CN112060888B

CN112060888B - Vehicle-mounted intelligent device

Info

Publication number: CN112060888B
Application number: CN202010960260.9A
Authority: CN
Inventors: 陈玉琴
Original assignee: Eagle Vision Corp ltd
Current assignee: Eagle Vision Corp ltd
Priority date: 2020-09-14
Filing date: 2020-09-14
Publication date: 2021-04-06
Anticipated expiration: 2040-09-14
Also published as: CN112060888A

Abstract

The invention discloses vehicle-mounted intelligent equipment which comprises a vehicle roof, wherein a skylight hole which penetrates through the vehicle roof from top to bottom is arranged in the vehicle roof, a containing groove with a forward opening is arranged on the rear side wall of the skylight hole, rotating rods are symmetrically and rotatably arranged on the upper wall and the lower wall of the containing groove from side to side, a rotating support rod is fixedly arranged on each rotating rod, the rotating support rods on the left side and the right side are connected through a spring rope, and the front-back separation movement of a skylight and a partition plate is controlled through the separation and engagement of a fixed bevel gear and a movable connection bevel gear.

Description

Vehicle-mounted intelligent device

Technical Field

The invention relates to the technical field of vehicle-mounted intelligent products, in particular to a vehicle-mounted intelligent device.

Background

Automobile and smart machine are developing at the rapid pace simultaneously, therefore the combination of both has also become the direction of development from now on, and present skylight system is comparatively crude, and the switching is convenient inadequately, can not control the size that the skylight was opened at will, and the skylight often can someone stretch out the skylight when opening, does not have the strong point, the easy accident that appears, when the accident appears, the personnel that stretch out the skylight are nervous easily, and the process of contracting can be in skylight department because of the action fault card.

Disclosure of Invention

Aiming at the technical defects, the invention provides a vehicle-mounted intelligent device which can overcome the defects.

The invention relates to vehicle-mounted intelligent equipment which comprises a vehicle roof, wherein a skylight hole which penetrates through the vehicle roof up and down is arranged in the vehicle roof, a containing groove with a forward opening is arranged on the rear side wall of the skylight hole, rotating rods are symmetrically and rotatably arranged on the upper wall and the lower wall of the containing groove in a left-right mode, a rotating support rod is fixedly arranged on each rotating rod, the rotating support rods on the left side and the right side are connected through a spring rope, a skylight containing cavity with a leftward opening is communicated with the right side wall of the skylight hole, a clamp is slidably arranged on the top wall of the skylight containing cavity, a skylight is slidably arranged on the left side of the clamp, a partition plate is slidably arranged on the bottom wall of the skylight containing cavity, a pushing gear groove with an upward opening is arranged on the bottom wall of the skylight containing cavity, a worm transmission shaft extending forwards and backwards is rotatably arranged on, the left side wall of the skylight hole is communicated with an inclined plane groove with a right opening, the front and rear walls of the inclined plane groove are symmetrically communicated with sliding grooves with openings facing the center of the inclined plane groove, movable supporting blocks are slidably mounted in the sliding grooves, movable shafts extending forwards and backwards are rotatably connected between the movable supporting blocks at the front and rear sides in the inclined plane groove, rockers are symmetrically rotatably mounted in the inclined plane groove in a front and rear mode and extend into the skylight hole, a clamping plate is fixedly connected with the rocker, a propelling groove with a forward opening is formed in the lower side of the accommodating groove in the rear side wall of the skylight hole, a segmented turnover plate is slidably mounted in the propelling groove and is connected with the rear side wall of the propelling groove through a spring, a rotating groove with a forward opening is formed in the right side wall of the skylight hole, and linking shafts extending leftwards and rightwards are rotatably mounted on the left and, the connecting shaft is fixedly connected with a lifting gear in the rotary groove, a lifting top block is slidably mounted on the rear side wall of the skylight hole at the joint of the rotary groove, and the lifting top block is in meshed connection with the lifting gear.

Preferably, fixed mounting has a biax motor on the chamber rear side wall is accomodate in the skylight, power connection has a screw motor shaft on the biax motor, the screw motor shaft in the skylight is accomodate intracavity front and back symmetry threaded connection has the screw thread piece, screw thread piece sliding fit the chamber right side wall is accomodate in the skylight, screw thread piece left side is rotated and is connected with the rocker, the rocker with fixture rotates the connection, link up the axle and extend right with biax motor power connects.

