CN218121788U - VR vision eyeball simulation angle testing device - Google Patents

Abstract

The utility model discloses a VR vision eyeball simulation angle testing device, which comprises a seat body, a base and a base, wherein the top and the bottom are arranged oppositely; the first driving assembly is connected to the top and comprises a first driving piece; the mounting seat is connected with the first driving component and can rotate relative to the seat body under the driving of the first driving component; the observation assembly is connected to the mounting seat and is suitable for observing a target object placed on the bottom; the second driving assembly is connected with the observation assembly and comprises a second driving piece; the observation assembly can slide on the sliding rail assembly under the driving of the second driving assembly; the axis of the output shaft of the first driving part is vertical to the axis of the output shaft of the second driving part; the whole arc that is of slide rail set spare to make the observation subassembly carry out omnidirectional detection to the target object under the drive of first drive assembly and second drive assembly, the testing result is accurate, uses manpower sparingly, effectively avoids the defective products to flow into next process.

Description

VR vision eyeball simulation angle testing device

Technical Field

The application belongs to the technical field of visual inspection equipment, and particularly relates to a VR vision eyeball simulation angle testing device.

Background

Modern society in the production process of VR glasses, because of the requirement to the quality and the responsible for glasses safe in utilization, need carry out the quality detection to the VR glasses of production, qualified VR glasses just can leave the factory and pack after detecting, normally get into the market and sell.

In the prior art, the target object is usually observed and detected by a manual mode, but the manual detection has low precision and deviation, and the situations of missing detection and defect omission inevitably occur, so that the unqualified target object flows into the next procedure, the material is wasted, and the defective products are probably delivered out of the factory, which affects the product credit of a production enterprise,

accordingly, there is a need for improvements in the art that overcome the deficiencies in the prior art.

SUMMERY OF THE UTILITY MODEL

Therefore, the utility model aims to solve the technical problem that a VR vision eyeball emulation angle testing arrangement that work efficiency is high, the testing result is accurate is provided.

In order to solve the technical problem, the utility model provides a VR vision eyeball emulation angle testing arrangement is applicable to among the high-speed motor, include:

the base body is provided with a top part and a bottom part which are oppositely arranged;

a first drive assembly connected to the top portion and including a first drive member;

the mounting seat is connected with the first driving assembly and can rotate relative to the seat body under the driving of the first driving assembly;

the observation assembly is connected to the mounting seat and is suitable for observing the target placed on the bottom;

the second driving assembly is connected with the observation assembly and comprises a second driving piece;

the sliding rail assembly is connected with the observation assembly and the mounting seat, and the observation assembly can slide on the sliding rail assembly under the driving of the second driving assembly;

the axis of the output shaft of the first driving part is perpendicular to the axis of the output shaft of the second driving part; the whole slide rail assembly is arc-shaped.

Furthermore, the mounting seat comprises a first mounting part connected with the output shaft of the first driving part and a second mounting part connected with the first mounting part;

the second driving piece is installed on the second installation part, and the plane where the first installation part is located is perpendicular to the plane where the second installation part is located.

Further, an accommodating space is formed between the first installation part and the second installation part, and the sliding rail assembly is installed in the accommodating space.

Furthermore, the mounting seat further comprises at least two supporting pieces arranged in the accommodating space, and the two supporting pieces are arranged at the joint of the first mounting part and the second mounting part.

Further, the slide rail assembly comprises a slide rail part connected with the mounting part and a sliding part arranged on the slide rail part, and the observation assembly is arranged on the sliding part.

Further, the sliding part is provided with a sliding groove corresponding to the sliding rail part, and the sliding part is connected with the output shaft of the second driving part and can slide along the sliding rail part under the driving of the second driving part.

Further, the second driving assembly further comprises a connecting rod piece, and the connecting rod piece comprises a first connecting rod and a second connecting rod, wherein one end of the first connecting rod is connected with the output shaft of the second driving piece, and the second connecting rod is connected with the other end of the first connecting rod and the sliding piece;

the extension directions of the lengths of the first connecting rod and the second connecting rod are vertically arranged.

Further, the observation assembly comprises an observation piece, and the observation piece is a camera.

Further, the observation piece is provided with a first position facing the target object and a second position offset relative to the target object, and the observation piece slides on the sliding rail piece to switch between the first position and the second position.

Further, a connecting line of the observation piece between the second position and the target object and a connecting line of the observation piece between the first position and the target object form an observation angle for the target object;

the observation angle ranges from 0 ° to 70 °.

