JPS62200630A - Optical fiber type photoelectric switch - Google Patents

Abstract

(57) [Abstract] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION Technical Field: This invention relates to improvements in photoelectric switches using optical fibers.

1 Conventional Device" Conventionally, as shown in FIG. Both heads 41a, 4], b are rotatably supported around the center.
The optical axes of the two are set to intersect at a predetermined angle in front of each. It is each detection head 41
This is because the optical fibers 25 and 26 held by the heads 41a and 41b have a predetermined aperture angle due to their nature.If the intersection angle between the two heads 41a and 41b is set large as shown in FIG. The light emitted from the light-emitting side detection head 41a directly enters the light-receiving side detection head 41b, causing malfunction. Therefore, both heads 41a and 41b
However, as shown in FIG. 6, a detection area is not formed in the area close to the detection head 41, and a rather wide detection area 37 is formed in the area far from the detection head 41. Therefore, there was a limit to improving detection accuracy.

"Purpose" In view of these conventional drawbacks, the present invention provides a photoelectronic device with high detection accuracy, in which a detection area is formed in a portion close to the detection head, and the light beam from the light emitting optical fiber does not directly enter the light receiving optical fiber. The purpose is to provide a switch.

"Summary" In order to achieve the object, the present invention has the ends of optical fibers for light emission and light reception facing each other on substantially the same straight line with a predetermined distance between them, and This shields the direct light emitted from the optical fiber to the receiving optical fiber.

"Example" An embodiment of the present invention will be described below with reference to the drawings.

That is, in FIGS. 2 and 3, the housing 1 has a pair of rectangular cases 3, which are divided into two from the center.
3. The side wall of the housing 1, that is, the first side wall 1a of the cases 3, 3, and the second side wall 1b adjacent to the first side wall have windows 4a of approximately the same size.
A window 4 consisting of 4b is provided. These windows are formed by rectangular notches in the periphery of each case 3. A fitting groove 5 is formed along the entire periphery of the windows 4a and 4b.The holder 7 is When the flange 8 formed in the window 4a is fitted into the fitting groove 8, the window 4a is closed.
The holder is provided with a pair of holes 9, 9 substantially parallel to each other along its axis. Also, on the inside of the holder, that is, on the Ujifugu 1 side, there is an element housing part 11.
．． 11 is provided, and a light projecting element 13 and a light receiving element 14 are respectively accommodated in this housing portion in correspondence with the respective holes 9, 9.

A guide wall 15 is provided protruding from the outside of the holder 7, and engagement protrusions 17a, 17a each having an inclined surface 16 are provided on a pair of opposing upper and lower walls, and notches 18 provided on both sides thereof. .18 gives a predetermined elasticity. The plug 21 is provided with a pair of holes 23, 23 along its axis, and is adapted to fit into the guide wall 15. Engagement recesses 17b, 17b that engage with the engagement protrusions 17a, 17a are provided on the upper and lower walls of this plug, and a set of engagement parts 17 is formed by these recesses and the engagement protrusions 17a, 17a. Ru. As shown in FIG. 5, a light-emitting optical fiber 25 and a light-receiving optical fiber 26 having a predetermined aperture angle of 0 are attached to the plug 21 by having one end thereof passed through the hole 23.23. Further, with this plug fitted into the holder 7, both optical fibers 25 and 26 pass through the hole 9.9 of the holder 7, and the light emitting optical fiber 25 and 26 pass through the hole 9.9 of the holder 7.
One end of the light receiving optical fiber 26 is optically connected to the light source, that is, the light projecting element 13, and one end of the light receiving optical fiber 26 is optically connected to the light receiving element 14. A large diameter portion 9 is provided at the end of the holes 9, 9 of the holder 7.
a, 9a are provided, and a rubber seal 27.27 for sealing between the holder 7 and the optical fiber 25.26 is provided at this large diameter portion. Further, the display unit plate 31 is molded from a translucent material, and its peripheral edge is fitted into the fitting groove 5 to be attached to the window 4b. A volume 33 for adjusting sensitivity and an indicator light 34, such as an LED, are arranged side by side on this display unit board. The printed circuit board 35 is housed within the housing 1 and is electrically connected to the light emitting element 13, the light receiving element 14, the volume 33, the indicator light 34, and the cable 36 drawn into the housing 1, respectively.

