CN216746701U - Testing equipment for optical machine - Google Patents

Abstract

The utility model discloses a testing device for an optical machine, which comprises: the mounting component is detachably connected to the optical machine; the mounting component is connected to the movable platform and is used for moving the mounting component on the movable platform along a moving plane; the rotating device is connected with the movable platform and is used for driving the movable platform to rotate so as to change an included angle between the moving plane and a horizontal plane; the power source is connected with the rotating device and is used for supplying power for the rotating device to rotate; and a controller electrically connected to the power source. The design of rotary device can make the operation of manual upset ray apparatus before become automatic upset, not only is favorable to reducing operating personnel's operation fatigue degree, promotes the upset precision and the efficiency of ray apparatus simultaneously, has effectively solved the inconvenient problem of test regulation when testing the ray apparatus.

Description

Testing equipment for optical machine

Technical Field

The utility model relates to a testing device for an optical machine.

Background

The ray apparatus has the wide application on projection equipment, the ray apparatus that is commonly used as shown in fig. 1, often need carry out the model detection in ray apparatus production process, when carrying out the model detection to the ray apparatus, need overturn respectively to the ray apparatus and make the face of waiting to detect of ray apparatus be formed with positive 45 degrees and negative 45 degrees with the horizontal plane, and initial position confirms operations such as resolution, and operations such as upset process often adopt artificial formula to go on, the manual focusing of operation personnel, manual upset ray apparatus, not only the flip angle is difficult to control, the operation has increased personnel's operation fatigue degree simultaneously lasts, the upset appears the picture phenomenon more easily inaccurate, need the situation of the operation more than the secondary, it is inconvenient to lead to the test adjustment to the ray apparatus like this.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem of providing test equipment for an optical machine in order to overcome the defect of inconvenient test and adjustment of the optical machine in the prior art.

The utility model solves the technical problems through the following technical scheme:

a test apparatus for a light engine, the test apparatus comprising: the mounting component is detachably connected to the optical machine; the mounting component is connected to the movable platform and is used for moving the mounting component on the movable platform along a moving plane; the rotating device is connected with the movable platform and is used for driving the movable platform to rotate so as to change an included angle between the moving plane and a horizontal plane; the power source is connected with the rotating device and is used for supplying power for the rotating device to rotate; and a controller electrically connected to the power source.

In this scheme, adopt above-mentioned structural style, can be so that the operation of manual upset ray apparatus in the past becomes automatic upset, not only be favorable to reducing operating personnel's operation fatigue degree, promote the upset precision and the efficiency of ray apparatus simultaneously, effectively solved the inconvenient problem of test regulation when testing the ray apparatus.

Preferably, the rotating device comprises a motor and a connecting piece, one end of the connecting piece is connected with the motor, the other end of the connecting piece is fixedly connected with the movable platform, and the motor drives the movable platform to rotate around the connecting piece.

Preferably, one side of the movable platform is the movable plane, the other side of the movable platform is a fixed plane, the connecting piece is arranged corresponding to the mounting part and connected with the fixed plane, and when the movable platform rotates around the connecting piece, two ends of the movable platform respectively move up and down relative to the horizontal plane.

In this scheme, adopt above-mentioned structural style, such design of rotary device is simple structure not only, and the debugging is convenient simultaneously, long service life.

Preferably, the test equipment further comprises a limiting device, the limiting device is respectively arranged on two sides of the connecting piece, and when the movable platform rotates to a preset angle, the limiting device abuts against the movable platform.

In this scheme, adopt above-mentioned structural style, be favorable to guaranteeing that the rotation angle of ray apparatus reaches the test requirement of ray apparatus.

Preferably, the mounting component includes a fixed jig and a displacement assembly, one end of the displacement assembly is fixedly connected to the movable platform, the other end of the displacement assembly is fixedly connected to the fixed jig, and the displacement assembly is adjusted to move the fixed jig on the movable platform.

Preferably, the displacement assembly includes a first displacement assembly and a second displacement assembly, the first displacement assembly drives the fixed jig to move on the movable platform along the axis direction of the motor, and the second displacement assembly drives the fixed jig to move on the movable platform along the axis direction perpendicular to the motor.

Preferably, the displacement assembly further comprises a pneumatic piece and a moving piece, one end of the moving piece is connected with the pneumatic piece, the other end of the moving piece is connected with the fixed jig, and the pneumatic assembly drives the fixed jig to displace through the moving piece.

In this scheme, adopt above-mentioned structural style, be favorable to realizing that the ray apparatus can carry out the regulation of two degrees of freedom in the mobile plane, such design of displacement subassembly not only makes the position control of ray apparatus rapid, is favorable to satisfying the test requirement of ray apparatus in the mobile plane simultaneously.

