DE4225281A1 - Electrical measurement appts. for bores of different dia. - features simultaneously adjustable fingers guided along radial grooves under action of bevel-wheel drive, and carrying inductive sensors - Google Patents

Abstract

Inductive measuring elements (30), each comprising a spring-mounted double lever (31) with a feeler (32) in the form of a spherical cap, are carried by centring fingers (15) which are radially adjustable, simultaneously and to the same extent, by a common actuator (19). The fingers in conjunction with sliders (14) form angular centring jaws (2) laid in radial guidance grooves (12) and movable by means of radial spindles (16). The jaws are secured by quadrant plates (e.g. 8,9) under the action of clamping screws. Outlets are provided on or around the fingers for compressed air supplied form a connection (42). ADVANTAGE - Costs of range of instruments for measurement of various dias. are saved without detriment to precision.

Description

The invention relates to a measuring device for measuring Bore diameters in the manner of a measuring mandrel. At acquaintances Measuring devices of this type, which are mainly used for Manufacturing measurement technology are determined, is the diameter of the cylindrical mandrel body about 4/100 to 6/100 mm smaller than the bore diameter. The thorn therefore only has the task to guide the gauge in the bore while two or more measuring elements attached to the mandrel circumference the distance to Record the surface of the hole.

Particularly suitable as measuring elements for this purpose flat inductive probes according to the German one Laid-open specification 40 23 504. But others can also electrical probes are used, including those at which the movement of the probe through inclined planes or Transfer lever to a measuring element and thereby deflected becomes. But there are also gauges with pneumatic  Known measuring elements according to the system nozzle - baffle work (specialist book "Manufacturing measurement technology", Dr.-Ing. Wolfgang Dutschke, B.G. Teubner Verlag, Stuttgart, 1990, page 87).

The disadvantage of these known measuring devices is that they only for a diameter value with a relatively small one Tolerance field are designed. This is a large assortment such measuring equipment necessary to measure all diameters to cover.

The invention has for its object these high Investment costs increase significantly with the same measuring accuracy reduce.

This task is the introductory part of a measuring device designated type according to the invention by the characterizing Features of claim 1 solved. After that, a adjustable "measuring mandrel" proposed, the mandrel body no is cylindrical block, but of several in it Distance adjustable centering fingers. Since that Typically also on the spindle of a measuring device Measuring machine or the like attached and in this way is inserted into the hole, the radial adjustment the centering finger symmetrical to the axis of this spindle or of the hole to be measured. For that is one Adjustment mechanism with a common actuator provided a radial adjustment with respect to Central axis to the same extent and accomplished at the same time. The centering fingers are parallel to each other and to Central axis arranged. There must be at least two but preferably four to two in two directions perpendicular to each other and thus the ovality of the Capture hole. The measuring device becomes coaxial in the bore introduced how it is possible with mechanical aids, so each centering finger should carry a measuring element. Can on the other hand, the measuring device during the measurement in the radial direction  dodge, e.g. B. if it is done by hand, it may suffice that only one of two diametrically opposite each other a measuring element attached opposite centering fingers is. The other centering finger then puts on immediately the bore surface. With centering fingers odd Other variants are also possible. The shape of the Centering finger is chosen so that it is cylindrical Have an outer surface whose radius of curvature is approximately the radius corresponds to that hole at the lower end of the Adjustment range.

The adjustment range can e.g. B. 20 mm. On everyone in The diameter in this range is the measuring device adjustable. A calibration ring is usually used for calibration, similar to DIN 2250.

As far as the constructive details are concerned suggested that the centering fingers each with a slider form angular centering jaws in radial Guide grooves on the face of a preferably cylindrical housing are slidably mounted. The Guide grooves can e.g. B. a T-shaped or one have a trapezoidal cross-section (dovetail). The Centering jaws can be arranged radially Spindles can be moved, the latter with bevel gears a common drive bevel gear mounted in the middle are engaged. This drive bevel gear, which the represents common actuator can at the Have a hexagon socket front so that one from the beginning, d. H. even if the measuring device is on a spindle attached, place the turning tool in the central axis and can make the adjustment by hand. The adjustment could alternatively be via one of the radially arranged ones Spindles are made on the casing side.  

Another common adjustment system for the centering jaws could look like a spindle coaxial with the central axis is stored in the housing and that the spindle nut on Deflecting lever acts, which are hinged to the housing and with move the centering jaws of the other lever arm. This too effective spindle as a common actuator could in same way as the aforementioned bevel gear for a hand tool be made accessible.