The technical scheme provided by the utility model, following advantage has: the utility model discloses a VR vision eyeball emulation angle testing arrangement is through being provided with the pedestal that has the top and the bottom of relative setting, connect the first drive assembly on the top, the mount pad of being connected with first drive assembly, connect the observation subassembly on the mount pad, the second drive assembly of being connected with the observation subassembly, and connect the slide rail set spare of observing subassembly and mount pad, wherein, first observation subassembly includes first driving piece, the mount pad can rotate the second drive assembly including the second driving piece relative pedestal under the drive of first drive assembly, the observation subassembly can slide on slide rail set spare under the drive of second drive assembly, and the axis of the output shaft of first driving piece sets up with the axis of the output shaft of second driving piece is perpendicular, slide rail set spare wholly is arc, thereby make the observation subassembly can carry out omnidirectional detection to the target object under the drive of first drive assembly and second drive assembly, the testing result is accurate, save the manpower, effectively avoid defective products to flow into down one process.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be 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 some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural view of the VR vision eyeball simulation angle testing device of the present invention;

fig. 2 is another schematic view structure diagram of the VR visual eyeball simulation angle testing apparatus shown in fig. 1.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are some, but not all embodiments of the present invention. The present invention will be described in detail below with reference to the accompanying drawings in conjunction with embodiments. It should be noted that, in the present invention, the embodiments and features of the embodiments may be combined with each other without conflict.

It should be noted that the terms "first," "second," and the like in the description and claims of the present invention and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order.

In the present application, where the contrary is not intended, the use of directional words such as "upper, lower, top and bottom" is generally with respect to the orientation shown in the drawings, or with respect to the component itself in the vertical, perpendicular or gravitational direction; likewise, for ease of understanding and description, "inner and outer" refer to the inner and outer relative to the profile of the components themselves, but the above directional words are not intended to limit the invention.

Referring to fig. 1 to 2, the present embodiment provides a VR visual eyeball simulation angle testing apparatus, which is adapted to perform observation and detection on a target 7 to ensure that the quality of the target 7 is good and avoid material waste caused by defective products flowing into a next process.

VR vision eyeball emulation angle testing arrangement includes pedestal 1 and connects first drive assembly 2 on pedestal 1, mount pad 3 of being connected with first drive assembly 2, the observation subassembly 4 of setting on mount pad 3, and with second drive assembly 5 of observing subassembly 4 and the slide rail set 6 of connecting observation subassembly 4 and mount pad 3, observation subassembly 4 can slide on slide rail set 6 under the drive of second drive assembly 5, thereby observe the detection to placing target 7 on pedestal 1, and then judge whether target 7 is qualified.

Specifically, along the height direction of the seat body 1, the seat body 1 has a top 11 and a bottom 12 which are arranged oppositely, the first driving component 2 is connected to the top 11 and comprises a first driving part 21, the mounting seat 3 can rotate relative to the seat body 1 under the driving of the first driving component 2, the target 7 is placed on the bottom 12 of the seat body 1, the second driving component 5 comprises a second driving part 51, wherein the axis of the output shaft of the first driving part 21 is perpendicular to the axis of the output shaft of the second driving part 51, and the whole sliding rail component 6 is arc-shaped, so that the observation component 4 can move around the target 7 under the driving of the first driving part 21 and the second driving part 51 in all directions, the target 7 can be observed in all directions without dead angles, the detection result is accurate, the manpower is saved, and the defective products are effectively prevented from flowing into the next process.

The mounting seat 3 comprises a first mounting part 31 connected with the output shaft of the first driving part 21 and a second mounting part 32 connected with the first mounting part 31, the second driving part 51 is mounted on the second mounting part 32, and the plane of the first mounting part 31 is perpendicular to the plane of the second mounting part 32, so that the axes of the output shafts of the first driving part 21 and the second driving part 51 can be arranged perpendicular to each other.

Be formed with the accommodation space between first installation department 31 and second installation department 32, in the 3 accommodation spaces of slide rail assembly 6 mount pad, mount pad 3 is still including setting up support piece 33 in the accommodation space, and support piece 33 is provided with at least two, and two support piece 33 settings are at the junction of first installation department 31 and second installation department 32 to provide the support to the junction of first installation department 31 and second installation department 32, guarantee the stability and the joint strength of mount pad 3.

The slide rail assembly 6 comprises a slide rail piece 61 connected with the mounting part and a sliding piece 62 arranged on the slide rail piece 61, the observation assembly 4 is arranged on the sliding piece 62, specifically, the sliding piece 62 is provided with a sliding groove corresponding to the slide rail piece 61, the sliding piece 62 is connected with an output shaft of the second driving piece 51, and can slide along the slide rail piece 61 under the driving of the second driving piece 51, so that the target object 7 can be observed and detected diagonally.

The second driving assembly 5 further includes a link member 52, the link member 52 includes a first link 521 having one end connected to the output shaft of the second driving member 51, and a second link 522 connecting the other end of the first link 521 and the sliding member 62, and the extending directions of the lengths of the first link 521 and the second link 522 are perpendicular to each other, so that when the output shaft of the second driving member 51 rotates, the observing member 4 can be driven by the link member 52 to slide on the sliding member 62.