Preferably, accomodate the groove diapire in the left side the bull stick right side is rotated and is installed the transition axle, the transition axle with through connecting the gear train meshing connection between the bull stick, the right side the bull stick with the transition axle passes through the drive belt transmission and connects, the right side the bull stick downwardly extending runs through and the swivelling joint the swivelling chute with accomodate the wall body between the groove, the bull stick in the swivelling chute internal fixation is connected with links up fixed bevel gear, link up the axle in the swivelling chute internal spline is connected with the movable spline sleeve, fixed mounting has movable bevel gear on the movable spline sleeve, movable bevel gear with link up fixed bevel gear meshing connection, the last rotation of movable spline sleeve is connected with the guide block, guide block sliding fit the lateral wall behind the swivelling chute.

Preferably, the roof in the spout rear side be equipped with the motor chamber of spout intercommunication, rotate on the lateral wall about the motor chamber and install the screw shaft, the guide block extends backward and stretches into and sliding fit the motor intracavity wall, the screw shaft with guide block threaded connection, fixed mounting has vice motor on the motor chamber diapire, power connection has the motor shaft on the vice motor, the motor shaft with the screw shaft is through connecting bevel gear group link, impel the groove with wall body between the motor chamber rotates installs the linking screw shaft of extending about, impel groove rear side wall bilateral symmetry is equipped with the chute that the opening is backward, linking screw shaft in impel groove female connection has bilateral symmetry and opposite screw thread's guide arm, the guide arm stretches into and sliding fit the chute inner wall.

Preferably, it in to link up the screw shaft link up the spline sleeve internal spline connection has linking up the spline sleeve, fixed mounting has movable worm wheel on the linking up the spline sleeve, the worm drive axle extends backward and runs through and swivelling joint impel the gear groove with wall body between the motor chamber, the worm drive axle in the motor chamber with movable worm wheel worm gear meshing connects, fixed mounting has the propulsion gear on the motor shaft, slidable mounting has the rack on the lateral wall before the motor chamber, the rack with impel gear meshing to connect, the rack with linking up the spline sleeve and rotate the connection.

Preferably, the movable supporting block is connected with the left side wall of the sliding groove through an ejection spring, the rear side of the sliding groove is communicated with a connecting cavity, a belt cavity is communicated between the connecting cavity and the propelling gear groove, the movable shaft extends backwards to extend into the connecting cavity, the movable shaft is in belt transmission connection with the worm transmission shaft through a connecting belt in the connecting cavity, the connecting shaft extends leftwards to penetrate and is in rotating connection with a wall body between the connecting cavity and the rotating groove, a fixed bevel gear is fixedly connected in the connecting cavity of the connecting shaft, a movable connection bevel gear is fixedly connected in the connecting cavity of the movable shaft, and the movable connection bevel gear is in meshing connection with the fixed bevel gear.

Preferably, the front end and the rear end of the segmented overturning plate are connected through torsion springs, the movable shaft can drive the rocker to rotate, and the movable shaft can be continuously overturned to prevent the rocker from rotating.

The beneficial effects are that: this device simple structure, convenient operation, through fixed bevel gear and swing joint bevel gear's separation meshing control skylight and baffle around separating the activity to in making the debris at door window top can directly not dropping the car, can drive the rotation support pole simultaneously and stretch out, make the people also have the strong point when the sky fenestra hole is stretched out for a short time, guarantee user's life safety, cooperation segmentation returning plate activity makes the user can get back to in the car and seal the sky fenestra hole rapidly when taking place dangerous situation simultaneously, improves the survival probability.

Drawings

In order to more clearly illustrate the embodiments of the invention 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, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a vehicle-mounted intelligent device according to the present invention;

FIG. 2 is a schematic cross-sectional view taken along line A-A of FIG. 1;

FIG. 3 is a schematic cross-sectional view taken along line B-B in FIG. 1;

FIG. 4 is a schematic cross-sectional view taken along line C-C in FIG. 2;

FIG. 5 is a top view of the segmented flipping panel of FIG. 1

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.

