JP4394515B2 - Scale manufacturing method - Google Patents

Description

The present invention also relates to scale production how.

Conventionally, as shown in FIG. 2, an optical displacement measuring apparatus 100 that includes a scale 200 and a detection head 300 and detects relative displacement between the scale 200 and the detection head 300 is known.
The scale 200 also has a back surface 230 with respect to the front surface 220 on which the optical pattern 210 is provided. If the reflected light from the back surface 230 affects the reflected light from the front surface 220, the scale 200 cannot be detected. This leads to detection error.
Therefore, a light-absorbing paint (for example, black) is applied to the back surface 230 of the scale 200, or a film 231 that hardly reflects light, such as chromium oxide, is formed.
Or, when attaching an optical displacement measuring device to a device that actually wants to detect the amount of relative displacement (for example, a slide mechanism in which a slider slides along a guide), processing to avoid reflection on the scale mounting surface (application of paint or light absorption) Film formation etc.).

  However, in order to prevent reflection from the back surface 230 of the scale 200, processing such as applying paint to the back surface 230 of the scale 200 or the scale mounting surface 400 is time-consuming and costly. Problems such as affecting mounting accuracy occur.

An object of the present invention is simple and inexpensive to manufacture, reliable detection of providing Luz scale manufacturing process to improve.

  The scale manufacturing method of the present invention is a method for manufacturing a scale that is provided so as to be relatively movable with respect to a detection head having a light source and a light receiving means, and has an optical pattern on one side that reflects light from the light source toward the light receiving means. The method further comprises a polishing step of polishing one surface on which the optical pattern is provided on a glass substrate having irregularities on both front and back surfaces, and the back surface of the one surface is not processed.

According to such a configuration, since the back surface of the scale is a rough surface, the light incident from the front surface and reflected by the back surface is scattered and does not enter the light receiving means. As a result, since the reflection from the back surface does not affect the detection by the light receiving means, the detection accuracy by the light receiving means can be improved. And when attaching the said scale to a slider apparatus etc., since no process is required for the back surface of a scale or a scale attachment surface, scale attachment accuracy can be improved.
Further , since the back surface is not processed, the processing steps can be simplified and the scale can be manufactured at low cost. And since a manufacturing process is simplified, manufacturing efficiency can be improved.

  The scale manufacturing method of the present invention is a method for manufacturing a scale that is provided so as to be relatively movable with respect to a detection head having a light source and a light receiving means, and has an optical pattern on one side that reflects light from the light source toward the light receiving means. A polishing step of polishing one surface on which the optical pattern is provided on a glass substrate having irregularities on both front and back surfaces, and a step of cutting into a scattering surface that scatters light on the back surface of the one surface. It is characterized by that.

  According to such a configuration, the back surface of the scale can be made an optical rough surface by grinding the back surface by grinding or sandblasting. Cutting the back surface is simpler than, for example, forming a coating film in a thin film shape, so that the manufacturing process can be simplified and the manufacturing cost can be reduced.

DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of the present invention will be illustrated and described with reference to reference numerals attached to respective elements in the drawings.
An embodiment of the present invention will be described.
FIG. 1 shows a reflective optical displacement measuring device 100. This reflective optical displacement measuring apparatus 100 includes a scale 200 having an optical pattern 210 on one surface, a light source 310 that irradiates light toward the scale 200, and a light receiving means 320 that receives reflected light from the scale 200. 300 and a displacement detector (not shown) that detects the relative displacement between the scale 200 and the detection head 300 based on the light reception signal received by the light receiving means 320.

The scale 200 has a transmission part 211 that transmits light and a light reflection part 212 that reflects light at one pitch in a length measurement direction on one surface of a glass base material 240 serving as a scale base material.
The glass substrate 240 is a low thermal expansion glass having a low thermal expansion coefficient, and is formed in a longitudinal shape having a length in the length measuring direction. In general, in such a low thermal expansion glass, there are irregularities on the front and back surfaces at the time of purchase, or the thickness is not uniform, but the longitudinal scale 200 having a uniform thickness is cut out and an optical pattern is provided. The front surface 220 is mirror-finished. Note that the back surface 230 is not particularly processed and remains in an uneven state.
The pattern of the light reflection part 212 is formed by lithography etc. with respect to the metal film formed into the glass base material.

The detection head 300 is provided so as to be slidable in the length measuring direction of the scale 200 while facing the front surface 220 of the scale 200.
The light source 310 of the detection head 300 is not particularly limited, and examples thereof include a white light emitting diode and a laser light source. The light receiving means 320 may be configured to have a photoelectric conversion function of outputting an electrical signal from the received light, and examples thereof include a photodiode.

When the reflective optical displacement measuring device 100 is attached to a device (for example, a slide device in which a slider (not shown) slides along the guide) whose relative displacement amount is to be detected, the scale 200 is attached to the scale mounting surface 400 of the guide. Install and fix.
At this time, the back surface 230 and the scale mounting surface 400 of the scale 200 do not need to be particularly processed by paint or film formation.

According to such a configuration, the following effects can be achieved.
(1) Since the back surface 230 of the scale 200 has irregularities, the back surface becomes an optical rough surface, and reflection from the back surface does not enter the light receiving means 320. As a result, the measurement error of the optical displacement measuring apparatus 100 can be reduced, and the measurement reliability can be improved.
(2) Only the front surface 220 of the scale 200 needs to be mirror-finished, and the back surface 230 is not particularly processed, so that the manufacturing process can be simplified. As a result, manufacturing costs are reduced and manufacturing efficiency is improved.
(3) When attaching the scale 200 to the scale attachment surface 400, it is not necessary to provide a light absorbing material or the like on the back surface 230 of the scale 200, so that the attachment accuracy can be improved.

It should be noted that the present invention is not limited to the above-described embodiment, and modifications, improvements, and the like within the scope that can achieve the object of the present invention are included in the present invention.
For example, the back surface 230 of the scale 200 has been described as an optically rough surface having irregularities by not processing in particular. However, for example, the back surface 230 of the scale 200 is actively irradiated with light by a method such as grinding or sandblasting. A scattering surface may be formed.

  The present invention can be used for an optical displacement measuring device.

The figure which shows the optical displacement measuring device concerning one Embodiment of this invention. The figure which shows the conventional optical displacement measuring device. The enlarged view of the conventional optical displacement measuring device.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 ... Optical displacement measuring device, 200 ... Scale, 210 ... Optical pattern, 211 ... Transmission part, 212 ... Light reflection part, 220 ... Front surface, 230 ... Back surface, 240 ... Glass base material, 300 ... Detection head 310 ... Light source, 320 ... Light receiving means, 400 ... Scale mounting surface.

Claims (2)

A method of manufacturing a scale, which is provided so as to be relatively movable with respect to a detection head having a light source and a light receiving means, and has an optical pattern on one surface that reflects light from the light source toward the light receiving means,
It comprises a polishing step for polishing one surface where the optical pattern is provided on a glass substrate having irregularities on both front and back surfaces,
The scale manufacturing method characterized by not processing the back surface of the said one surface. A method of manufacturing a scale, which is provided so as to be relatively movable with respect to a detection head having a light source and a light receiving means, and has an optical pattern on one surface that reflects light from the light source toward the light receiving means,
A polishing step for polishing one surface on which the optical pattern is provided on a glass substrate having irregularities on both front and back sides,
And a step of cutting a scattering surface that scatters light to the back surface of the one surface.

Images