CN220463816U - Universal support bracket system for optical scanning - Google Patents

Abstract

The utility model relates to a universal support bracket system for optical scanning in the field of solid product size inspection, which comprises a support mechanism, a bracket center shaft, a rotating shaft system and a fixed quick clamp; the supporting mechanism is connected with the middle shaft of the bracket; a rotatable first regulating switch is arranged on the middle shaft of the bracket; the first regulating switch is positioned above the connecting part of the supporting mechanism and the middle shaft of the bracket; the rotating shaft system comprises an X-axis rotating shaft, a Y-axis rotating shaft and a Z-axis rotating shaft; the measured product is fixedly placed on the fixed quick clamp, and the measured product is adjusted to a proper position by using the X-axis rotating shaft, the Y-axis rotating shaft and the Z-axis rotating shaft together for measurement by the optical scanning equipment; the utility model solves the problem that the shielding surface exists in the prior art when the product collects data, and the shielding surface can not synchronously and comprehensively collect the data of the tested product.

Description

Universal support bracket system for optical scanning

Technical Field

The utility model relates to the field of product size inspection, in particular to a universal support bracket system for optical scanning.

Background

When scanning the product and gathering data, will be surveyed the product and place at an regional position at random, can lead to the one side of product to receive to shelter from like this, and the face that shelters from of product is the work that can't carry out data acquisition in step at this moment, because the position of optical scanning equipment is fixed, so need the inspection personnel upset product to carry out secondary measurement, can increase useless data during the secondary measurement, after the measurement is accomplished, need the inspection personnel to remove useless data again manually, this certainly has increased inspection personnel's work load. This is only for a single product, and when the number of products is large, the efficiency of data collection is reduced.

Disclosure of Invention

In order to solve the technical problems that the data acquisition efficiency is low, the workload of inspection staff is large, and the product needs to be turned over to carry out secondary measurement, and the data of the product cannot be synchronously and comprehensively acquired, the utility model discloses a universal support bracket system for optical scanning.

The technical scheme of the utility model is realized as follows:

a gimbaled support bracket system for optical scanning, comprising: the device comprises a supporting mechanism, a bracket center shaft, a rotating shaft system and a fixed quick clamp;

the supporting mechanism is connected with the middle shaft of the bracket;

a rotatable first regulating switch is arranged on the middle shaft of the bracket;

the first regulating switch is positioned above the connecting part of the supporting mechanism and the middle shaft of the bracket;

the rotating shaft system comprises a central shaft, a first shaft body shell, a second shaft body shell, a first locking screw, an X-axis rotating shaft, a Y-axis rotating shaft and a Z-axis rotating shaft;

the first shaft body shell and the second shaft body shell are sleeved on the central shaft;

the X-axis rotating shaft comprises a first X-axis rotating shaft and a first locking screw;

the first X-axis rotating shaft is rotatably connected to the central shaft and is positioned on the right side of the first shaft body shell;

the first locking screw is rotatably arranged at two sides of the first shaft body shell;

the Y-axis rotating shaft comprises a first Y-axis rotating shaft and a second locking screw;

the first Y-axis rotating shaft is positioned at two sides of the second shaft body shell;

the second locking screw is positioned above the second shaft body shell and used for clamping the first Y-axis rotating shaft;

the Z-axis rotating shaft comprises the first Z-axis rotating shaft and a second Z-axis rotating shaft;

the first Z-axis rotating shaft penetrates through the first shaft body outer shell to be connected with the fixed quick clamp, and the second Z-axis rotating shaft penetrates through the second shaft body outer shell to be connected with the bracket center shaft.

Preferably, the rotating shaft system further comprises a through cavity and a counterweight balance rod;

the through cavity is connected to the left side of the second shaft body shell;

the counterweight balance rod is slidably arranged in the through cavity.

Preferably, a third locking screw is further arranged above the through cavity and used for locking the counterweight balance rod.

Preferably, the X-axis rotation axis, the Y-axis rotation axis and the Z-axis rotation axis adopt a movable structure.

Preferably, the three legs of the supporting mechanism are also provided with rotatable second adjusting switches.

The utility model can solve the technical problems that the product in the prior art has a shielding surface when collecting data, and the data of the product can not be synchronously and comprehensively collected when collecting the data; according to the utility model, the measured product is fixedly placed on the fixed quick clamp, and the position of the measured product is jointly adjusted by using the X-axis rotating shaft, the Y-axis rotating shaft and the Z-axis rotating shaft, so that the technical effect of synchronously and comprehensively collecting the product data can be realized in a mode of measuring by the optical scanning equipment.

