DE1143338B - Dial Test indicator - Google Patents

Description

The invention relates to the improvement of a known lever measuring device with a holder that can be inserted into the spindle of a machine tool or the like. The holder rotating with the spindle carries on the one hand a feeler lever, on the other hand an annular component with a dial gauge operated by the feeler lever is mounted on it in such a way that the dial gauge is held in place for the purpose of reading. The dial gauge and the component supporting it are accessible from the outside, so that it is sufficient to hold the supporting component with an arm which runs against a machine part serving as an abutment. The arm is flexible and inelastic so that it retains the shape it is given. In this way, the dial gauge bearing member in any angular positions about the spindle axis can be adjusted so that the clock can be held stationary in a favorable position for reading.

If you don't want to attach the dial gauge to the outside of the device - for example to protect it from dirt and damage to protect - the difficulty arises that they cannot be used in the usual way can hold on with mechanical means because it is inaccessible from the outside. Still is one Such a design is very desirable because it allows the dial gauge to be coaxial with the spindle axis to arrange. The relative movement between the stylus of the fixed dial indicator and that of the Feeler lever operated rotating transmission parts is smallest when this pin is in the spindle axis is arranged, while it increases with increasing radial distance from the spindle axis.

The invention consists in that the part which can be inserted into the spindle with the part carrying the feeler lever Part of the holder connected by means of a transparent hollow cylinder and that the dial indicator is inside of the hollow cylinder rotatably mounted about the longitudinal axis of its stylus, which is arranged parallel to the axis of rotation is, and that a stationary adjustable holding part for the dial gauge is arranged outside the hollow cylinder is, with the holding part and dial gauge as a preferably permanent magnet and influenced by it Anchors are formed and the hollow cylinder consists of a magnetically neutral material. At the location of mechanical holding parts, which cannot be attached according to the above, thus occur according to the invention magnetic lines of force that are effective across an air gap and into Give space to the air gap surrounding connecting parts without being disturbed by them.

In a preferred embodiment of the invention, a lever measuring device

Applicant:

Friedrich Wilhelm Deckel,
Munich 22, Bürkleinstr. 18th

2

the hollow cylinder and the dial gauge are arranged coaxially to the axis of rotation.

Further features of the invention emerge from the description of the exemplary embodiments of the invention shown in the drawings in conjunction with the claims. It shows
Fig. 1 is a longitudinal section through the device,
Fig. 2 is a view perpendicular to the longitudinal section of Fig. 1 partially cut in the direction C,

3 shows a cross section along line AA in FIG. 1, FIG. 4 shows a cross section along line BB in FIG. 1, FIGS. 5 and 6, other embodiments of the device in partial longitudinal section.

All of the feeler arm gauges shown in FIGS. 1 to 6 have a holder 10 which, with its cone 10 α, can be used in the spindle 12 of a machine, not shown. In the holder 10 is a coaxial to the axis of rotation hollow cylinder 14 made of solid, transparent, magnetically neutral material, for. B. glass or plastic. A holding plate 16 is fastened to the hollow cylinder 14, on which a slide 18 is arranged transversely to the axis of rotation so as to be displaceable and lockable. In the carriage 18 of the test piece 20 at 22 and scanning a pivoted feeler lever 22. The movement of the sensing lever superimposed are passed through a mouth 22 b to transmit in its longitudinal axis in the tips 23 pivotally mounted vibrating plate 24th A fork-shaped transmission lever 26 is pivotably mounted about bearing journals 28 and on the other hand rests with its cutting edge 26 α on the upper surface of the oscillating plate 24, so that when the sensing lever 22 pivots, the transmission lever 26 is pivoted up or down around the bearing journals 28. These pivoting movements of the transmission lever 26 are transferred to the in the spindle axis via its support dome 26 b

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lying, axially movable probe 30 r / the dial gauge 30 transferred.

The shaft 29 carrying the bearing pin 28 is fastened to a resilient plate 32 by means of two rivets 32 a. The plate itself is attached to the retaining plate 16 by screws 326. By adjusting an adjusting screw 16 α seated in the holding plate and pressing against the plate 32, the plate 32 can be bent downwards, which in the transmission lever 26 results in a pivoting movement about its cutting edge 26 α. The bearing dome 26 b is also adjusted here, and the pointer of the dial gauge can thereby be brought to a starting or zero position which is favorable for reading.

The dial gauge 30 is arranged within the hollow cylinder 14 such that the longitudinal axis of the stylus 30 α coincides with the spindle axis and thus the plane of its dial is parallel to this axis. The dial gauge is mounted freely rotatably in the holding plate 16 by means of a ball bearing 16 b and in the holder 10 by means of a bearing tip 306. In order to be able to stop the dial gauge in a position favorable for reading during the rotary movements of the parts 10 to 18 and 22, a device is provided, of which FIGS. 1 to 4, 5 and 6 show different versions.

