CN209910649U

CN209910649U - Dynamic inclination angle sensor

Info

Publication number: CN209910649U
Application number: CN201920949895.1U
Authority: CN
Inventors: 杨军
Original assignee: Shenzhen Wogan Technology Co Ltd
Current assignee: Shenzhen Wogan Technology Co Ltd
Priority date: 2019-06-24
Filing date: 2019-06-24
Publication date: 2020-01-07
Anticipated expiration: 2029-06-24

Abstract

The utility model discloses a dynamic inclination sensor, including main part, preceding bottom plate and back bottom plate, main part bottom integrated into one piece is connected with the base, be provided with shaft hole and last spout on the base, the shaft hole is seted up in base top front end both sides, and the shaft hole is inside to be connected with preceding swivel nut through the bearing interference, go up the spout and set up in base top rear end both sides, go up the inside both sides of spout and seted up the side spout, the inside nested axle sleeve that has of side spout, the preceding bottom plate is placed in main part bottom front end, the back bottom plate symmetry is placed in main part bottom rear end. The utility model discloses can easily install dynamic tilt sensor on the assigned position.

Description

Dynamic inclination angle sensor

Technical Field

The utility model relates to a developments inclination sensor belongs to inclination sensor technical field.

Background

The dynamic tilt angle sensor is an inertia product which is specially used for providing dynamic roll and pitch angle measurement with high refresh rate for moving objects; the installation angle of the current dynamic tilt angle sensor is a fixed structure, and cannot be adjusted according to an installation surface, so that the construction efficiency is seriously influenced. In order to solve the problems, a new technical scheme is provided.

Disclosure of Invention

An object of the utility model is to provide a dynamic tilt angle sensor to solve the problem that proposes among the above-mentioned background art.

In order to realize the purpose, the utility model adopts the following technical scheme: the utility model provides a dynamic tilt sensor, includes main part, preceding bottom plate and back bottom plate, main part bottom integrated into one piece is connected with the base, be provided with shaft hole and last spout on the base, the shaft hole is seted up in base top front end both sides, and the shaft hole is inside to be connected with preceding swivel nut through the bearing interference, the last spout is seted up in base top rear end both sides, and the side spout has been seted up to the inside both sides of last spout, the inside nested axle sleeve that has of side spout, the preceding bottom plate is placed in main part bottom front end, the back bottom plate symmetry is placed in main part bottom rear end.

Preferably, the top of the front threaded sleeve is welded with a front jacking column, and the top of the front jacking column is provided with a front cross groove.

Preferably, be provided with fastening bolt and back swivel nut on the axle sleeve, fastening bolt threaded connection is in the axle sleeve outside, and fastening bolt nestification is in the side spout, back swivel nut passes through the bearing interference and connects inside the axle sleeve, and the welding of back swivel nut top has the back fore-set, back cross recess has been seted up at back fore-set top.

Preferably, the front bottom plate is provided with a front screw, a front through groove and a connecting rod, the front screw is welded on two sides of the top of the front bottom plate and is in threaded connection with the front threaded sleeve, the front through groove is formed in the top of the front bottom plate, the connecting rod is welded in the middle of the rear end of the front bottom plate, and lower through grooves are formed in two sides of the connecting rod.

Preferably, be provided with back screw rod, back logical groove and slider on the back bottom plate, back screw rod welds in back bottom plate top outer end, and back screw rod and back swivel nut threaded connection, back logical groove is seted up in back bottom plate top, the slider welds in back bottom plate inner, and the slider nestification is in logical inslot down.

Compared with the prior art, the beneficial effects of the utility model are that: the front threaded sleeve is connected inside the shaft hole through the bearing in an interference manner, so that the front threaded sleeve can easily rotate; the shaft sleeve is nested in the side sliding groove, so that the shaft sleeve can easily slide back and forth along the side sliding groove; the front screw is in threaded connection with the front threaded sleeve, and the front screw can be easily driven to lift through the front threaded sleeve; the rear screw is in threaded connection with the rear threaded sleeve, and the rear screw can be easily driven to lift through the rear threaded sleeve; the fastening bolt is in threaded connection with the outer side of the shaft sleeve and is nested in the side sliding groove, so that the position of the shaft sleeve can be easily locked; the slider is nested in the lower through groove, can make the back bottom plate easily slide from beginning to end along the lower through groove.

Drawings

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

FIG. 2 is a schematic view of the main structure of the present invention;

FIG. 3 is a schematic structural view of the front bottom plate of the present invention;

FIG. 4 is a schematic structural view of the rear bottom plate of the present invention;

in the figure: 1-a body; 2-front bottom plate; 3-rear bottom plate; 4-a base; 5-shaft hole; 6-an upper chute; 7-side chute; 8-front threaded sleeve; 9-front top pillar; 10-a front cross groove; 11-front screw rod; 12-front through groove; 13-a connecting rod; 14-lower through groove; 15-shaft sleeve; 16-tightening the bolt; 17-rear threaded sleeve; 18-rear top pillar; 19-rear cross groove; 20-rear screw rod; 21-rear through groove; 22-sliding block.

