CN219757250U - Automatic three-dimensional measuring device - Google Patents

Abstract

The utility model belongs to the technical field of measuring devices, and particularly relates to an automatic three-dimensional measuring device which comprises a base, wherein a rotating rod is rotatably connected inside the base through a bearing, and the top end of the rotating rod penetrates through the top of the base and is fixedly provided with a supporting tray. According to the utility model, the rotation of the object to be measured can be realized by arranging the rotating rod, the bearing tray, the first driven large gear, the first motor and the first driving small gear, and the heights and angles of the three-dimensional scanner can be adjusted by arranging the supporting plate, the lifting assembly and the adjusting assembly, so that the object can be better scanned and measured.

Description

Automatic three-dimensional measuring device

Technical Field

The utility model relates to the technical field of measuring devices, in particular to an automatic three-dimensional measuring device.

Background

With the development of society and the advancement of science and technology, when measuring appearance data of some articles and constructing models thereof, a three-dimensional scanner is needed, and currently, a worker usually holds the three-dimensional scanner to scan all angles of the articles, so that the operation is time-consuming and labor-consuming, and the scanning measurement efficiency is low, therefore, an automatic three-dimensional measuring device is provided to solve the problems.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the utility model provides an automatic three-dimensional measuring device, which solves the problems in the background art.

(II) technical scheme

The utility model adopts the following technical scheme for realizing the purposes:

the utility model provides an automatic change three-dimensional measuring device, includes the base, the inside of base is connected with the bull stick through the bearing rotation, the top of bull stick runs through the top of base and is fixed with the support tray, the surface cover of bull stick is established and is fixed with first driven gear, the bottom inner wall of base is fixed with first motor, the output shaft of first motor is fixed with the first initiative pinion that is connected with first driven gear meshing, the top of base is provided with the backup pad, the top of base is provided with the lifting unit who is used for adjusting backup pad height, one side of backup pad is provided with clamping assembly, the top of backup pad is provided with the adjusting part that is used for adjusting clamping assembly angle, be provided with three-dimensional scanner on the clamping assembly.

Further, lifting assembly is including fixing the L template at the base top, the top of base is connected with unidirectional screw through the bearing rotation, unidirectional screw's top is connected with the top rotation of L template through the bearing, the top of L template is fixed with the second motor, the output shaft of second motor and unidirectional screw's top fixed connection, the top symmetry of base is fixed with two guide bars, the top of guide bar all with the top fixed connection of L template, backup pad threaded connection is at unidirectional screw's surface, backup pad sliding connection is at the surface of two guide bars.

Further, the clamping assembly comprises a frame body arranged on one side of the supporting plate, a bidirectional screw rod is rotatably connected to the inside of the frame body through a bearing, a knob is fixed to one end of the bidirectional screw rod, two connecting blocks are symmetrically connected to the surface of the bidirectional screw rod in a threaded mode, two through holes matched with the connecting blocks are symmetrically formed in the top of the frame body, and the top ends of the connecting blocks penetrate through the corresponding through holes in a sliding mode and are fixedly provided with clamping plates.

Further, a side wall of the clamping plate is fixedly provided with an anti-slip rubber pad, and anti-slip lines are formed in the surface of the knob.

Further, the adjusting component comprises two support blocks symmetrically fixed at the top of the support plate, a first shaft rod is rotatably connected between the two support blocks through bearings, connecting strips are fixedly sleeved on the surfaces of two ends of the first shaft rod, one ends of the connecting strips are fixedly connected with the surface of the frame body, a second driven large gear is fixedly sleeved on the two ends of the first shaft rod, a second shaft rod is rotatably connected between the two support blocks through bearings, a second driving pinion in meshed connection with the second driven large gear is fixedly sleeved on the two ends of the second shaft rod, a third motor is fixedly arranged at the top of the support plate, and an output shaft of the third motor is fixedly connected with one end of the second shaft rod.

(III) beneficial effects

Compared with the prior art, the utility model provides an automatic three-dimensional measuring device, which comprises the following components

The beneficial effects are that:

according to the utility model, the rotation of the object to be measured can be realized by arranging the rotating rod, the supporting plate, the lifting assembly and the adjusting assembly, and the height and the angle of the three-dimensional scanner can be adjusted, so that the object can be better scanned and measured.

Drawings

FIG. 1 is a schematic view of a first view angle structure of the whole of the present utility model;

FIG. 2 is a schematic diagram of the overall second view structure of the present utility model;

FIG. 3 is a schematic view of the structure of the support plate of the present utility model;

FIG. 4 is a schematic view of a clamping assembly according to the present utility model;

fig. 5 is a schematic view of the structure of the connecting block of the present utility model.