Drawings

In order to more clearly illustrate the embodiments of the present utility model 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, wherein like parts are denoted by like reference numerals. It should be noted that the words "front", "rear", "left", "right", "upper" and "lower" used in the following description refer to directions in the drawings.

FIG. 1 is a schematic diagram of the overall structure of an embodiment;

FIG. 2 is a schematic view of the center shaft structure of the tripod;

FIG. 3 is a schematic axial view of a support bracket;

fig. 4 is a left side view of fig. 1.

In the above drawings, each reference numeral indicates: 1. supporting mechanism

1-1, second regulating switch

2. Bracket center shaft

2-1, a first regulating switch

3. Fixed quick clamp

4. X-axis rotation axis

4-1, first X-axis rotation

4-2, first locking screw

5. Y-axis rotation axis

5-1, first Y-axis rotation axis

5-2, second locking screw

6. Z-axis rotation axis

6-1, first Z axial rotation axis

6-2, second Z axial rotation axis

7. Balance weight balance rod

8. First shaft housing

9. Second shaft body shell

10. Through cavity

10-1, third locking screw

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, 2 and 4, a universal support bracket system for optical scanning comprises a support mechanism 1, a bracket center shaft 2, a rotating shaft system (not shown in the figures) and a fixed quick clamp 3; in the embodiment, a bracket center shaft 2 is connected through a supporting mechanism 1; the bracket center shaft 2 is connected with a rotating shaft system; the rotating shaft system is connected below the fixed quick clamp 3 to jointly form a bracket system.

A rotatable first regulating switch 2-1 is arranged on the bracket center shaft 2; the first regulating switch 2-1 is positioned above the connecting part of the supporting mechanism 1 and the bracket center shaft 2, and the first regulating switch 2-1 can be rotated to regulate the height of the bracket when in use, so as to adapt to different scanning devices and enrich the applicable scenes of the bracket.

When the product is measured, the measured product is fixed by the fixed quick clamp 3, and the rotating shaft system is adjusted to enable the product to be positioned at a proper position according to the specific requirements of the scanning equipment, and the measurement is carried out. The rotation shaft system includes a central shaft (not shown), a first shaft housing 8, a second shaft housing 9, a first locking screw 4-2, an X-axis rotation shaft 4, a Y-axis rotation shaft 5, and a Z-axis rotation shaft 6. The first shaft housing 8 and the second shaft housing 9 are sleeved on the central shaft, wherein the X-axis rotation shaft 4, the Y-axis rotation shaft 5 and the Z-axis rotation shaft 6 are defined according to the positions of the adjustable products in the space. The X-axis rotation shaft 4 comprises a first X-axis rotation shaft 4-1 and a first locking screw 4-2, the first X-axis rotation shaft 4-1 is rotatably connected to the central shaft and positioned on the right side of the first shaft housing 8, and the first locking screw 4-2 is rotatably arranged on two sides of the first shaft housing 8; the Y-axis rotating shaft 5 comprises a first Y-axis rotating shaft 5-1 and a second locking screw 5-2, and the second locking screw 5-2 is located above the second shaft housing 9 and is used for clamping the first Y-axis rotating shaft 5-1. The Z-axis rotating shaft 6 comprises a first Z-axis rotating shaft 6-1 and a second Z-axis rotating shaft 6-2, wherein the first Z-axis rotating shaft 6-1 penetrates through a first shaft body shell 8 to be connected with the fixed quick clamp 3, and the second Z-axis rotating shaft 6-2 penetrates through a second shaft body shell 9 to be connected with the bracket center shaft 2.

When the X-axis quick clamp is used, the first locking screw 4-2 is rotated and loosened, the first shaft body shell 8 and the fixed quick clamp 3 horizontally move in the X-axis direction by rotating the first X-axis rotating shaft 4-1 clockwise or anticlockwise, the horizontal position of the fixed quick clamp 3 is adjusted, and the position of the fixed quick clamp 3 is fixed by screwing the first locking screw 4-2 after the position adjustment is completed; the second locking screw 5-2 and the first Y-axis rotating shaft 5-1 are rotated and loosened, and the angles of the first shaft body shell 8 and the fixed quick clamp 3 are manually adjusted; through rotating the first Z axial rotation shaft 6-1, fine adjustment is carried out on the fixed quick clamp 3, the fixed quick clamp 3 can ascend along the Z axial direction, the second Z axial rotation shaft 6-2 is rotated, the rotation shaft system and the fixed quick clamp 3 integrally ascend along the Z axial direction, so that the height of a measured product can be indirectly adjusted, and after the position adjustment of the measured product is completed, the first locking screw 4-2 and the second locking screw 5-2 are locked, so that integral fixation is realized.