Preferably, the fixing jig further comprises a positioning column, a positioning hole is formed in the optical machine, and the positioning column is inserted into the positioning hole so that the optical machine is connected with the fixing jig.

In this scheme, adopt above-mentioned structural style, be favorable to improving the efficiency of being connected of ray apparatus and fixed tool, reduce operating personnel's operation fatigue degree simultaneously.

Preferably, the test equipment further includes a heat sink and a fan, the heat sink is connected to the fixing jig, and the fan dissipates heat from the optical machine.

In this scheme, adopt above-mentioned structural style, the form of radiator and fan is in time dispelled the heat to the ray apparatus, is favorable to forming the protection to the ray apparatus when the test.

Preferably, the testing apparatus further includes a camera and a control device, the control device is electrically connected to the camera and the rotating device respectively, the camera and the optical machine are disposed correspondingly, the control device controls the movable platform to rotate through the rotating device, and the control device controls the camera to test the optical machine.

In this scheme, adopt above-mentioned structural style, be favorable to realizing the automation to the ray apparatus test, improve the operation precision, be favorable to reducing operating personnel's intensity of labour simultaneously.

On the basis of the common knowledge in the field, the above preferred conditions can be combined randomly to obtain the preferred embodiments of the utility model.

The positive progress effects of the utility model are as follows:

this a check out test set for ray apparatus is equipped with rotary device, and rotary device's design can be so that the operation of manual upset ray apparatus before becomes automatic upset, not only is favorable to reducing operating personnel's operation fatigue degree, promotes the upset precision and the efficiency of ray apparatus simultaneously, has effectively solved the inconvenient problem of test regulation when testing the ray apparatus.

Drawings

Fig. 1 is a schematic structural diagram of an optical machine according to an embodiment of the present invention.

Fig. 2 is a schematic structural diagram of a detection apparatus for an optical machine according to an embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a rotating device according to an embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a mounting part and a movable platform according to an embodiment of the present invention.

Description of reference numerals:

mounting component 1

Fixing jig 11

First displacement assembly 12

Second displacement assembly 13

Pneumatic part 14

Moving part 15

Movable platform 2

Rotating device 3

Motor 31

Connecting piece 32

Plane of movement 33

Fixed plane 34

Limiting device 4

Heat sink 5

Fan 6

Optical machine 7

Detailed Description

The present invention will be more clearly and completely described below by way of examples and with reference to the accompanying drawings, but the present invention is not limited thereto.

An embodiment of the present invention provides a testing apparatus for an optical machine, as shown in fig. 1 to 4, the testing apparatus includes: the mounting component 1, the mounting component 1 is detachably connected to the optical machine 7; a movable platform 2, the mounting part 1 is connected to the movable platform 2, and is used for enabling the mounting part 1 to move on the movable platform 2 along a moving plane 33; the rotating device 3 is connected with the movable platform 2, and the rotating device 3 is used for driving the movable platform 2 to rotate so as to change an included angle between the moving plane 33 and a horizontal plane; a power source connected to the rotating device 3 for providing power for the rotating device 3 to rotate; and a controller electrically connected to the power source.

By adopting the structure form, the testing equipment for the optical machine 7 is provided with the movable platform 2, the upper surface of the movable platform 2 is the movable plane 33, the installation part 1 is arranged on the movable plane 33, the optical machine 7 is installed on the installation part 1, meanwhile, the installation part 1 can carry out position adjustment in the movable plane, the testing equipment also comprises the rotating device 3, the rotating device 3 comprises the motor 31 and the connecting piece 32, the side wall of the connecting piece 32 is fixedly connected with the other side of the movable platform 2, the end part of the connecting piece 32 is connected with the motor 31, the positive 45-degree and negative 45-degree angles can be formed between the surface to be detected of the optical machine 7 on the movable platform 2 and the horizontal plane by driving the connecting piece 32 through the motor 31, the design can change the operation of the prior manual overturning of the optical machine 7 into automatic overturning, thereby not only being beneficial to reducing the operation fatigue of operators, but also improving the overturning precision and efficiency of the optical machine 7, the problem of inconvenient test regulation when testing light machine 7 has effectively been solved.

As a preferred embodiment, as shown in fig. 1-4, the rotating device 3 includes a motor 31 and a connecting member 32, one end of the connecting member 32 is connected to the motor 31, the other end of the connecting member 32 is fixedly connected to the movable platform 2, and the motor 31 drives the movable platform 2 to rotate around the connecting member 32. One side of the movable platform 2 is a movable plane 33, the other side of the movable platform 2 is a fixed plane 34, the connecting piece 32 is arranged corresponding to the mounting part 1 and is connected with the fixed plane 34, and when the movable platform 2 rotates around the connecting piece 32, two ends of the movable platform 2 respectively move up and down relative to a horizontal plane.

