easily cause the fracture, lead to the damage of equipment.

Accordingly, the present application provides a slider structure for a mobile communication device to meet the needs.

Disclosure of Invention

The present application is directed to a sliding cover structure for a mobile communication device, so as to solve the problems of the background mentioned above.

In order to achieve the above purpose, the present application provides the following technical solutions: a sliding closure structure for mobile communication equipment comprises a supporting mechanism and communication equipment, and further comprises a first sliding mechanism, a second sliding mechanism, an adjusting mechanism and a balancing weight;

the supporting mechanism is arranged on one side of the first sliding mechanism in a sliding mode, the first sliding mechanism is arranged on one side of the second sliding mechanism in a sliding mode, the adjusting mechanism is movably arranged on one side of the bottom of the second sliding mechanism, the supporting mechanism slides along one side of the first sliding mechanism and transversely slides the communication equipment, and the sliding stroke of the supporting mechanism is increased;

the first sliding mechanism slides transversely along one side of the second sliding mechanism, the first sliding mechanism and the supporting mechanism are adjusted in transverse stroke, the adjusting mechanism is used for adjusting the angles and the mounting directions of the supporting mechanism, the communication equipment, the first sliding mechanism and the second sliding mechanism, and the counterweight block is used for carrying out overall structural balance on the second sliding mechanism;

Adjustment mechanism includes horniness board, driven shaft and outer bush, the both sides of outer bush respectively fixed mounting in one side of driven shaft, subtend piece is installed to one side of outer bush, one side of outer bush is fixed with the mounting disc, the top both sides of subtend piece are installed in second slide mechanism's bottom, first wedge spout has been seted up on the surface of outer bush, the inside slidable mounting of first wedge spout has the slide-spindle piece, the internally mounted of outer bush one side has the thread bush, the cross section of outer bush is sunken annular structure, the internally mounted of mounting disc has the neck bush.

Preferably, the horny plate is one side that the symmetry form is fixed in second slide mechanism, the driven shaft runs through the horny plate and rotates the inside of installing in the horny plate, the driving shaft is installed in one side rotation of horny plate, one side of driving shaft is hand wheel column structure, driving shaft one side runs through the horny plate and rotates the inside of installing in the horny plate.

Preferably, the inside of horny plate is rotated through the rolling disc and is installed first rotation tooth, the outside of rolling disc and the surface of horny plate inner wall are bearing assembly structure, one side of driving shaft is fixed to be cup jointed in the inside of first rotation tooth, first rotation tooth and second are rotated the tooth and are the parallel form meshing, the diameter of first rotation tooth is greater than the diameter that the second rotated the tooth, the driven shaft runs through outer bush and horny plate fixed mounting and puts in the central point of rolling disc.

Preferably, a threaded disc is fixedly mounted on one side of the inner bushing, the inner bushing is rotatably mounted inside the threaded bushing through the threaded disc and connected with the threaded disc, the diameter of the outer bushing is matched with that of the inner bushing, a second wedge-shaped sliding groove is formed in the surface of the inner bushing, and the sliding shaft block penetrates through the first wedge-shaped sliding groove and is slidably mounted inside the second wedge-shaped sliding groove.

Preferably, the supporting mechanism comprises a first mounting plate, a reinforcing plate and a second mounting plate, the communication equipment is fixedly mounted at the top of the supporting mechanism, the reinforcing plate is fixed between the first mounting plate and the second mounting plate, one side of the first mounting plate and one side of the second mounting plate are provided with mounting holes, and one side of the reinforcing plate is of a T-shaped structure.

Preferably, first slide mechanism includes linkage plate, linear slide rail and linear slide block, linear slide rail is symmetry form fixed mounting in the top of linkage plate, linear slide block slidable mounting is in linear slide rail's surface, linear slide block's quantity is four groups at least, and is two bisymmetry forms and slides in linear slide rail's surface, install the backup pad between the both sides of linkage plate, the fixed surface of backup pad has the fixed plate.

Preferably, the second slide mechanism includes installation base, shielding plate and rotation piece, the locking slide rail is installed to the top symmetry of installation base, it runs through to rotate the piece one side of shielding plate rotate install in one side of locking slide rail through the bearing, the surface symmetry of locking slide rail installs the locking spout, one side fixed mounting of installation base has the bearing frame, one side of rotating the piece is rotated and is installed the axis of rotation, one side of axis of rotation is run through the bearing frame and is rotated and install in the inside of bearing frame.