Since the measured product is fixed by the fixing quick clamp 3, the product can still be covered by a part, but the data acquisition is not affected in the measuring process, so that the whole data of the measured product can be synchronously and comprehensively carried out. And the fixed fast clamp 3 is positioned at a fixed position after the adjustment, so that when other tested products are scanned, the tested products are only required to be placed on the fixed fast clamp, the positions of the tested products do not need to be rearranged, and the data of the tested products can be comprehensively and synchronously collected, so that useless data deletion is not required, the workload of inspection staff is effectively reduced, and the data collection efficiency is improved.

In a preferred embodiment, during the measurement of the product, since the fixed quick clamp 3 and the measured product have a certain weight, and may be in an unbalanced state during use, in order to ensure that the product is in a balanced state, the rotating shaft system is further provided with a through cavity 10 and a counterweight balance rod 7, a third locking screw 10-1 for locking the counterweight balance rod 7 is further arranged above the through cavity 10, the through cavity 10 is connected to the left side of the second shaft housing 9, the counterweight balance rod 7 is slidably arranged in the through cavity 10, after the position of the measured product is adjusted, the third locking screw 10-1 is loosened, the counterweight balance rod 7 is slid to a proper position so as to maintain the balance of the whole system, and finally, the optical device is used to start measuring the product until the measurement is completed.

In a preferred embodiment, since the X-axis rotation shaft 4, the Y-axis rotation shaft 5, and the Z-axis rotation shaft 6 are each of a movable structure, the X-axis rotation shaft 4, the Y-axis rotation shaft 5, and the Z-axis rotation shaft 6 can be rotated and stopped at any positions, and thus the above-described adjustment method can be fully realized.

In a preferred embodiment, the support mechanism 1 is a tripod with better stability, and three legs of the tripod are further provided with rotatable second adjusting switches 1-1 in consideration of different requirements of different optical devices, and the length of the tripod is adjusted by rotating the second adjusting switches 1-1 so as to meet the measurement requirements of different optical devices.

The beneficial effects of the utility model are as follows:

1. the data of the tested product can be synchronously and comprehensively collected;

2. the workload of the inspector is reduced; 3. and the data acquisition efficiency is improved.

Claims (5)

1. A gimbal support system for optical scanning comprising: the device comprises a supporting mechanism, a bracket center shaft, a rotating shaft system and a fixed quick clamp;

the supporting mechanism is connected with the middle shaft of the bracket;

a rotatable first regulating switch is arranged on the middle shaft of the bracket;

the first regulating switch is positioned above the connecting part of the supporting mechanism and the middle shaft of the bracket;

the rotating shaft system comprises a central shaft, a first shaft body shell, a second shaft body shell, a first locking screw, an X-axis rotating shaft, a Y-axis rotating shaft and a Z-axis rotating shaft;

the first shaft body shell and the second shaft body shell are sleeved on the central shaft;

the X-axis rotating shaft comprises a first X-axis rotating shaft and a first locking screw;

the first X-axis rotating shaft is rotatably connected to the central shaft and is positioned on the right side of the first shaft body shell;

the first locking screw is rotatably arranged at two sides of the first shaft body shell;

the Y-axis rotating shaft comprises a first Y-axis rotating shaft and a second locking screw;

the first Y-axis rotating shaft is positioned at two sides of the second shaft body shell;

the second locking screw is positioned above the second shaft body shell and used for clamping the first Y-axis rotating shaft;

the Z-axis rotating shaft comprises a first Z-axis rotating shaft and a second Z-axis rotating shaft;

the first Z-axis rotating shaft penetrates through the first shaft body outer shell to be connected with the fixed quick clamp, and the second Z-axis rotating shaft penetrates through the second shaft body outer shell to be connected with the bracket center shaft.

2. The system of claim 1, wherein the rotating shaft system further comprises a through cavity and a counterweight balance bar;

the through cavity is connected to the left side of the second shaft body shell;

the counterweight balance rod is slidably arranged in the through cavity.

3. The universal support bracket system for optical scanning of claim 2 wherein a third locking screw is further disposed above said through cavity.

4. The gimbal support system for optical scanning of claim 1, wherein the X-axis rotation axis, Y-axis rotation axis and Z-axis rotation axis are movable.

5. A gimbaled support system for optical scanning according to claim 1, wherein the support mechanism is further provided with rotatable second adjustment switches on three legs.