RU2249786C2 - Device for testing axis alignment - Google Patents

Abstract

FIELD: measuring engineering.

SUBSTANCE: device comprises corner mirror with two mirror surfaces which define the right angle between them, flat mirror, and adjusting units. The optical axis of one of the channels to be tested passes through the corner mirror. The optical axis of the second channel to be tested passes through the flat mirror. The device is additionally provided with several corner and flat mirrors. Each pair of the mirrors defines a prism and used for testing one channel of the article with one wavelength. The adjusting instrument is made of a built-in collimator provided with several light sources having different wavelengths.

EFFECT: enhanced accuracy of testing.

2 cl, 3 dwg

Description

A device for checking the parallelism of the axes relates to optical instrumentation, namely, devices for reconciling the parallelism of the optical axes of complex multichannel optoelectronic devices.

A device for controlling the parallelism of two axes according to the application of Germany (No. 3932078, G 01 B 11/27, prior September 26, 89, published 04/04/91), containing a corner mirror through which the optical axis of one controlled channel passes, consisting of two mirrors forming a right angle between themselves, and having the ability to swing in two mutually perpendicular planes, and a flat mirror through which the optical axis of the second controlled channel passes. Moreover, in the initial position, the corner mirror and the flat mirror are located so that their three main reflection planes are mutually perpendicular. This arrangement is called a system of three mirrors, and its advantage is the constancy of the angles of deviation of the rays in two mutually perpendicular planes. When swinging the corner mirror, they check the parallelism of the axes of the two channels of the tested product, controlling the position of the three main reflection planes of the mirrors with the help of adjustment and adjustment equipment made in the form of two auto-collimators, one of which is rigidly connected to a flat mirror. Autocollimators measure the angles of rotation of the corner mirror using additional mirrors that are rigidly connected to the corner mirror. Moreover, the planes of the additional mirrors are also mutually perpendicular, and, in addition, they are perpendicular to the axis of rotation of the corner mirror. This device allows you to control the parallelism of the axes of the product in laboratory conditions.

The disadvantage of the prototype is the bulkiness of the system, due to the use of two autocollimators, two additional mirrors and a rigid connection of one autocollimator with a flat mirror, which eliminates the possibility of integrated control. In addition, such a device allows you to control only two channels of the product.

The problem to be solved by the alleged invention is aimed at creating a compact system built into the device that provides regular product verification at any time of its operation, while maintaining high accuracy of checking the parallelism of the axes between each other and increasing the number of controlled channels.

The problem is achieved in that the device for checking the parallelism of the axes contains a corner mirror through which the optical axis of one controlled channel passes, a flat mirror through which the optical axis of another controlled channel passes, and control and adjustment equipment.

The present invention differs from the prototype in that the corner mirror and the flat mirror are rigidly interconnected and made in the form of a single prism so that their main reflection planes are mutually perpendicular and have a constant deflection angle when the reflected rays return in two mutually perpendicular planes, and the control -adjustment equipment is made in the form of a separate built-in collimator having several radiation sources operating alternately. Moreover, the number of prisms corresponds to the number of channels tested.

Prisms can be made of various materials, depending on the purpose of the channel, and have different sizes corresponding to the distances between the axes of the product channels.

Such a system of three mirrors, based on the rigid connection of a corner and a flat mirror, made in the form of a single prism, ensures the mutual perpendicularity of the three main planes of the mirrors in any position, and also ensures the mutual conformity of the device design to check the parallelism of the axes of the structure of the controlled product. The absence of a rigid connection between the mirrors and the control and adjustment equipment allows for integrated control and significantly reduce the dimensions of the device. In addition, it becomes possible to increase the number of such prisms and, accordingly, increase the number of monitored channels. The presence of several radiation sources operating alternately in the collimator integrated into the product allows controlling the axis of the channels for different wavelengths. The accuracy of control of such a device is maintained.

The essence of the alleged invention is presented in figures 1-3.

Figure 1 presents a view And a device for checking the parallelism of the axes.