Adopt above-mentioned structural style, movable platform 2 is the sheet metal, movable platform 2 one side up is the activity plane, movable platform 2's opposite side is fixed plane 34, rotary device 3 includes motor 31 and connecting piece 32, the axis of connecting piece 32 is parallel with movable platform 2, and with movable platform 2's fixed plane 34 fixed connection, the one end of connecting piece 32 is connected with motor 31, the rotatory accessible connecting piece 32 of motor 31 drives movable platform 2 and carries out rotary motion around the axis of connecting piece 32, because connecting piece 32 connects in fixed plane 34's intermediate position, so movable platform 2 its both ends can carry out up-and-down motion relative to the horizontal plane respectively when rotatory. The design of the rotating device 3 is simple in structure, convenient to debug and long in service life.

As a preferred embodiment, as shown in fig. 1-4, the testing apparatus further includes a limiting device 4, the limiting device 4 is respectively disposed at two sides of the connecting member 32, and when the movable platform 2 rotates to a predetermined angle, the limiting device 4 abuts against the movable platform 2.

Adopt above-mentioned structural style, both sides and the movable platform 2 both ends at connecting piece 32 correspond respectively and are equipped with stop device 4, when movable platform 2 was rotatory under motor 31's drive, movable platform 2's both ends can carry out the up-and-down motion relative to the horizontal plane respectively, when the face of waiting of glazing machine 7 on movable platform 2 was formed with positive 45 degrees and negative 45 degrees with the horizontal plane, stop device 4 that corresponds one side can be leaned on with movable platform 2's one end counterbalance to guarantee that the rotation angle of glazing machine 7 reaches the test requirement of glazing machine 7.

As a preferred embodiment, as shown in fig. 1-4, the mounting component 1 includes a fixed jig 11 and a displacement assembly, one end of the displacement assembly is fixedly connected to the movable platform 2, and the other end of the displacement assembly is fixedly connected to the fixed jig 11, and the displacement assembly is adjusted to move the fixed jig 11 on the movable platform 2. The displacement assembly comprises a first displacement assembly 12 and a second displacement assembly 13, the first displacement assembly 12 drives the fixed jig 11 to move on the movable platform 2 along the axis direction of the motor 31, and the second displacement assembly 13 drives the fixed jig 11 to move on the movable platform 2 along the axis direction perpendicular to the motor 31. The displacement assembly further comprises a pneumatic piece 14 and a moving piece 15, one end of the moving piece 15 is connected with the pneumatic piece 14, the other end of the moving piece 15 is connected with the fixed jig 11, and the pneumatic assembly drives the fixed jig 11 to displace through the moving piece 15.

By adopting the structure form, the mounting part 1 comprises the fixed jig 11 and the displacement assembly, the optical machine 7 is mounted on the fixed jig 11, the displacement assembly comprises the pneumatic part 14 and the moving part 15, one end of the moving part 15 is connected with the fixed jig 11, the other end of the moving part 15 is connected with the pneumatic part 14, and the pneumatic part 14 can enable the fixed jig 11 to move in the moving plane 33 through the moving part 15, so that the optical machine 7 is adjusted to a proper test position in the moving plane 33. The displacement assembly comprises a first displacement assembly 12 and a second displacement assembly 13, the first displacement assembly 12 drives the fixed jig 11 to move on the movable platform 2 along the axis direction of the motor 31, the second displacement assembly 13 drives the fixed jig 11 to move on the movable platform 2 along the axis direction perpendicular to the motor 31, so that the optical machine 7 can be adjusted in two degrees of freedom in the movable plane 33, the optical machine 7 is rapidly adjusted by the aid of the displacement assembly, and meanwhile, testing requirements of the optical machine 7 in the movable plane 33 are favorably met.

As a preferred embodiment, as shown in fig. 1-4, the fixing fixture 11 further includes a positioning column, a positioning hole is formed on the optical machine 7, and the positioning column is inserted into the positioning hole, so that the optical machine 7 is connected to the fixing fixture 11.

By adopting the structure, the positioning hole is formed in the optical machine 7, the positioning column is arranged on the fixing jig 11 opposite to the positioning hole, when an operator places the optical machine 7 on the fixing jig 11, the positioning column is inserted into the corresponding positioning hole in the optical machine 7, so that the optical machine 7 is connected with the fixing jig 11, the design is favorable for improving the connection efficiency of the optical machine 7 and the fixing jig 11, and meanwhile, the operation fatigue of the operator is reduced.

