DE2530163A1 - Positioning optical measuring instrument - has grating illuminator and image optics for positioning or reading of relative position of two objects - Google Patents

Abstract

Optical measuring instrument for positioning or reading of relative position of two objects has grating, illuminating device and image optics. The optics magnify a sector of the graduation onto a ground-glass plate. The graduation of the grating (3) comprises also unnumbered fine graduations. A sector (T) of the graduation is shown on a stationary reading index (J). The optics or the carrier are supported directly by the grating. The carrier is coupled to a driver (1) which projects from a hollow body. The path of light beams passes into the hollow body and the path of image beams onto the ground-glass plate.

Description

Optical measuring device The invention relates to an optical measuring device for positioning or reading the relative position of two objects, consisting of one Scale, a lighting device and an imaging optics, by means of which a Graduated section of the scale, optically enlarged, shown on a focusing screen will.

In optical measuring devices of this type, they are often used Striving for strongly magnifying, short focal length imaging optics. The usage such imaging optics is problematic. Because of their shallow depth of field namely cause even slight fluctuations in distance between the imaging optics and the plane of division of the scale blurs in the figure. The demand of High image quality therefore not only requires high quality optics, but # also a high level of precision in the mechanics involved.

From CH-PS 398 098 it is already in the case of an optical measuring device known that the imaging optics or their support body via sliding blocks directly supported on the division surface of the scale. This measure ensures that the working distance between the imaging optics and the dividing surface of the scale always remains constant. A disadvantage of this optical measuring device is to be seen as that due to the small working distance between the imaging optics and the scale one Cleaning of these assemblies will be difficult.

In addition, there is a risk that in rough workshop operation the scale experiences damage.

From DT-OS 2 259 604 an arrangement has also become known, in which one is suspended from leaf springs to stabilize the working distance The imaging optics are supported by an air bearing on a movable component (image plate). The possible uses of such an arrangement are limited.

The object of the invention is to provide an optical measuring device of the initially mentioned called type to create, which is characterized by high accuracy, easy handling, in particular but characterized by a simple and compact design.

Another object of the invention is to achieve that the scale and the optical components of the measuring device even in rough workshop operation stay free from any pollution. The invention should also cultivate the optical measuring device on machines can be made much easier.

The invention solves the problem essentially by Combination of the following features, some of which are known per se: a) the division of the scale shows fine divisions that have not yet been numbered between numbered graduation intervals, b) the optical image of a graduation cutout of the scale on a stationary one Reading index is by means of a strongly magnifying, short focal length Imaging optics causes c) the imaging optics or their carrier body is supported directly on the scale, so that the working distance between the imaging optics and the dividing plane the scale is always constant, d) is the support body for the imaging optics coupled via a backlash-free coupling to a driver, which consists of a The scale and the imaging optics protrude from the hollow body shielding against environmental influences, e) through the driver is the illumination beam path into the interior of the Hollow body and the imaging beam path from the hollow body to the driver attached ground glass.

Further features of the invention can be found in the subclaims.

The optical measuring device according to the invention offers the following essentials Advantages: 1. High accuracy with a small, compact design, 2. Particularly light Handling, as the measured value can be read immediately without adjusting any components is, 3. structurally simple construction and thus cost-effective production possible, 4. Uncomplicated installation of the measuring device on the machine, since the measuring device is delivered in a fully adjusted state, 5. versatile applicability, and 8. because of the independence of machine guides, 6. no pollution and Damage to the sensitive assemblies (scale / optical parts) possible, 7th possibility for full value adjustment.

An exemplary embodiment of the invention is shown in the drawing.

It shows FIG. 1 a side view of the optical measuring device according to FIG of the invention, Figure 2 is a plan view of Figure 1, Figure 3 is a section according to the Line A-B of Figure 2, Figure 4 shows a section along the line C-D of Figure 1, Figure 5 shows a section along the line E-F in FIG. 4, and FIG. 6 shows a section along the line G-H of Figure 4.