In addition, in FIG. 1 KN, the detection head 41 has a pair of recesses 42,
42, mounting convex portions 43 and 43 are formed at both ends thereof, and a shielding portion 45 is formed at the intermediate portion thereof. For mounting, a pair of mounting holes 46, 46a and 46b are formed in the convex portion 43.43 on the same straight line along the axis of the detection head 41, and one mounting hole 46a, 46b is formed opposite to each other. is inserted through the other end of the light emitting optical fiber 25,
In addition, for the other installation, the light receiving optical fiber 26 is installed in the hole 46b.
The other end is inserted through. Further, the height of the shielding part 45 from the recess 42 is set to a height that prevents the light emitted from the light emitting optical fiber 25 from directly entering the light receiving optical fiber 26, that is, a height that blocks direct light. . Therefore, the light emitted from the light projection optical fiber 25 is transmitted to the detection head 4.
A detection area 47 having a height A from the detection head 41 is formed between the light emitting optical fiber 25 and the light receiving optical fiber 26.

"Operation" Therefore, the light emitted from the light projecting element 13 passes through the light projecting optical fiber 25 and is emitted at the detection head 41. When a detected object 48 enters the detection area 47 in this state, the light from the light emitting optical fiber 25 is reflected by the detected object and enters the light receiving optical fiber 26. Furthermore, the light incident on this light-receiving optical fiber is guided to the light-receiving element 14, whereby a switching operation is performed.

Note that the detection distance, that is, the distance between the detection head and the detected object 48 and the amount of light incident on the light-receiving optical fiber 26 are determined by the fourth
As shown in the figure, as the detection distance increases, the amount of incident light gradually decreases, and when it crosses the boundary of the detection area, that is, point A, the amount of incident light decreases rapidly. The ends of the optical fibers are placed almost on the same line and face each other at a predetermined distance, and between the two optical fibers, the direct light emitted from the light emitting optical fiber to the light receiving optical fiber is blocked, and light other than this direct light is blocked. Since the light from the light emitting optical fiber is guided to the light receiving optical fiber by the object to be detected, even if the light emitting optical fiber and the light receiving optical fiber are faced to each other at the shortest distance, the light from the light emitting optical fiber will not directly enter the light receiving optical fiber. Therefore, it is possible to obtain a reflective photoelectric switch that can detect the object to be detected at a short distance and within a limited area, and has high accuracy.

[Brief explanation of drawings]

Figure 1 is a front view of the detection head of the photoelectric switch according to the present invention, Figure 2 is a front sectional view of the photoelectric switch body, Figure 3 is an exploded perspective view, and Figure 4 shows the relationship between detection distance and amount of incident light. FIG. 5 is a front view showing the aperture angle of the optical fiber, and FIGS. 6 and 7 are front views of the detection head of a conventional photoelectric switch. 1...Housing, 3...Case, 4...Window, 5
... Fitting groove, 7... Holder, 8... Flange, 9.
... hole, 11 ... element housing part, 13 ... light emitting element,
14... Light receiving element, 15... Guide wall, 16... Inclined surface, 17... Engaging portion, 17a... Engaging convex portion, 17
b... Engagement recess, 18... Notch, 21... Plug, 23... Hole, 25... Optical fiber for light projection,
26... Optical fiber for light reception, 27... Rubber seal, 31... Display unit board, 33... Volume,
34... Indicator light, 35... Printed circuit board, 36
... Cable, 41 ... Detection head, 42 ... Recess, 43 ... Mounting on convex part, 45 ... Shielding part, 46
... Mounting hole, 47... Detection area, 48... Object to be detected. Patent applicant: Yamatake Honeywell Co., Ltd.A

Claims (2)

[Claims] (1) The ends of the light emitting and light receiving optical fibers having a predetermined aperture angle are placed substantially on the same straight line and facing each other at a predetermined interval, and between the two optical fibers, from the light emitting optical fiber to the light receiving optical fiber, An optical fiber type photoelectric switch characterized in that direct light emitted to a light receiving optical fiber is shielded, and light other than the direct light is guided to the light receiving optical fiber by an object to be detected. (2) One end of the light emitting optical fiber with a predetermined aperture angle is connected to the light source, one end of the light receiving optical fiber with a predetermined aperture angle is connected to the light receiving element, and the other ends of both optical fibers are connected to the detection head. , are mounted facing each other on the same straight line with a predetermined interval, and further includes a shield on the detection head for blocking direct light emitted from the light emitting optical fiber and directly entering the light receiving optical fiber. A detection area is formed by the shield and the aperture angle of both optical fibers, and when an object to be detected enters the detection area, light from the light emitting optical fiber is transmitted to the light receiving optical fiber. A fiber optic photoelectric switch designed to guide the user.