SU1697034A1 - Multichannel optic rotating device - Google Patents

Abstract

The invention relates to a fiber-optic communication technique, can be used to transmit optical information from rotating to fixed nodes and improves reliability by ensuring the identical conditions of radiation transmission in the channels and vibration resistance. Radiation from the radiator 6, reflected from a conical mirror 2, made at one end of the transparent cylinder 1, hits a spherical or vapor-bolic mirror 4, made at the other end of cylinder 1, and then gets into the photodetector 5 installed in the focus of the mirror 4. 3s account sequential set of cylinders 1 it is possible to increase the number of information kagalov 1 or

Description

The invention relates to optical communication technology and can be used to transmit optical information from rotating nodes to stationary.

The purpose of the invention is improving reliability ^: 5 posta device by ensuring the identity of the conditions for the transmission of radiation in the channels and vibration resistance.

The drawing schematically shows the design of a multi-channel optical 10 rotating device on three channels.

The device consists of separate transparent cylinders 1. combined into a single unit. The number of these identical cylinders corresponds to the number of optical 15 channels. The left end of each cylinder 1 is made in the form of a truncated cone, the generatrix 2 of which is reflective, and the plane of the smaller base 3 is transparent to radiation. The right end of each 20 cylinder 1 is made in the form of a spherical or parabolic mirror 4. In this case, the axis of the truncated cone 2 and the main optical axis of the mirror 4 coincide with the axis of rotation of the cylinders 1 and the entire device as a whole, 25 and the plane of the smaller base of the cone 3 is located in the focus of the mirror 4. The receiver 5 is installed on the plane of the smaller base of the cone 3 on the axis of rotation of the device.

The emitter 6 is placed opposite the reflecting surface of the cone 2 outside the block. The operation mode of each channel, as follows from the drawing, is similar to the others,

As transparent cylinders 1, silica glass cylinders with appropriate end processing can be used. Reflecting surfaces 2 and 4 can be made by metallization of these surfaces, for example by spraying a 40 ’metal or alloy with a high reflection coefficient. If the mirror 4 is spherical, then the longitudinal dimensions of the elements 1 are determined by the radius of curvature of the mirror. In this case, the distance from the plane 45 3 to the center of the spherical mirror will be equal to the focal length of the spherical mirror, i.e. R / 2. The angle of inclination of surfaces 2 should be 4E +. As receiver 5, for example, a photodiode or an end of a fiber waveguide can be used, followed by connection with a photodetector. The emitter 6 may be the end of a fiber waveguide to create a parallel beam of light or a laser (light emitting diode) with focusing optics at the end, etc.

The device operates as follows.

When the cylinder block 1 rotates around the axis, the beam of rays from the emitter'6 is reflected from the surface 2 and is focused by the mirror 4 to the point of intersection of the axis of rotation and the end surface 3 on which the receiver 5 is mounted. Further, the information is output to the corresponding devices.

The paths of the rays of each channel are identical. The number of channels of the proposed device is not limited, as it is provided by a simple increase in the number of elements 1. in the block.

Claims (1)

Claim A multichannel optical rotating device, each channel of which contains an emitter mounted for rotation, a parabolic or spherical mirror with a photodetector installed in its focus, which is related to the fact that, in order to increase reliability by ensuring identity conditions of radiation transmission in the channels and vibration resistance, a transparent cylinder is introduced into each channel of the device, at one end of which a recess is made in the form of a truncated cone with an angle at the apex 90 ', coaxial with the transparent cylinder the core, and a parabolic or spherical mirror is made on the other end of the transparent cylinder, while the generatrix of the truncated cone is made mirrored, and on the small base of the truncated cone there is a photodetector optically coupled to an emitter mounted opposite the conical mirror, and transparent cylinders of various channels are mounted respectively on the longitudinal device axis.