In the example, the reading device is item number 1 and 2 denotes the structural unit carrying the scale 3. The reader 1 and the structural unit 2 are attached to a machine bed or machine slide. The structural unit 2 expediently consists of an extruded hollow aluminum body 4 and a glass scale 3, which is fixed in the hollow body 4 by gluing. The rigid one Hollow body 4 is by means of flexible, roof-shaped sealing lips 5/6 closed.

In the case of the graduation applied to the scale 3, in the exemplary embodiment the tenth intervals are numbered. Figure 2 shows a complete picture of the used Graduation T in reading field A of the device 1. The reading option in numbers is accordingly "0.1 mm", with un-numbered graduation lines "0.01 mm". The reading on the index J is exactly 220.2 mm.

A coarse division TG is also provided on the hollow body 4, which can be read from an index JG of the device 1.

The mapping of a partial extent of the scale 3 takes place by means of a short focal length objective 7 which is attached to a carrier body 8 (Figure 3). The objective 7 has a very high magnification (50 times).

The lens carrier 8 is supported directly via low-friction sliding shoes 9 on the dividing surface of the glass scale 3. This ensures that the very short working distance due to the short focal length of the lens 7 between the objective 7 and the division surface of the scale 3 is always constant. On the carrier body 8 rollers (ball bearings) 10 are also provided over which this is supported on the hollow body 4.

The carrier body 8 is free of play, which is designated as a whole by 11 Coupling (FIG. 4) coupled to component 1 designed as a driver. Of the Driver 1 penetrates the sealing lips 5/6 and has a in this section sword-shaped cross-section (Figure 6). In the opposite to the hollow body 4 protruding area the driver 1 is designed as a housing 12. The lighting device is in the housing 12 21, deflection mirror 16 and 17, a ground glass 18, a reading magnifier 19 (Figure 5) and accommodated the mechanical parts of the assembly 20 for the full value setting. The lighting device 21 contains a lamp 13 and a condenser 14. Das The housing 12 accommodating the aforementioned parts is secured by means of a cover 22 locked.

In the housing 12 there is an opening 23 for the illumination beam path, a shower breach 24 for the imaging path and a breakthrough 25 for the angle lever 26 of the assembly 20 The illumination beam path is on the back of the scale 3 deflected via mirrors 27 and 28. The mirror 27 is via a holder (not shown) attached to the sword-shaped portion of the housing 12 The mirror 28 is together with a condenser via a holder 30 (Figure 3) on the carrier body 8 for lens 7.

The coupling 11 11 between the lens carrier 8 8 and driver 1 is made from a flat connecting part 31, which has a backlash-free ball joint 32 on Lens carrier 8 and, via a further ball joint 33, to one attached to the driver 1 Angle lever 26 is coupled. The center of the ball joint 32 or 33 is located at the level of the neutral of the scale 3. This ensures that the lens carrier 8 on the sword-shaped section of the driver 1 at the level of the neutral fiber of the Scale 3 is coupled. This coupling causes deformations of the ## stabes 3 caused errors compensated.

A preloaded spring 34 that is positioned between the mounting shaft of the Ball joint 33 and a hole in the connecting part 31 is introduced, causes that the lens carrier 8 both against the guide surface on the glass scale 3 as well is pressed against the guide surface on the hollow body 4.

The assembly 20, which enables full value adjustment, contains an angle lever 26, an actuating screw 36 and a spring 37. The angle lever 26, to which the ball joint 33 is attached, is on the driver via an axis of rotation 35 1 pivoted. The angle lever 26 is adjusted by means of the screw 36 against the action of the spring 37. When the screw 36 is actuated, the coupling assembly 11 deflected and the lens carrier 8 relative to the division of the scale 3 slightly postponed until a numbered division interval from which at the measurement is to be assumed, the reading index J is set.