Preferably, the surface slidable mounting of axis of rotation has the slip cap, the recess with axis of rotation surface looks adaptation is seted up to the inside of slip cap, and the surface slip of meshing axis of rotation, the top fixed mounting of slip cap has the connecting plate.

In conclusion, the technical effects and advantages of the invention are as follows:

1. according to the scheme, the cross section of the outer bushing is of a concave ring-shaped structure, the inner bushing rotates along the inside of the outer bushing, the bottom of the sliding shaft block is of a sliding pin shaft-shaped structure, the top of the sliding shaft block is fixedly connected with the outer bushing, the bottom of the sliding shaft block slides along the insides of the first wedge-shaped sliding chute and the second wedge-shaped sliding chute, the first wedge-shaped sliding chute is formed along one side of the surface of the outer bushing, the second wedge-shaped sliding chute is formed along the surface of the inner bushing in a circumferential shape, in the rotating process, the first wedge-shaped sliding chute and the second wedge-shaped sliding chute are intersected at the central position to drive the opposite direction block to be in a return state, the driven shaft is rotated, the opposite direction block rotates by more than or equal to 180 degrees, and then the supporting mechanism, the communication equipment, the first sliding mechanism and the second sliding mechanism are driven to rotate by more than or equal to degrees, and angle adjustment of the communication equipment is completed;

2. According to the scheme, the rotating shaft is arranged to rotate, so that the surface of the sliding sleeve, which is internally meshed with the rotating shaft, is driven to slide, the top of the connecting plate and the bottom of the fixing plate are fixed to each other (the fixing mode is a threaded assembly or a bolt-shaped assembly structure), the top of the fixing plate and two sides of the connecting plate are connected and mounted, the first sliding mechanism is driven to move along the sliding vector direction of the sliding sleeve, and the supporting mechanism and the communication equipment are driven to transversely adjust;

3. above-mentioned scheme, further, to one side promotion supporting mechanism, the installation is connected with the top of sharp slider respectively in the bottom of first mounting panel and second mounting panel, and one side of sharp slider slides in linear slide rail's surface, and then drives first mounting panel and second mounting panel and carry out lateral sliding, has increased the biggest stroke of communication equipment slip in-process installation, has improved overall structure's stability and suitability.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic side view of an adjusting mechanism and its overall structure;

FIG. 3 is a schematic view of the internal structure of the angle plate of the present invention;

FIG. 4 is a schematic view of an angle adjustment structure of the present invention;

FIG. 5 is a schematic view of an angle adjustment separation configuration of the present invention;

FIG. 6 is a schematic structural diagram of a first sliding mechanism according to the present invention;

FIG. 7 is a schematic structural view of the second sliding mechanism of the present invention.

In the figure: 1. a support mechanism; 2. a communication device; 3. a first sliding mechanism; 4. a second sliding mechanism; 5. an adjustment mechanism; 6. a balancing weight; 11. a first mounting plate; 12. a reinforcing plate; 13. a second mounting plate; 31. a connector tile; 32. a linear slide rail; 33. a linear slider; 34. a fixing plate; 35. a support plate; 41. installing a base; 42. a shielding plate; 43. a rotating member; 44. locking the slide rail; 45. a locking chute; 46. a bearing seat; 47. a rotating shaft; 48. a sliding sleeve; 49. a connecting plate; 51. a horn-shaped plate; 52. a driven shaft; 53. an outer liner; 54. a drive shaft; 55. a first rotating tooth; 56. rotating the disc; 57. a second rotating tooth; 58. mounting a disc; 59. an opposite block; 531. a first wedge-shaped chute; 532. a sliding shaft block; 533. a threaded sleeve; 534. an inner liner; 535. a threaded disc; 536. a second wedge runner.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example (b): referring to fig. 1-7, a sliding cover structure for a mobile communication device includes a supporting mechanism 1 and a communication device 2, and further includes a first sliding mechanism 3, a second sliding mechanism 4, an adjusting mechanism 5 and a weight block 6;

the supporting mechanism 1 is slidably mounted on one side of the first sliding mechanism 3, the first sliding mechanism 3 is slidably mounted on one side of the second sliding mechanism 4, the adjusting mechanism 5 is movably mounted on one side of the bottom of the second sliding mechanism 4, the supporting mechanism 1 slides along one side of the first sliding mechanism 3 and transversely slides the communication equipment 2, and the sliding stroke of the supporting mechanism 1 is increased;

the first sliding mechanism 3 transversely slides along one side of the second sliding mechanism 4, the first sliding mechanism 3 and the supporting mechanism 1 are adjusted in transverse stroke, the adjusting mechanism 5 is used for adjusting the angles and the installation directions of the supporting mechanism 1, the communication equipment 2, the first sliding mechanism 3 and the second sliding mechanism 4, and the counterweight 6 is used for integrally balancing the second sliding mechanism 4 in structure.