Figure 2 shows a section bB of the device for checking the parallelism of the axes.

Figure 3 presents the operation of the device for checking the parallelism of the axes of the four channels of the tested product.

In the housing 1 (Fig. 1) four prisms 2, 3, 4 and 5 are placed, each of which provides verification of the parallelism of the axes of the two channels of the product. Each prism is made according to a system of three fixed mirrors, i.e. there are two mutually perpendicular mirror surfaces 6 forming the roof, and a third mirror 7, the main plane of which is perpendicular to the plane of the roof.

All four prisms differ from each other in size B (figure 2) and material.

For incoming and outgoing rays under each prism in the housing 1 there are through holes closed by protective glasses 8. The position of the holes and prisms 2, 3, 4, 5, respectively (Fig. 1) is determined by the placement of channels in the product and the placement of the housing 1 on the product (Fig. .3).

The internal cavity of the housing 1 with the installed prisms 2, 3, 4, 5 is closed by a cover 9 (figure 2). The housing 1 with its flange in diameter D is mounted on the housing 10 (Fig.3) of the tested product.

The principle of operation of the device is based on checking the parallelism of the axes of two product channels in series, one of which is the master, and the other is the receiving channel. Channels can have different wavelengths, but each pair, consisting of a master and a receiver channel, operates at the same wavelength.

For example, the product under test has four channels, three of them receiving ones: infrared channel 11, television channel 12 and direction finder 13, and one master: laser channel 14. In addition, there is an additional built-in collimator 15, which is also the master. The axis of the collimator 15 is a sensor for the receiving channels 11, 12 and 13, and the axis of the laser channel 14 is a sensor, for example, for the television channel 12.

The procedure for checking the parallelism of the axes of the four channels of the product is as follows.

The housing 1 with four prisms 2, 3, 4 and 5 (Fig. 1) is secured by its flange to the housing 10 (Fig. 3) of the product under test. The housing 10 with the four channels 11, 12, 13, 14 and collimator 15 located therein can rotate around the Y, Z axes. By turning the housing 10 relative to the Y, Z axes, the axis of any receiving channel and the axis of the sensor are combined with the input and output rays of the corresponding prism . For example, the axis of the infrared channel 11 and the axis of the collimator 15 are combined with the input and output rays of the prism 2.

The mismatch signals of the infrared channel 11 relative to the collimator 15 determine the deviation of the parallelism of the axes of these channels.

Similarly, by turning the body of the product relative to its Y, Z axes, the axis of the television channel 12 and the axis of the collimator 15 are combined with the input and output rays of the corresponding prism 3, the axis of the direction finder 13 and the axis of the collimator 15 with the input and output rays of the prism 4, the axis of the television channel 12 and the laser axis channel 14 with the input and output rays of the prism 5. The deviation from the parallelism of the axes is estimated from the mismatch signals of each receiving channel from the indicated pairs.

Thus, the use of a block of prisms having a constant angle of deviation of the input and output beam and not having a rigid connection with the control and adjustment equipment, in this case, the collimator 15, which is a mediator when measuring the angle of deviation from the parallelism of the axes, provides built-in control and verification of parallelism axes of several product channels.

Claims (3)

1. A device for checking the parallelism of the axes, containing a corner mirror with two mirror surfaces forming a right angle between them through which the optical axis of one controlled channel passes, a flat mirror through which the optical axis of the second controlled channel passes, made according to a system of three mirrors, which all three main reflection planes are mutually perpendicular, and control and adjustment equipment, characterized in that it contains several corner and flat mirrors, each pair of which It is made according to a system of three mirrors in the form of a prism and is designed to check one channel of the product with one radiation wavelength, and the control and adjustment equipment is made in the form of an integrated collimator having several radiation sources with different wavelengths working alternately with each channel so that Each measurement uses one radiation source. 2. A device for checking the parallelism of the axes according to claim 1, characterized in that the prisms have different sizes. 3. A device for checking the parallelism of the axes according to claims 1 and 2, characterized in that the prisms are made of various materials.

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