Claims (10)

Expectations 1. Optical measuring device for positioning or reading the relative position two objects, consisting of a scale, a lighting device and a Imaging optics, by means of which a division section of the scale is optically enlarged is formed on a focusing screen, characterized by the combination of the following partly known features: a) the division of the scale (3) shows between numbered graduation intervals still un-numbered fine divisions, b) the optical Illustration of a graduated section (T) of the scale (3) on a stationary one Reading index (33 is determined by means of a highly magnifying, short focal length imaging lens (7) causes, c) the imaging optics (7) or its carrier body (8) is supported directly on the scale (3) so that the working distance between the imaging optics (7) and the division plane of the scale (3) is always constant, d) the support body (8) for the imaging optics (?) is via a backlash-free coupling (11) on a driver (1) coupled, which consists of a scale (3) and the imaging optics (7) against Hollow body (4) shielding environmental influences protrudes, e) through the driver (through is the illumination beam path into the interior of the Zohlkorpers (4) and the Imaging beam path from the hollow body (4) to the one attached to the driver (1) Ground glass (18). 2.) Optical measuring device according to claim 1, characterized in that that the scale (3) is a glass scale in a rigid hollow body (4) is attached and that on the dividing surface of the glass scale (3) and on one the surface of the hollow body (4) lying approximately at right angles to the carrier body (8) for the imaging optics (7) is performed and that also the carrier body (8) over a backlash-free coupling (11) on a slender in the area of the hollow body (4), preferably sword-shaped driver (1) is coupled between flexible, roof-shaped sealing lips (5/6) which close the hollow body (4), is passed and that also the driver (1) in the opposite to the hollow body (4) protruding area is designed so that it the housing (12) of the reading device embodied. 3.) Optical measuring device according to claim 1 and 2, characterized in that that the support body (8) for the imaging optics (7) resiliently against the guide surfaces on the glass scale (3) and hollow body (4) is pressed and on the guide surface the glass scale (3) via sliding shoes (9), preferably made of plastic, and on the guide surface of the hollow body (4) is expediently supported via ball bearings (10). 4.) Optical measuring device according to claim 1 to 3, characterized in that that the rigid hollow body (4) made of metal, preferably aluminum, and that the glass scale (3) is fixed in the hollow body (4) by gluing. 5.) Optical measuring device according to claim 2 to 4, characterized in that that the lighting device (21) in the housing (12) of the driver (1) provided # 'fs ## and that the illumination beam path through a breakthrough (23) is guided in the driver (1) into the interior of the hollow body (4) and in the hollow body (4) is deflected by means of mirrors (2? And 28) which face away from the imaging optics (7) Side of the scale (3) are provided and one of which is on the slim section of the driver (1) and the other together with a condenser (29) on the carrier body (8) for the imaging optics (7) is attached and that also the imaging beam path through an opening (24) in the driver (1) via a deflection mirror (16; on a in the housing (12) attached ground glass (18) is guided. 6.) Optical measuring device according to claim 1 to 5; characterized, that the backlash-free coupling (11) between the carrier body (8) for the imaging optics (7) and the driver (1) is a joint-like assembly (31/32/33). 7.) Optical measuring device according to claim 6, characterized in that that the coupling (11) consists of a kinkateifen connecting part (31) that over a backlash-free ball joint (32) on the support body (8) for the imaging optics (7) is coupled and coupled to the driver (1) via a further ball joint (33) is and that the center of the sphere of the aforementioned joints (32/33) at the level of the neutral Fiber of the scale (3) lies. 8.) Optical measuring device according to claim 1 to 7, characterized in that that the joint-like coupling element (11) is slightly deflected for full value adjustment is and that by the deflection of the coupling element (11) an adjustment of the Carrier body (8) for the imaging optics (7) relative to the division of the glass scale (3) is effected. 9.) Optical measuring device according to claim 8, characterized in that that a joint (32) of the coupling (11) attached directly aT \ .ein an angle lever (26) is rotatably mounted in the housing (12) of the driver (1) and counteracts the action a spring (37) slightly adjustable by means of an actuating element (36) is. 10.) Optical measuring device according to claim 1 to 9, characterized in that that on the surface of the hollow body (4) lying in the plane of the reading field (A) a coarse graduation (TG) is provided, which at an index (JG) on the housing (12) of the Reading device is readable.