The invention will now be described in detail with reference to fig. 1-4, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The vehicle-mounted intelligent equipment of the device comprises a vehicle roof 23, wherein a skylight hole 12 which penetrates through the vehicle roof 23 up and down is arranged in the vehicle roof 23, a containing groove 14 with a forward opening is arranged on the rear side wall of the skylight hole 12, rotating rods 27 are symmetrically and rotatably arranged on the upper wall and the lower wall of the containing groove 14 left and right, a rotating support rod 38 is fixedly arranged on the rotating rod 27, the rotating support rods 38 on the left side and the right side are connected through a spring rope 39, a skylight containing cavity 16 with a leftward opening is communicated with the right side wall of the skylight hole 12, a clamp 19 is slidably arranged on the top wall of the skylight containing cavity 16, a skylight 17 is slidably arranged on the left side of the clamp 19, a partition plate 18 is slidably arranged on the bottom wall of the skylight containing cavity 16, a pushing gear groove 67 with an upward opening is arranged on the bottom wall of the skylight containing cavity 16, a worm transmission shaft 49 which extends back and forth is rotatably, the reciprocating gear 50 is engaged with the partition 18, the left side wall of the skylight opening 12 is communicated with an inclined plane groove 11 with a rightward opening, the front and rear walls of the inclined plane groove 11 are symmetrically communicated with sliding grooves 33 with openings facing the center of the inclined plane groove 11, movable supporting blocks 43 are slidably mounted in the sliding grooves 33, a movable shaft 42 extending forwards and backwards is rotatably connected between the front and rear movable supporting blocks 43 and the inclined plane groove 11, the movable shaft 42 is rotatably mounted in the inclined plane groove 11 in a front-back symmetrical manner and is provided with a rocker 40, the rocker 40 extends into the skylight opening 12 and is fixedly connected with a clamping plate 41, a pushing groove 52 with a forward opening is arranged on the lower side of the accommodating groove 14 on the rear side wall of the skylight opening 12, a sectional overturning plate 51 is slidably mounted in the pushing groove 52, the sectional overturning plate 51 is connected with the rear side wall of the pushing groove 52 through a spring, and a rotating groove 29 with a forward opening is arranged on the right side, the left side wall and the right side wall of the rotating groove 29 are rotatably provided with connecting shafts 30 extending left and right, the connecting shafts 30 are fixedly connected with lifting gears 31 in the rotating groove 29, the rear side wall of the skylight hole 12 is provided with a lifting top block 32 at the joint of the rotating groove 29 in a sliding manner, and the lifting top block 32 is meshed with the lifting gears 31.

Beneficially, a double-shaft motor 26 is fixedly installed on the rear side wall of the skylight accommodating cavity 16, a screw motor shaft 21 is dynamically connected to the double-shaft motor 26, screw blocks 22 are symmetrically and threadedly connected to the front and the back of the screw motor shaft 21 in the skylight accommodating cavity 16, the screw blocks 22 are in sliding fit with the right side wall of the skylight accommodating cavity 16, a rocker 20 is rotatably connected to the left side of the screw blocks 22, the rocker 20 is rotatably connected with the fixture 19, and the connecting shaft 30 extends rightward and is dynamically connected with the double-shaft motor 26.

Advantageously, the bottom wall of the receiving groove 14 is rotatably mounted with the transition shaft 13 on the left side and on the right side of the rotating rod 27, the transition shaft 13 is engaged with the rotating rod 27 through a connecting gear set 24, the rotating rod 27 on the right side is in belt transmission connection with the transition shaft 13 through a transmission belt 15, the rotating rod 27 on the right side extends downwards to penetrate through and is rotatably connected with a wall body between the rotating groove 29 and the accommodating groove 14, the rotating rod 27 is fixedly connected with a connecting fixed bevel gear 64 in the rotating groove 29, the connecting shaft 30 is connected with a movable spline sleeve 55 in the rotating groove 29 through a spline, the movable spline sleeve 55 is fixedly provided with a movable bevel gear 28, the movable bevel gear 28 is meshed with the engaging fixed bevel gear 64, the movable spline sleeve 55 is rotatably connected with a guide block 53, and the guide block 53 is in sliding fit with the rear side wall of the rotary groove 29.