In the figure: 1. a base; 2. a rotating rod; 3. a tray; 4. a first driven gearwheel; 5. a first motor; 6. a first drive pinion; 7. a support plate; 8. a lifting assembly; 801. an L-shaped plate; 802. a unidirectional screw; 803. a second motor; 804. a guide rod; 9. a clamping assembly; 901. a frame; 902. a bidirectional screw; 903. a knob; 904. a connecting block; 905. a through port; 906. a clamping plate; 10. an adjustment assembly; 1001. a bracket block; 1002. a first shaft; 1003. a connecting strip; 1004. a second driven gearwheel; 1005. a second shaft; 1006. a second drive pinion; 1007. a third motor; 11. a three-dimensional scanner.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Examples

As shown in fig. 1 and 2, an automatic three-dimensional measuring device according to an embodiment of the present utility model includes a base 1, a rotating rod 2 rotatably connected to the inside of the base 1 through a bearing, a supporting plate 3 fixed to the top of the rotating rod 2 penetrating through the top of the base 1, a first driven gearwheel 4 fixed to the surface of the rotating rod 2, a first motor 5 fixed to the inner wall of the bottom of the base 1, a first driving pinion 6 meshed with the first driven gearwheel 4 fixed to an output shaft of the first motor 5, a supporting plate 7 arranged above the base 1, a lifting assembly 8 for adjusting the height of the supporting plate 7 arranged at the top of the base 1, a clamping assembly 9 arranged at one side of the supporting plate 7, an adjusting assembly 10 for adjusting the angle of the clamping assembly 9 arranged at the top of the supporting plate 7, and a three-dimensional scanner 11 arranged on the clamping assembly 9, the article to be measured is placed on the supporting plate 3, the article can be scanned and measured through the three-dimensional scanner 11, when the angle of the article needs to be adjusted, the first motor 5 can be started, the first motor 5 can drive the first driving pinion 6 to rotate, the first driving pinion 6 can drive the first driven big gear 4 to rotate, the first driven big gear 4 can drive the rotating rod 2 to rotate, the rotating rod 2 can drive the supporting plate 3 to rotate, thereby the article to be measured can be driven to rotate, the condition that the rotation rate of the supporting plate 3 is slower, the article placed on the top of the supporting plate cannot be displaced can be explained, when the height of the three-dimensional scanner 11 needs to be adjusted, the lifting assembly 8 can be utilized for adjustment, when the angle of the three-dimensional scanner 11 needs to be adjusted, the adjusting assembly 10 can be utilized for adjustment, when the three-dimensional scanner 11 fails, it can be removed from the clamping assembly 9 so that it can be serviced.

As shown in fig. 1, fig. 2 and fig. 3, in some embodiments, the lifting assembly 8 includes an L-shaped plate 801 fixed on the top of the base 1, the top of the base 1 is rotatably connected with a unidirectional screw 802 through a bearing, the top of the unidirectional screw 802 is rotatably connected with the top of the L-shaped plate 801 through a bearing, the top of the L-shaped plate 801 is fixed with a second motor 803, an output shaft of the second motor 803 is fixedly connected with the top of the unidirectional screw 802, the top of the base 1 is symmetrically fixed with two guide rods 804, the top of the guide rods 804 is fixedly connected with the top of the L-shaped plate 801, the support plate 7 is in threaded connection with the surface of the unidirectional screw 802, the support plate 7 is in sliding connection with the surface of the two guide rods 804, when the height of the three-dimensional scanner 11 needs to be adjusted, the second motor 803 can be started, the unidirectional screw 802 can drive the unidirectional screw 802 to move in the vertical direction, and thus the height of the three-dimensional scanner 11 can be adjusted.

As shown in fig. 1, fig. 4 and fig. 5, in some embodiments, the clamping assembly 9 includes a frame 901 disposed at one side of the support plate 7, a bidirectional screw 902 is rotatably connected to the inside of the frame 901 through a bearing, a knob 903 is fixed at one end of the bidirectional screw 902, two connecting blocks 904 are symmetrically screwed on the surface of the bidirectional screw 902, two through openings 905 adapted to the connecting blocks 904 are symmetrically provided at the top of the frame 901, the top ends of the connecting blocks 904 slide through the corresponding through openings 905 and are fixed with clamping plates 906, one side wall of each clamping plate 906 is fixed with an anti-slip rubber pad, which can play a better anti-slip role, so that the three-dimensional scanner 11 can be clamped more firmly, the surface of the knob 903 is provided with an anti-slip grain, which can play a better anti-slip role, so that the user can rotate conveniently, when the three-dimensional scanner 11 is required to be disassembled for maintenance, the knob 903 can drive the bidirectional screw 902 to rotate, the bidirectional screw 902 can drive the two connecting blocks 904 to move outwards, and the connecting blocks 904 can drive the corresponding clamping plates to move outwards, so that the three-dimensional scanner 11 can be disassembled.