The observation assembly 4 includes an observation member 41, the observation member 41 has a first position (shown in fig. 1) for observing the target 7 and a second position (shown in fig. 2) offset from the target 7, the observation member 41 slides on the slide rail member 61 under the driving of the second driving member 51, and can be switched between the first position and the second position, and a connecting line between the second position and the target 7 and a connecting line between the first position and the target 7 of the observation member 41 form an observation angle with respect to the target 7, in this embodiment, the observation angle is in a range from 0 ° to 70 °, in other embodiments, the observation angle can be other, such as greater than 70 °, and the like, and the observation angle can be determined according to actual requirements, and is not specifically limited herein.

To sum up, the process of detecting the target object 7 by the VR visual eyeball simulation angle testing device is as follows: place object 7 on the bottom 12 of pedestal 1, later rotate around object 7 through first drive assembly 2 drive mount pad 3 to slide on slide rail set 6 through second drive assembly 5 drive observation subassembly 4 simultaneously, make observation subassembly 4 carry out omni-directional movement in certain extent relative object 7, thereby carry out the omnidirectional observation to object 7 and detect, detect whether there is the defect in object 7.

In summary, the following steps: the utility model discloses a VR vision eyeball emulation angle testing arrangement is through being provided with the top that has relative setting and the pedestal of bottom, connect the first drive assembly on the top, the mount pad of being connected with first drive assembly, connect the observation subassembly on the mount pad, the second drive assembly of being connected with the observation subassembly, and connect the slide rail set spare of observing subassembly and mount pad, wherein, first observation subassembly includes first driving piece, the mount pad can rotate the second drive assembly including the second driving piece relative to the pedestal under the drive of first drive assembly, the observation subassembly can slide on slide rail set spare under the drive of second drive assembly, and the axis of the output shaft of first driving piece sets up with the axis of the output shaft of second driving piece is perpendicular, slide rail set spare is whole to be arc, thereby make the observation subassembly can carry out omnidirectional detection to the target object under the drive of first drive assembly and second drive assembly, the testing result is accurate, and save the manpower, effectively avoid defective products to flow into down one process.

It is to be understood that the above-described embodiments are only some of the embodiments of the present invention, and not all of the embodiments. Based on the embodiment of the utility model, ordinary technical personnel in this field can make other different forms of change or change under the prerequisite of not making creative work, all should belong to the scope of protection of the utility model.

Claims (10)

1. The utility model provides a VR vision eyeball emulation angle testing arrangement which characterized in that includes:

the base body is provided with a top part and a bottom part which are oppositely arranged;

a first drive assembly connected to the top portion and including a first drive member;

the mounting seat is connected with the first driving assembly and can rotate relative to the seat body under the driving of the first driving assembly;

the observation assembly is connected to the mounting seat and is suitable for observing the target object placed on the bottom;

the second driving assembly is connected with the observation assembly and comprises a second driving piece;

the sliding rail assembly is connected with the observation assembly and the mounting seat, and the observation assembly can slide on the sliding rail assembly under the driving of the second driving assembly;

the axis of the output shaft of the first driving part is perpendicular to the axis of the output shaft of the second driving part; the whole slide rail assembly is arc-shaped.

2. The VR vision eyeball simulation angle testing device of claim 1, wherein the mounting base includes a first mounting portion coupled to the output shaft of the first driving member, and a second mounting portion coupled to the first mounting portion;

the second driving piece is installed on the second installation part, and the plane at the first installation part is perpendicular to the plane at the second installation part.

3. The VR vision eyeball simulation angle testing device of claim 2, wherein a receiving space is formed between the first mounting portion and the second mounting portion, and the slide rail assembly is mounted in the receiving space.

4. The VR vision eyeball simulation angle testing device of claim 3, wherein the mounting seat further comprises at least two support members disposed in the accommodating space, and the two support members are disposed at a connection position of the first mounting portion and the second mounting portion.

5. The VR vision eyeball simulation angle testing device of claim 3, wherein the sliding rail assembly comprises a sliding rail member connected with the mounting portion, and a sliding member disposed on the sliding rail member, and the observation assembly is disposed on the sliding member.

6. The VR vision eyeball simulation angle testing device of claim 5, wherein the sliding member has a sliding slot corresponding to the sliding rail member, and the sliding member is connected to the output shaft of the second driving member and can slide along the sliding rail member under the driving of the second driving member.

7. The VR visual eyeball simulation angle testing apparatus of claim 6, wherein the second driving assembly further includes a link member, the link member including a first link having one end connected to the output shaft of the second driving member, and a second link connecting the other end of the first link and the sliding member;

the extension directions of the lengths of the first connecting rod and the second connecting rod are vertically arranged.

8. The VR visual eyeball simulation angle testing apparatus of claim 7, wherein the observation assembly includes an observation, and the observation is a camera.

9. The VR vision eyeball simulation angle testing apparatus of claim 8, wherein the sight has a first position facing the target object and a second position offset from the target object, and the sight slides on the sliding rail member to switch between the first position and the second position.

10. The VR vision eyeball simulation angle testing device of claim 9, wherein a line between the second position of the scope and the target object forms an angle of view of the target object with a line between the first position of the scope and the target object;

the observation angle ranges from 0 ° to 70 °.

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