In this embodiment, the adjusting mechanism 5 includes a corner plate 51, a driven shaft 52 and an outer bushing 53, the corner plate 51 is symmetrically fixed to one side of the second sliding mechanism 4 to support the whole, the driven shaft 52 is rotatably mounted inside the corner plate 51 through the corner plate 51, a driving shaft 54 is rotatably mounted on one side of the corner plate 51, a hand wheel-shaped structure is formed on one side of the driving shaft 54, and the driving shaft 54 is rotatably mounted inside the corner plate 51 through the corner plate 51.

In this embodiment, (see fig. 2) the top of the horn plates 51 on both sides are mounted by a swing shaft, forming a lever structure with the bottom of the second slide mechanism 4.

In this embodiment, the horn-shaped plate 51 is rotatably installed with a first rotating tooth 55 inside by a rotating disc 56, one side of the driving shaft 54 is fixedly sleeved inside the first rotating tooth 55, the first rotating tooth 55 and the second rotating tooth 57 are engaged in parallel, the engaging effect is increased, wherein the second rotating gear 57 rotates through the driving shaft 54, and further drives (57) to rotate, since the outer side of the rotary disk 56 and the surface of the inner wall of the horn-shaped plate 51 are bearing fitting structures, the first rotary teeth 55 are opened in the inside of the rotary disk 56, and the second rotating tooth 57 is engaged in parallel with the inside of the first rotating tooth 55 in the case of the rotation of the origin, and then the rotating disc 56 is driven to rotate along the bearing assembly structure at one side of the angle-shaped plate 51, the diameter of the first rotating tooth 55 is larger than that of the second rotating tooth 57, and the driven shaft 52 penetrates through the outer bushing 53 and the angle-shaped plate 51 and is fixedly installed at the central position of the rotating disc 56.

In this embodiment, the diameter of the first rotating tooth 55 is larger than that of the second rotating tooth 57, and the rotating speed of the first rotating tooth 55 is increased, so that the torque is reduced, and the stability of the rotation of the first rotating tooth 55 is ensured.

In this embodiment, the driving shaft 54 is rotated, and the driving shaft 54 drives the second rotating tooth 57 to rotate by engaging with one side of the first rotating tooth 55, wherein the first rotating tooth 55 is an inner ring tooth-shaped structure, and further drives the first rotating tooth 55 to rotate along the surface of the rotating disc 56, and the rotating disc 56 drives the driven shaft 52 to rotate along the central position of the first rotating tooth 55 during the rotation process.

In this embodiment, an opposing block 59 is installed on one side of the outer bushing 53, a mounting plate 58 is fixed on one side of the outer bushing 53, two sides of the top of the opposing block 59 are installed at the bottom of the second sliding mechanism 4, a first wedge-shaped sliding groove 531 is formed in the surface of the outer bushing 53, a sliding shaft block 532 is slidably installed inside the first wedge-shaped sliding groove 531, a threaded sleeve 533 is installed inside one side of the outer bushing 53, the cross section of the outer bushing 53 is a recessed annular structure, and an inner bushing 534 is installed inside the mounting plate 58.

In this embodiment, a threaded disc 535 is fixedly installed on one side of the inner bushing 534, the inner bushing 534 is rotatably installed inside the threaded bushing 533 through the threaded disc 535, and the installation disc 58 rotates to drive the inner bushing 534 to rotate, and further drive the threaded disc 535 to rotate 360 degrees along the inside of the threaded bushing 533.

In this embodiment, the diameter of the outer bushing 53 is matched with the diameter of the inner bushing 534 to ensure the adaptability during the installation process, the surface of the inner bushing 534 is provided with a second wedge-shaped sliding groove 536, and the sliding shaft block 532 is slidably installed inside the second wedge-shaped sliding groove 536 through the first wedge-shaped sliding groove 531.