As a preferred embodiment, as shown in fig. 1 to 4, the testing apparatus further includes a heat sink 5 and a fan 6, the heat sink 5 is connected to the fixing fixture 11, and the fan 6 dissipates heat of the optical machine 7.

Adopt above-mentioned structural style, still be connected with radiator 5 on fixed tool 11's the surface, still be equipped with fan 6 on the activity plane, after ray apparatus 7 is connected with fixed tool 11, tester can be switched on to ray apparatus 7, for avoiding ray apparatus 7 to damage in ray apparatus 7 test procedure, adopts radiator 5 and fan 6's form to in time dispel the heat to ray apparatus 7, is favorable to forming the protection to ray apparatus 7 when testing.

As a preferred embodiment, as shown in fig. 1 to 4, the testing apparatus further includes a camera and a control device, the control device is electrically connected to the camera and the rotating device 3, the camera is disposed corresponding to the optical engine 7, the control device controls the movable platform 2 to rotate through the rotating device 3, and the control device controls the camera to test the optical engine 7.

Adopt above-mentioned structural style, it is equipped with the camera to correspond in movable platform 2's top, the camera is connected with controlling means electricity, controlling means is connected with rotary device 3 electricity, operating personnel starts this controlling means when the test begins, and controlling means will carry out automatic focusing and angle upset to ray apparatus 7 according to setting for to and carry out automatic test after reseing, be favorable to realizing like this to the automation of ray apparatus 7 test, improve the operation precision, be favorable to reducing operating personnel's intensity of labour simultaneously.

While specific embodiments of the utility model have been described above, it will be appreciated by those skilled in the art that this is by way of example only, and that the scope of the utility model is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the spirit and scope of the utility model, and these changes and modifications are within the scope of the utility model.

Claims (10)

1. A test device for a light engine, the test device comprising:

the mounting component is detachably connected to the optical machine;

the mounting component is connected to the movable platform and is used for moving the mounting component on the movable platform along a moving plane;

the rotating device is connected with the movable platform and is used for driving the movable platform to rotate so as to change an included angle between the moving plane and a horizontal plane;

the power source is connected with the rotating device and is used for supplying power for the rotating device to rotate; and

and the controller is electrically connected to the power source.

2. The testing apparatus for an optical machine according to claim 1, wherein the rotating device comprises a motor and a connecting member, one end of the connecting member is connected to the motor, the other end of the connecting member is fixedly connected to the movable platform, and the motor drives the movable platform to rotate around the connecting member.

3. The testing apparatus for optical-mechanical apparatus according to claim 2, wherein one side of the movable platform is the movable plane, the other side of the movable platform is a fixed plane, the connecting member is disposed corresponding to the mounting member and connected to the fixed plane, and when the movable platform rotates around the connecting member, two ends of the movable platform respectively move up and down relative to the horizontal plane.

4. The testing apparatus for an optical machine according to claim 2, further comprising a limiting device, wherein the limiting device is respectively disposed at two sides of the connecting member, and when the movable platform rotates to a predetermined angle, the limiting device abuts against the movable platform.

5. The testing apparatus for optical-mechanical device according to claim 2, wherein the mounting member comprises a fixed fixture and a displacement assembly, one end of the displacement assembly is fixedly connected to the movable platform, the other end of the displacement assembly is fixedly connected to the fixed fixture, and the displacement assembly is adjusted to move the fixed fixture on the movable platform.

6. The testing apparatus for optical-mechanical device according to claim 5, wherein the displacement assembly comprises a first displacement assembly and a second displacement assembly, the first displacement assembly drives the fixed fixture to move on the movable platform along the axis of the motor, and the second displacement assembly drives the fixed fixture to move on the movable platform along the axis perpendicular to the motor.

7. The testing apparatus for an optical bench according to claim 5, wherein the displacement assembly further comprises a pneumatic member and a moving member, one end of the moving member is connected to the pneumatic member, the other end of the moving member is connected to the fixed jig, and the pneumatic member drives the fixed jig to displace through the moving member.

8. The testing apparatus for an optical-mechanical device according to claim 5, wherein the fixing fixture further comprises a positioning post, the optical-mechanical device is provided with a positioning hole, and the positioning post is inserted into the positioning hole to connect the optical-mechanical device and the fixing fixture.

9. The testing apparatus for the optical machine according to claim 5, further comprising a heat sink and a fan, wherein the heat sink is connected to the fixing jig, and the fan dissipates heat of the optical machine.

10. The testing apparatus for a bare engine according to claim 1, further comprising a camera and a control device, wherein the control device is electrically connected to the camera and the rotating device, respectively, the camera is disposed corresponding to the bare engine, the control device controls the movable platform to rotate through the rotating device, and the control device controls the camera to test the bare engine.

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