Detailed Description

The technical solution in the embodiment of the present invention will be clearly and completely explained below with reference to the drawings in the embodiment of the present invention.

As shown in fig. 1-4, a dynamic tilt sensor, including main part 1, preceding bottom plate 2 and back bottom plate 3, main part 1 bottom integrated into one piece is connected with base 4, be provided with shaft hole 5 and last spout 6 on base 4, shaft hole 5 is seted up in base 4 top front end both sides, the inside swivel nut 8 that is connected with through bearing interference in shaft hole 5, last spout 6 is seted up in base 4 top rear end both sides, side spout 7 has been seted up to the inside both sides of last spout 6, the inside nested axle sleeve 15 that has of side spout 7, preceding bottom plate 2 is placed in main part 1 bottom front end, back bottom plate 3 symmetry is placed in main part 1 bottom rear end.

The specific use mode is as follows: when the dynamic tilt sensor is installed, the front support pillar 9 and the rear support pillar 18 are screwed according to the height required to be installed, the front support pillar 9 rotates to drive the front threaded sleeve 8 to rotate, the front threaded sleeve 8 rotates to drive the front screw rod 11 to linearly lift, and the front screw rod 11 linearly lifts to drive the front bottom plate 2 to linearly lift to adjust the distance between the front through groove 12 and the main body 1; the rear top post 18 rotates to drive the rear threaded sleeve 17 to rotate, the rear threaded sleeve 17 rotates to drive the rear screw 20 to linearly lift, and the rear screw 20 linearly lifts to drive the rear bottom plate 3 to linearly lift to adjust the distance between the rear through groove 21 and the main body 1; then, according to the distance between the mounting screw holes, the rear jacking pillar 18 is pushed and pulled back and forth to drive the shaft sleeve 15 to slide back and forth along the side sliding groove 7, the shaft sleeve 15 slides back and forth to drive the rear bottom plate 3 to slide back and forth along the lower through groove 14, and the rear bottom plate 3 slides back and forth to adjust the distance between the rear through groove 21 and the front through groove 12; finally, bolts are passed through the rear through grooves 21 and the front through grooves 12 to fix the main body 1 at a specified position.

The foregoing is a preferred embodiment of the present invention, and for those skilled in the art to understand the teaching of the present invention, the changes, modifications, replacements and variations to the embodiments will still fall within the protection scope of the present invention without departing from the principle and spirit of the present invention.

Claims

1. A dynamic tilt sensor, comprising a main body (1), a front base plate (2) and a rear base plate (3), characterized in that: main part (1) bottom integrated into one piece is connected with base (4), be provided with shaft hole (5) and last spout (6) on base (4), base (4) top front end both sides are seted up in shaft hole (5), and shaft hole (5) are inside to be connected with preceding swivel nut (8) through the bearing interference, go up spout (6) and set up in base (4) top rear end both sides, go up the inside both sides of spout (6) and seted up side spout (7), side spout (7) inside nested there is axle sleeve (15), place in main part (1) bottom front end front bottom plate (2), back bottom plate (3) symmetry is placed in main part (1) bottom rear end.

2. A dynamic tilt sensor according to claim 1, wherein: the front top post (9) is welded at the top of the front screw sleeve (8), and a front cross groove (10) is formed in the top of the front top post (9).

3. A dynamic tilt sensor according to claim 1, wherein: be provided with tight set bolt (16) and back swivel nut (17) on axle sleeve (15), tight set bolt (16) threaded connection in axle sleeve (15) outside, and tight set bolt (16) nestification in side spout (7), back swivel nut (17) are connected in axle sleeve (15) inside through the bearing interference, and back swivel nut (17) top welding has back fore-set (18), back cross recess (19) have been seted up at back fore-set (18) top.

4. A dynamic tilt sensor according to claim 1, wherein: preceding screw rod (11), preceding logical groove (12) and connecting rod (13) are provided with on preceding bottom plate (2), preceding screw rod (11) weld in preceding bottom plate (2) top both sides, and preceding screw rod (11) and preceding swivel nut (8) threaded connection, preceding logical groove (12) are seted up in preceding bottom plate (2) top, connecting rod (13) weld in the middle of preceding bottom plate (2) rear end, and logical groove (14) have been seted up down to connecting rod (13) both sides.

5. A dynamic tilt sensor according to claim 1, wherein: be provided with back screw rod (20), back logical groove (21) and slider (22) on back bottom plate (3), back screw rod (20) weld in back bottom plate (3) top outer end, and back screw rod (20) and back swivel nut (17) threaded connection, back logical groove (21) are seted up in back bottom plate (3) top, slider (22) weld in back bottom plate (3) inner, and slider (22) nestification is led to in groove (14) down.