In this embodiment, the bottom of the sliding shaft block 532 is a sliding pin shaft-shaped structure, the top of the sliding shaft block 532 is fixedly connected with the outer bushing 53, and the bottom slides along the insides of the first wedge-shaped chute 531 and the second wedge-shaped chute 536, wherein the first wedge-shaped chute 531 is arranged along one side of the surface of the outer bushing 53, the second wedge-shaped chute 536 is arranged along the surface of the inner bushing 534 in a circumferential manner, during the rotation process, the first wedge-shaped chute 531 and the second wedge-shaped chute 536 intersect at the central position to drive the counter block 59 to be in a return-positive state, the driven shaft 52 is rotated, the counter block 59 rotates by more than or equal to 180 degrees, and then the support mechanism 1, the communication device 2, the first sliding mechanism 3 and the second sliding mechanism 4 are driven to rotate by more than or equal to 180 degrees.

In this embodiment, the support mechanism 1 includes a first mounting plate 11, a reinforcing plate 12, and a second mounting plate 13, the communication device 2 is fixedly mounted on the top of the support mechanism 1, and the reinforcing plate 12 is fixed between the first mounting plate 11 and the second mounting plate 13.

In this embodiment, the first mounting plate 11 and the second mounting plate 13 have mounting holes formed on one side thereof for adaptive mounting of communication devices of different specifications, and the reinforcing plate 12 has a T-shaped structure on one side thereof for increasing load bearing capability of the communication devices.

In this embodiment, the first sliding mechanism 3 includes a connecting plate 31, a linear slide rail 32 and a linear slide block 33, the linear slide rail 32 is symmetrically and fixedly mounted on the top of the connecting plate 31, the linear slide block 33 is slidably mounted on the surface of the linear slide rail 32, and the top of the linear slide block 33 is fixedly mounted on the bottom of the first mounting plate 11 and the second mounting plate 13.

In this embodiment, the number of the linear sliders 33 is at least four, and the linear sliders 33 slide on the surfaces of the linear slide rails 32 in a pairwise symmetric manner, so that the resistance during sliding is reduced, and sliding resistance caused by abrasion of the linear slide rails 32 is prevented, a support plate 35 is installed between two sides of the connecting plate 31, the support plate 35 supports the two sides of the connecting plate 31, and a fixing plate 34 is fixed on the surface of the support plate 35 and used for connection between the first sliding mechanism 3 and the support mechanism 1.

In this embodiment, the second sliding mechanism 4 includes a mounting base 41, a shielding plate 42 and a rotating member 43, a locking slide rail 44 is symmetrically mounted on the top of the mounting base 41, a locking slide groove 45 is symmetrically mounted on the surface of the locking slide rail 44, the locking slide groove 45 slides on the surface of the locking slide rail 44, and the top of the locking slide groove 45 is connected to the bottom of the connecting plate 31.

In this embodiment, a bearing seat 46 is fixedly installed at one side of the installation base 41, a rotation shaft 47 is rotatably installed at one side of the rotation member 43, and one side of the rotation shaft 47 is rotatably installed inside the bearing seat 46 through the bearing seat 46.

In this embodiment, a sliding sleeve 48 is slidably mounted on the surface of the rotating shaft 47, a groove adapted to the surface of the rotating shaft 47 is formed in the sliding sleeve 48, and the sliding sleeve 48 is engaged with the surface of the rotating shaft 47 to slide, so as to drive the sliding sleeve 48 to slide along the vector direction of the rotating shaft 47, a connecting plate 49 is fixedly mounted on the top of the sliding sleeve 48, and the connecting plate 49 supports and limits the bottom of the fixing plate 34.

In this embodiment, the weight 6 is balanced as a whole, and the whole is prevented from being inclined due to gravity.

In this embodiment, the number of symmetrical additions of the angled panels 51 may be field adjusted (single set 2 of angled panels 51 or double set 4 of angled panels 51) depending on the application.

In this embodiment, the linear sliding block 33, the linear sliding rail 32, the locking sliding chute 45 and the locking sliding rail 44 are in a ball and limiting hole structure, and limit the distance in the sliding process.