Advantageously, the roof 23 is provided, on the rear side of the rotary slot 29, with a motor chamber 66 communicating with the rotary slot 29, the left side wall and the right side wall of the motor cavity 66 are rotatably provided with screw shafts 54, the guide block 53 extends backwards and extends into and is in sliding fit with the inner wall of the motor cavity 66, the screw shaft 54 is in threaded connection with the guide block 53, the bottom wall of the motor cavity 66 is fixedly provided with an auxiliary motor 37, the auxiliary motor 37 is connected with a motor shaft 63 in a power mode, the motor shaft 63 is connected with the screw shaft 54 through a bevel gear connecting set 62, the wall body between the propelling groove 52 and the motor cavity 66 is rotatably provided with a connecting screw shaft 59 extending left and right, the rear side wall of the pushing groove 52 is bilaterally symmetrically provided with inclined grooves 60 with backward openings, the connecting screw shaft 59 is connected with guide rods 61 which are bilaterally symmetrical and have opposite threads in the pushing groove 52 in an internal thread manner, and the guide rods 61 extend into and are in sliding fit with the inner walls of the inclined grooves 60.

Beneficially, the engagement screw shaft 59 is connected with the engagement spline sleeve 58 through a spline in the engagement spline sleeve 58, a movable worm wheel 57 is fixedly mounted on the engagement spline sleeve 58, the worm transmission shaft 49 extends backward to penetrate through and is connected with a wall body between the propulsion gear groove 67 and the motor cavity 66 in a rotating manner, the worm transmission shaft 49 is connected with the movable worm wheel 57 and the worm gear in a meshing manner, a propulsion gear 35 is fixedly mounted on the motor shaft 63, a rack 56 is mounted on the front side wall of the motor cavity 66 in a sliding manner, the rack 56 is connected with the propulsion gear 35 in a meshing manner, and the rack 56 is connected with the engagement spline sleeve 58 in a rotating manner.

Advantageously, the movable supporting block 43 is connected to the left side wall of the sliding slot 33 through an ejection spring 34, the rear side of the sliding slot 33 is communicated with a connecting cavity 47, a belt cavity 44 is communicated between the connecting cavity 47 and the pushing gear slot 67, the movable shaft 42 extends backwards to extend into the connecting cavity 47, the movable shaft 42 is in belt transmission connection with the worm transmission shaft 49 through a connecting belt 45 in the connecting cavity 47, the connecting shaft 30 extends leftwards to penetrate and is in rotating connection with the wall body between the connecting cavity 47 and the rotating slot 29, the connecting shaft 30 is fixedly connected with a fixed bevel gear 48 in the connecting cavity 47, the movable shaft 42 is fixedly connected with a movable connecting bevel gear 46 in the connecting cavity 47, and the movable connecting bevel gear 46 is in meshing connection with the fixed bevel gear 48.

Advantageously, the front and rear ends of the segment flipping plate 51 are connected by a torsion spring, the movable shaft 42 can drive the rocker 40 to rotate, and the movable shaft 42 can continue to flip without rotating the rocker 40.

In an initial state, the skylight accommodating cavity 16 and the partition plate 18 close the upper opening of the skylight hole 12, the rotary supporting rod 38 is accommodated in the accommodating groove 14, the segmented overturning plate 51 is accommodated in the pushing groove 52 and is in a horizontal state, the movable connecting bevel gear 46 is separated from the fixed bevel gear 48, the connecting fixed bevel gear 64 is meshed with the movable bevel gear 28, the movable worm gear 57 is separated from the worm transmission shaft 49, and the connecting transmission belt 45 is tensioned;

when the skylight is required to be opened, the double-shaft motor 26 is started to drive the screw motor shaft 21 and the connecting shaft 30 to rotate, the connecting shaft 30 drives the lifting top block 32 to move downwards through the lifting gear 31, the worm transmission shaft 49 drives the partition plate 18 to be retracted into the skylight accommodating cavity 16 through the reciprocating gear 50, meanwhile, the movable shaft 42 drives the clamping plate 41 to turn over through the rocker 40, the clamping plate 41 is matched with the lifting top block 32 to enable the skylight 17 to move downwards to the skylight accommodating cavity 16, the movable support block 43 drives the movable shaft 42 to move under the action of the ejection spring 34, the movable shaft 42 drives the movable connection bevel gear 46 to move so that the movable connection bevel gear 46 is meshed with the fixed bevel gear 48, the connecting shaft 30 drives the movable shaft 42 to rotate through the fixed bevel gear 48 and the movable connection bevel gear 46, the movable shaft 42 drives the worm transmission shaft 49 to rotate through the connection transmission belt 45, the front and rear threaded blocks 22 drive the fixture 19 to slide through the rocker 20, so as to drive the skylight 17 to be accommodated in the skylight accommodating cavity 16, the connecting shaft 30 drives the movable bevel gear 28 to rotate through the movable spline sleeve 55, the movable bevel gear 28 drives the right rotating rod 27 to rotate through the connecting fixed bevel gear 64, the right rotating rod 27 drives the transition shaft 13 to rotate through the transmission belt 15, the transition shaft 13 drives the left rotating rod 27 to rotate through the connecting gear set 24, the left and right rotating rods 27 rotate to transfer the rotating supporting rod 38 to extend out of the accommodating groove 14, and the left and right rotating supporting rods 38 enable the spring rope 39 to be spread and serve as a supporting point.