As shown in fig. 1 and fig. 2, in some embodiments, the adjusting component 10 includes two support blocks 1001 symmetrically fixed on the top of the supporting plate 7, a first shaft rod 1002 is rotatably connected between the two support blocks 1001 through bearings, connecting strips 1003 are respectively sleeved and fixed on two end surfaces of the first shaft rod 1002, one ends of the two connecting strips 1003 are respectively fixedly connected with the surface of the frame 901, a second driven gear wheel 1004 is respectively sleeved and fixed on two ends of the first shaft rod 1002, a second driving pinion 1006 is rotatably connected between the two support blocks 1001 through bearings, two ends of the second shaft rod 1005 are respectively sleeved and fixed with a second driving pinion 1006 which is meshed and connected with the second driven gear wheel 1004, a third motor 1007 is fixed on the top of the supporting plate 7, an output shaft of the third motor 1007 is fixedly connected with one end of the second shaft rod 1005, when the angle of the three-dimensional scanner 11 needs to be adjusted, the third motor 1007 can be started, the third motor 1007 can drive the second shaft rod 1005 can drive the two second driving pinions 1006 to rotate, the second driving pinions 1006 can drive the corresponding second driven gears 1004 to rotate, the second driven gears 1004 can drive the two driven gears 1003 to rotate, the two driven gears 1003 can drive the two driven gears to rotate, and the two driven shafts 1002 can drive the two driven shafts to rotate the three-dimensional scanner 11 to rotate, so that the two driven shafts can drive the two driven shafts to rotate 1002 to rotate, and can be rotatably driven by two driven shafts to rotate.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present utility model has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (5)

1. An automated three-dimensional measuring device comprising a base (1), characterized in that: the inside of base (1) is connected with bull stick (2) through the bearing rotation, the top of bull stick (2) runs through the top of base (1) and is fixed with supporting disk (3), the surface cover of bull stick (2) is established and is fixed with first driven gear wheel (4), the bottom inner wall of base (1) is fixed with first motor (5), the output shaft of first motor (5) is fixed with first initiative pinion (6) of being connected with first driven gear wheel (4) meshing, the top of base (1) is provided with backup pad (7), the top of base (1) is provided with lifting unit (8) that are used for adjusting the height of backup pad (7), one side of backup pad (7) is provided with clamping unit (9), the top of backup pad (7) is provided with adjusting unit (10) that are used for adjusting clamping unit (9) angle, be provided with three-dimensional scanner (11) on clamping unit (9).

2. An automated three-dimensional measurement device according to claim 1, wherein: lifting unit (8) are including fixing L template (801) at base (1) top, the top of base (1) is connected with unidirectional screw (802) through the bearing rotation, the top of unidirectional screw (802) is connected with the top rotation of L template (801) through the bearing, the top of L template (801) is fixed with second motor (803), the output shaft of second motor (803) and the top fixed connection of unidirectional screw (802), the top symmetry of base (1) is fixed with two guide bars (804), the top of guide bar (804) all is connected with the top fixed connection of L template (801), backup pad (7) threaded connection is on the surface of unidirectional screw (802), backup pad (7) sliding connection is at the surface of two guide bars (804).

3. An automated three-dimensional measurement device according to claim 1, wherein: clamping assembly (9) are including setting up framework (901) in backup pad (7) one side, the inside of framework (901) is connected with bi-directional screw (902) through the bearing rotation, the one end of bi-directional screw (902) is fixed with knob (903), the surface symmetry threaded connection of bi-directional screw (902) has two connecting blocks (904), two through openings (905) that adapt to connecting block (904) have been seted up to the top symmetry of framework (901), the top of connecting block (904) slides and runs through corresponding through opening (905) and is fixed with splint (906).

4. An automated three-dimensional measurement device according to claim 3, wherein: an anti-slip rubber pad is fixed on one side wall of the clamping plate (906), and anti-slip lines are formed in the surface of the knob (903).

5. An automated three-dimensional measurement device according to claim 3, wherein: the adjusting component (10) comprises two support blocks (1001) symmetrically fixed at the top of the supporting plate (7), a first shaft rod (1002) is rotatably connected between the two support blocks (1001) through bearings, connecting strips (1003) are fixedly sleeved on the surfaces of the two ends of the first shaft rod (1002), one ends of the connecting strips (1003) are fixedly connected with the surface of the frame body (901), a second driven gearwheel (1004) is fixedly sleeved on the two ends of the first shaft rod (1002), a second shaft rod (1005) is rotatably connected between the two support blocks (1001) through bearings, a second driving pinion (1006) meshed with the second driven gearwheel (1004) is fixedly sleeved on the two ends of the second shaft rod (1005), a third motor (1007) is fixedly connected with the top of the supporting plate (7), and an output shaft of the third motor (1007) is fixedly connected with one end of the second shaft rod (1005).