The working principle of the invention is as follows:

the first step is as follows: when the communication device 2 needs to be transversely adjusted, the rotating piece 43 is rotated to one side, the rotating piece 43 rotates along the rotating direction to drive the rotating shaft 47 to rotate, so that the surface of the sliding sleeve 48, which is internally meshed with the rotating shaft 47, is driven to slide, the top of the connecting plate 49 and the bottom of the fixing plate 34 are mutually fixed (the fixing mode is a threaded assembly or bolt-shaped assembly structure), the top of the fixing plate 34 and the two sides of the connecting plate 31 are connected and installed, so that the first sliding mechanism 3 is driven to move along the sliding vector direction of the sliding sleeve 48, and the supporting mechanism 1 and the communication device 2 are driven to be transversely adjusted;

The second step is that: when the position of the communication equipment 2 is smaller than the installation position, the supporting mechanism 1 is pushed to one side, the bottoms of the first installation plate 11 and the second installation plate 13 are respectively connected and installed with the top of the linear sliding block 33, (the installation mode is equal to that of the connecting plate 49 and the fixing plate 34), one side of the linear sliding block 33 slides on the surface of the linear sliding rail 32, and then the first installation plate 11 and the second installation plate 13 are driven to transversely slide, so that the maximum installation stroke of the communication equipment 2 in the sliding process is increased, and the stability and the adaptability of the whole structure are improved;

the third step: when the communication equipment 2 needs to be adjusted at different angles, the driving shaft 54 is rotated to one side, the driving shaft 54 rotates to drive the second rotating teeth 57 to rotate in the same direction, then the second rotating teeth 57 are meshed with the first rotating teeth 55 in a parallel shape to rotate, the outer side of the rotating disc 56 and the surface of the inner wall of the angle plate 51 are in a bearing assembly structure, then the driven shaft 52 rotates along the central position of the rotating disc 56, the driven shaft 52 penetrates through the inner bushing 534 to rotate and is arranged on the surface of one side of the angle plate 51, and the rotation mode of the angle plate 51 and the driven shaft 52 is a bearing or rotating bushing assembly structure so as to drive the inner bushing 534 to rotate;

The fourth step: in the rotating process of the inner bushing 534, the threaded disc 535 rotates 360 degrees along the inside of the threaded bushing 533, the cross section of the outer bushing 53 is of a concave ring-shaped structure, the inner bushing 534 rotates along the inside of the outer bushing 53, the bottom of the sliding shaft block 532 is of a sliding pin shaft-shaped structure, the top of the sliding shaft block 532 is fixedly connected with the outer bushing 53, and the bottom of the sliding shaft block slides along the insides of the first wedge-shaped sliding groove 531 and the second wedge-shaped sliding groove 536;

the fifth step: first wedge spout 531 is seted up along one side on outer bush 53 surface, second wedge spout 536 is offered along the surface of inner liner 534 for the circumference form, at the rotation in-process, first wedge spout 531 and second wedge spout 536 intersect at central point and drive subtend piece 59 and be the state of returning, rotate driven shaft 52, subtend piece 59 carries out the rotation that is more than or equal to 180 degrees, and then drives supporting mechanism 1, communication equipment 2, first slide mechanism 3 and second slide mechanism 4 carry out the rotation that is more than or equal to 180 degrees, accomplish the angle modulation to communication equipment 2.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (8)

1. A sliding cover structure for a mobile communication device, comprising a support mechanism (1) and a communication device (2), characterized in that: the device also comprises a first sliding mechanism (3), a second sliding mechanism (4), an adjusting mechanism (5) and a balancing weight (6);

the supporting mechanism (1) is slidably mounted on one side of a first sliding mechanism (3), the first sliding mechanism (3) is slidably mounted on one side of a second sliding mechanism (4), the adjusting mechanism (5) is movably mounted on one side of the bottom of the second sliding mechanism (4), the supporting mechanism (1) slides along one side of the first sliding mechanism (3) and transversely slides the communication equipment (2), and the sliding stroke of the supporting mechanism (1) is increased;

the first sliding mechanism (3) slides transversely along one side of the second sliding mechanism (4), the first sliding mechanism (3) and the supporting mechanism (1) are adjusted in transverse stroke, the adjusting mechanism (5) is used for adjusting the angles and the installation directions of the supporting mechanism (1), the communication equipment (2), the first sliding mechanism (3) and the second sliding mechanism (4), and the counterweight block (6) is used for carrying out integral structural balance on the second sliding mechanism (4);

Adjustment mechanism (5) are including horny board (51), driven shaft (52) and outer bush (53), the both sides of outer bush (53) fixed mounting respectively in one side of driven shaft (52), subtend piece (59) is installed to one side of outer bush (53), one side of outer bush (53) is fixed with mounting disc (58), the bottom in second slide mechanism (4) is installed to the top both sides of subtend piece (59), first wedge spout (531) have been seted up on the surface of outer bush (53), the inside slidable mounting of first wedge spout (531) has slide shaft piece (532), the internally mounted of outer bush (53) one side has thread bush (533), the cross section of outer bush (53) is sunken annular column structure, the internally mounted of mounting disc (58) has bush (534).