When an accident occurs, the auxiliary motor 37 is started and drives the motor shaft 63 to rotate, the motor shaft 63 drives the screw shaft 54 to rotate through the connecting bevel gear set 62, the screw shaft 54 drives the guide block 53 to drive the movable spline sleeve 55 to move through screw transmission, the movable spline sleeve 55 drives the movable bevel gear 28 to move and is connected with the fixed bevel gear 64 to separate, a person can manually drive the rotating support rod 38 to rotate and separate from the limit, the propelling gear 35 drives the rack 56 to move, the rack 56 drives the movable worm wheel 57 to move through the connecting spline sleeve 58, the movable worm wheel 57 is meshed with the worm transmission shaft 49, the screw motor shaft 21 rotates to drive the skylight accommodating cavity 16 and the skylight 17 to close the skylight hole 12 again, the connecting shaft 30 drives the worm transmission shaft 49 to rotate, the worm transmission shaft 49 drives the connecting screw shaft 59 to rotate through the movable worm wheel 57 and the connecting spline sleeve 58, and the screw shaft 59 enables the left, the guide rod 61 is movably matched with the chute 60 to extend the sectional overturning plate 51, and the front end of the sectional overturning plate 51 is overturned by extending the sectional overturning plate through a torsion spring, so that the human body is driven to be retracted into the vehicle.

After the operation is finished, the double-shaft motor 26 is turned off, the auxiliary motor 37 is turned back and then turned off, and the device is restored to the initial state.

Has the advantages that: this device simple structure, convenient operation, through fixed bevel gear and swing joint bevel gear's separation meshing control skylight and baffle around separating the activity to in making the debris at door window top can directly not dropping the car, can drive the rotation support pole simultaneously and stretch out, make the people also have the strong point when the sky fenestra hole is stretched out for a short time, guarantee user's life safety, cooperation segmentation returning plate activity makes the user can get back to in the car and seal the sky fenestra hole rapidly when taking place dangerous situation simultaneously, improves the survival probability.

The above description is only an embodiment of the invention, but the scope of the invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the invention. Therefore, the protection scope of the invention should be subject to the protection scope defined by the claims.

Claims

1. The utility model provides an on-vehicle smart machine, includes the roof, its characterized in that: the top of the car is internally provided with a skylight hole which penetrates through the car top up and down, the rear side wall of the skylight hole is provided with an accommodating groove with a forward opening, the upper wall and the lower wall of the accommodating groove are bilaterally and symmetrically provided with rotating rods, the rotating rods are fixedly provided with rotating supporting rods, the left side and the right side of the rotating supporting rods are connected through spring ropes, the right side wall of the skylight hole is communicated with a skylight accommodating cavity with a leftward opening, the top wall of the skylight accommodating cavity is slidably provided with a clamping device, the left side of the clamping device is slidably provided with a skylight, the bottom wall of the skylight accommodating cavity is slidably provided with a partition plate, the bottom wall of the skylight accommodating cavity is provided with a propelling gear groove with an upward opening, the front side and the rear side of the propelling gear groove are rotatably provided with a worm transmission shaft extending forwards and backwards, the worm transmission shaft is, the front wall and the rear wall of the inclined plane groove are symmetrically communicated with sliding grooves with openings facing the center of the inclined plane groove, movable supporting blocks are arranged in the sliding grooves in a sliding mode, movable shafts extending forwards and backwards are rotatably connected between the movable supporting blocks on the front side and the rear side in the inclined plane groove, the movable shafts are symmetrically rotatably arranged in the inclined plane groove in a front-back mode and are provided with rockers, the rockers extend into the skylight holes and are fixedly connected with clamping plates, a pushing groove with a forward opening is formed in the lower side of the accommodating groove on the rear side wall of the skylight holes, a segmented turnover plate is slidably arranged in the pushing groove and is connected with the rear side wall of the pushing groove through springs, a rotating groove with a forward opening is formed in the right side wall of the pushing groove on the rear side wall of the skylight holes, linking shafts extending leftwards and rightwards are rotatably arranged on the left side wall, the rear side wall of the skylight hole is provided with a lifting top block at the joint of the rotary groove in a sliding manner, and the lifting top block is in meshed connection with the lifting gear.