On the back of the dial gauge (Fig. 3) a plastic support 34 is attached, in which some plate-shaped permanent magnets 36 are inserted with alternating polarity and are connected to one another by a soft iron insert 36 a. The magnets 36 are at a small distance from the inner surface of the hollow cylinder 14. A carrier 38 of circular arc-shaped cross-section is slidably placed on the outer surface of the hollow cylinder and is secured against axial displacement by the front edges of 10 and 16. The carrier 38 is made of resilient material, for example plastic, so that it can be pushed onto the hollow cylinder and removed from it, even if it extends to more than 180 ° for secure retention. A plurality of plate-shaped permanent magnets 40 with alternating polarity directions are also used in the carrier 38. They act on the magnets 36 and turn the clock so that the permanent magnets are as close as possible. In this way it is achieved that the dial gauge 30 is held in that position which results from the angular position of the magnet carrier 38 with respect to the axis of rotation. The magnet support body 38 can easily be set in any angular position and held in place by an abutment, for example by means of a holding rod 38 a (FIG. 1) bent parallel to the spindle axis, which engages in a bore of a stationary holder 42. The same is fastened by means of a flexible folded tube 42 α provided with a holding magnet 42 b at any point on the machine, as shown, at a flat point on the headstock 12 a.

The illustrated holding device for the magnet carrier permits a greater adjustment of the lever measuring device in the direction of the axis of rotation without changing the angular position of the dial gauge.

The described bearing of the dial gauge and the point-like contact lying in the spindle axis between the lever 26 and the stylus 30 a allows a smooth rotary movement of the dial gauge with respect to the rotating parts of the lever measuring device, so that the dial gauge by the magnetic device is held securely in the reading position.

Due to the soft iron insert 36 α, the dial gauge and its parts are largely against the action of the magnet shielded. To be on the safe side, it is preferable to avoid ferromagnetic materials for the dial gauge, to make their display as independent as possible from the magnetic lines of force.

In the embodiment according to FIG. 5, which essentially corresponds to the device according to FIG. 1, a ring 44 is rotatably mounted on the outer jacket of the holder 10 by means of a ball bearing. In a holder 46, the ring carries an electromagnet 48 which, with one pole, connects to the hollow cylinder 14 is facing. There is an air gap between the magnetic core and the hollow cylinder. On version 46 is a folding tube 49 attached to the other end carries a ball 50. This ball is suitable for receiving a plug 52 or a power source Feeding of the electromagnet 48. The connecting cables 54 are laid inside the folding tube.

According to Fig. 6, the electromagnet 48 is attached to the end of a folding tube 56, which by means of the on his Holding magnets 58 located at the other end on a schematically indicated ferromagnetic Machine part 60 is liable. The holding magnet is also designed as an electromagnet. The connector 52 or the Power source, not shown, are arranged in the same way as the cables 54 in the same way as in the Example according to FIG. 5. The folding tube is inelastic and flexible; the magnet 48 is also useful here adjusted so that an air gap remains free between it and the hollow cylinder.

Claims (8)

PATENT CLAIMS: 1. Fühlhebelmeßgerät with a holder which can be inserted into the spindle of a machine tool and which carries a sensor lever rotating with the spindle and on which a dial indicator actuated by the feeler lever is mounted for the purpose of reading, characterized in that the insertable into the spindle Part (10) is connected to the part (16) of the holder carrying the feeler lever by means of a transparent hollow cylinder (14) and that the dial gauge (30) is rotatably mounted inside the hollow cylinder about the longitudinal axis of its stylus (30 a), which is parallel to the axis of rotation. and that outside of the hollow cylinder a stationary adjustable holding part (38) is arranged for the dial gauge, the holding part (38) and dial gauge (30) being designed as a preferably permanent magnet and an armature (36, 40) influenced by it and the hollow cylinder being a magnetic one neutral material. 2. Lever measuring device according to claim 1, characterized in that the hollow cylinder and the dial gauge are arranged coaxially to the axis of rotation. 3. Lever measuring device according to claim 1 or 2, characterized in that the magnet consists of several partial magnets (40, 36), which, preferably with alternating opposing Direction of polarity in the direction of the orbital movement are arranged one behind the other and with their poles facing the armature (36, 40). 4. Lever measuring device according to claim 3, characterized in that the armature is also made of consists of several partial magnets, preferably with alternately opposite polarity directions are arranged one behind the other in the direction of the rotational movement. 5. Feeler lever measuring device according to one of the preceding claims, characterized in that that the holding part as the hollow cylinder partially encompassing, on it slidably mounted support body (38) designed in the form of a bearing shell and connected to a stationary abutment is. 6. Lever measuring device according to one of claims 1 to 4, characterized in that the Stopped !! (48) is attached to a ring (44) coaxial to the spindle axis, which is on a outer circumferential surface of the holder (10), preferably by means of ball bearings, mounted and with a fixed abutment is connected, between the holding part (48) and the outer jacket of the hollow cylinder (14) remains an air gap (Fig. 5). 7. Feeling lever measuring device according to one of the preceding claims, characterized in that that the holding part (38; 48) at the end of a flexible, inelastic carrier (56) z. B. one The folding tube is preferably detachably attached, the other end of which has a holding magnet (58) carries (Fig. 6). 8. Fühlebelmeßgerät according to claim 7, characterized in that the magnet of the holding part and the holding magnet are electromagnets and that the connecting cables and preferably the power source is also housed in the flexible support. 1 sheet of drawings © 309 508/131 1.63