2. A slide cover structure for a mobile communication device according to claim 1, wherein: horny board (51) are the one side that the symmetry form was fixed in second slide mechanism (4), driven shaft (52) run through horny board (51) and rotate and install in the inside of horny board (51), one side rotation of horny board (51) installs driving shaft (54), one side of driving shaft (54) is hand wheel column structure, driving shaft (54) one side runs through horny board (51) and rotates and install in the inside of horny board (51).

3. A slide cover structure for a mobile communication device according to claim 2, wherein: the inside of horny board (51) is rotated through rolling disc (56) and is installed first rotation tooth (55), the outside of rolling disc (56) and the surface of horny board (51) inner wall are bearing assembly structure, one side of driving shaft (54) is fixed to be cup jointed in the inside of first rotation tooth (55), first rotation tooth (55) and second rotation tooth (57) are the meshing of parallel form, the diameter of first rotation tooth (55) is greater than the diameter of second rotation tooth (57), driven shaft (52) run through outer bush (53) and horny board (51) fixed mounting in the central point of rolling disc (56).

4. A slide cover structure for a mobile communication device according to claim 1, wherein: one side of the inner bushing (534) is fixedly provided with a threaded disc (535), the inner bushing (534) is rotatably arranged inside the threaded bushing (533) through the threaded disc (535) to be connected, the diameter of the outer bushing (53) is matched with that of the inner bushing (534), the surface of the inner bushing (534) is provided with a second wedge-shaped sliding groove (536), and the sliding shaft block (532) penetrates through the first wedge-shaped sliding groove (531) to be slidably arranged inside the second wedge-shaped sliding groove (536).

5. A slide cover structure for a mobile communication device according to claim 1, wherein: supporting mechanism (1) includes first mounting panel (11), reinforcing plate (12) and second mounting panel (13), communications facilities (2) fixed mounting is in the top of supporting mechanism (1), reinforcing plate (12) are fixed in between first mounting panel (11) and second mounting panel (13), the mounting hole has been seted up to one side of first mounting panel (11) and second mounting panel (13), one side of reinforcing plate (12) is "T" style of calligraphy structure.

6. A slide cover structure for a mobile communication device according to claim 1, wherein: first slide mechanism (3) are including linking up fishplate bar (31), linear slide rail (32) and straight line slider (33), linear slide rail (32) are symmetry form fixed mounting in the top of linking up fishplate bar (31), straight line slider (33) slidable mounting is in the surface of linear slide rail (32), the quantity of straight line slider (33) is four groups at least, and is two bisymmetry forms and slides in the surface of linear slide rail (32), install backup pad (35) between the both sides of linking up fishplate bar (31), the fixed surface of backup pad (35) has fixed plate (34).

7. A slide cover structure for a mobile communication device according to claim 1, wherein: second slide mechanism (4) are including installation base (41), shielding plate (42) and rotation piece (43), locking slide rail (44) are installed to the top symmetry of installation base (41), it runs through to rotate piece (43) one side of shielding plate (42), rotate through the bearing install in one side of locking slide rail, locking spout (45) are installed to the surface symmetry of locking slide rail (44), one side fixed mounting of installation base (41) has bearing frame (46), one side of rotating piece (43) is rotated and is installed axis of rotation (47), one side of axis of rotation (47) is run through bearing frame (46) and is rotated and install in the inside of bearing frame (46).

8. A slide cover structure for a mobile communication device according to claim 7, wherein: the surface slidable mounting of axis of rotation (47) has sliding sleeve (48), the inside of sliding sleeve (48) is seted up with axis of rotation (47) surface looks adaptation's recess, and the surface slip of meshing axis of rotation (47), the top fixed mounting of sliding sleeve (48) has connecting plate (49).

Images