2. The vehicle-mounted intelligent device according to claim 1, wherein: fixed mounting has a biax motor on the chamber rear side wall is accomodate in the skylight, power is connected with the screw rod motor shaft on the biax motor, the screw rod motor shaft in the skylight is accomodate intracavity front and back symmetry threaded connection and is had the screw thread piece, screw thread piece sliding fit the chamber right side wall is accomodate in the skylight, screw thread piece left side is rotated and is connected with the rocker, the rocker with fixture rotate the connection, link up the axle extend right with biax motor power connects.

3. The vehicle-mounted intelligent device according to claim 2, wherein: the containing groove bottom wall is arranged on the left side, a transition shaft is installed on the right side of the rotating rod in a rotating mode, the transition shaft is meshed with the rotating rod through a connecting gear set, the rotating rod is connected with the transition shaft through a transmission belt in a transmission mode, the rotating rod extends downwards to penetrate through and is in rotating connection with the rotating groove and a wall body between the containing grooves, the rotating rod is fixedly connected with a linking fixed bevel gear in the rotating groove, the linking shaft is connected with a movable spline sleeve in the rotating groove in a spline mode, a movable bevel gear is fixedly installed on the movable spline sleeve, the movable bevel gear is meshed with the linking fixed bevel gear, a guide block is rotatably connected onto the movable spline sleeve, and the guide block is in sliding fit with the rear side wall of the rotating groove.

4. The vehicle-mounted intelligent device according to claim 3, wherein: the roof in the commentaries on classics groove rear side be equipped with the motor chamber of commentaries on classics groove intercommunication, rotate on the lateral wall about the motor chamber and install the screw shaft, the guide block extends backward and stretches into and sliding fit the motor intracavity wall, the screw shaft with guide block threaded connection, fixed mounting has vice motor on the motor chamber diapire, power connection has the motor shaft on the vice motor, the motor shaft with the screw shaft is through connecting bevel gear group link, impel the groove with wall body between the motor chamber rotates installs the linking screw shaft of extending about, impel groove rear side wall bilateral symmetry and be equipped with the chute that the opening is backward, screw linking axle in impel groove female connection has bilateral symmetry and opposite screw thread's guide arm, the guide arm stretches into and sliding fit the chute inner wall.

5. The vehicle-mounted intelligent device according to claim 4, wherein: linking screw shaft in linking up spline sleeve internal spline and being connected with linking spline sleeve, fixed mounting has movable worm wheel on the linking spline sleeve, the worm transmission shaft extends backward and runs through and swivelling joint impel the gear groove with wall body between the motor chamber, the worm transmission shaft in the motor chamber with movable worm wheel worm gear meshing connects, fixed mounting has the propulsion gear on the motor shaft, slidable mounting has the rack before the motor chamber on the lateral wall, the rack with impel gear meshing and connect, the rack with linking spline sleeve and rotating the connection.

6. The vehicle-mounted intelligent device according to claim 5, wherein: the movable supporting block is connected with the left side wall of the sliding groove through an ejection spring, the rear side of the sliding groove is communicated with a connecting cavity, a belt cavity is communicated between the connecting cavity and the propelling gear groove, the movable shaft extends backwards to extend into the connecting cavity, the movable shaft is in belt transmission connection with the worm transmission shaft through a connecting transmission belt in the connecting cavity, the connecting shaft extends leftwards to penetrate through and is in rotating connection with a wall body between the connecting cavity and the rotating groove, a fixed bevel gear is fixedly connected in the connecting cavity, a movable connection bevel gear is fixedly connected in the connecting cavity, and the movable connection bevel gear is in meshing connection with the fixed bevel gear.

7. The vehicle-mounted intelligent device according to claim 6, wherein: the front end and the rear end of the segmented overturning plate are connected through torsion springs, the movable shaft can drive the rocker to rotate, and the movable shaft can be continuously overturned to prevent the rocker from rotating.