To the radial in further development of the aforementioned proposal Coupling spindles with the centering jaws expediently provide the sliders with extensions, the elongated openings at the bottom of the guide grooves enforce and are designed as spindle nuts. Against Penetration of dirt and shavings can prevent these openings be protected by having a sliding Cover, for example made of spring band steel or several sheets of spring band steel lying on top of each other, are provided.

Although a spindle drive with a small pitch is self-locking is, so that the set position of the centering jaws too is maintained, it is necessary in terms of high accuracy advantageous if the centering jaws during of the measuring operation are clamped. This can happen with an embodiment of the measuring device with four centering jaws and two vertically crossing guide grooves can be achieved in that the groove side surfaces by the Edges formed by four quadrant-shaped guide plates are fixed, with two diametrically arranged guide plates connected to the housing and the other two to Clamping the sliders can be clamped to the housing. Depending on the cross-section of the guide grooves, it may be sufficient if the two movably arranged guide plates are very exactly, for example by means of a ball bushing in axial Direction, d. H. perpendicular to their surface extension,  be performed. A is used to apply the clamping force axially attached screw. But it is also possible for example with guide grooves Dovetail cross section, the guide plate radial, d. H. in the direction of the bisector of the guide grooves, or in addition to the radial plane inclined and to tense. Definitely can be a safe in this way Locking of the centering jaws can be achieved.

This preferred drive system is also suitable excellent for introducing the connection and other Lines to the measuring elements, mind you when adjusting the centering jaws with these their position with respect to the Change housing. It is suggested that the Centering jaws and their respective extension with a from Measuring element up to the inner nut through the spindle nut are provided. It is also proposed that the housing its own, accommodating the spindle drive system locked gearbox and one of them by a radial transverse wall has a separate terminal space from which from the measuring lines to the inner channels and through them the measuring elements are guided. Under measuring lines are in In the case of electrical buttons, electrical lines understood, with pneumatic buttons it can Hose lines. In the connection room there is Possibility of coming from the individual measuring elements Test leads on terminal strips or the like Summarize connection elements. In addition, the Connection room for housing electronic Components used for processing the measurement signals become.

Another closely related Further training sees purging air openings on the measuring elements or on the centering fingers in the area of the measuring elements. The outflowing air, also called sealing air, is supposed to do that  Prevent dirt from entering the measuring gap. The air can be introduced through the inner channel mentioned, too if this electrical wiring or the hose for one contains pneumatic measuring nozzle. In this case, the Internal ducts via hose lines of a correspondingly large size Cross section connected to the connection space. This Hose lines extend from the transverse wall to the Beginning of the inner channels on the extensions. They contain also the measuring lines. The connection space is in this Execute case tightly. It serves as shared storage for the purge air and is for this purpose with a Compressed air connection to be provided.

Instead of the manual adjustment described above Centering jaws to the desired measuring diameter also the possibility of a servomotor for the common Provide actuator, e.g. B. an electric motor. On the other hand in this case should be the complete Remote control to allow a power operated Clamping device for locking the centering jaws be provided for what z. B. compressed air would be suitable.

An embodiment of the invention is explained below with reference to the drawing. In particular, FIG 1. 2 shows an axial section of Bohrungsmeßgeräts according to the section line II in Fig. 3, Fig. Is a view of the upper part of the Bohrungsmeßgeräts according to Fig. 1, partially cut away according to the line II-II in Fig. 3 and Fig. 3 2 shows a top view of the bore measuring device according to FIG. 1.

An essentially cylindrical housing 1 is provided which has four centering jaws 2 on one end face and a shaft 3 on the other end for attachment to the spindle 4 of a machine tool, indicated by dash-dotted lines. The housing is divided by a transverse wall 5 in an upper gear space 6 and a lower connection space 7 . In the present simplified illustration of the housing, it is not shown that the upper and lower end walls of the housing can be removed, so that the two spaces mentioned are accessible for assembly.

On the top of the housing 1 , in particular according to FIG. 3, four quadrant-shaped guide plates 8 , 9 , 10 and 11 can be seen. These guide plates form between them and with the housing surface two intersecting, cross-sectionally T-shaped ( FIG. 2) guide grooves 12 and 13 . In these guide grooves four sliders 14 are slidably guided, which form the angular centering jaws 2 already mentioned with centering fingers 15 .

To move the centering jaws in the guide grooves 12 and 13 , four radially arranged spindles 16 are arranged in the gear chamber 6 . They are mounted with one end in a central projection of the transverse wall 5 and with the outer end in a bearing 17 , which is inserted into the wall of the housing 1 . The spindles 16 each carry a bevel gear 18 on the inner side and these bevel gears mesh with a central drive bevel gear 19 mounted in the central axis, which is also mounted in the aforementioned projection and at the top in the end wall of the housing. An extension 20 designed as a spindle nut is attached to each slide piece 14 by means of a sleeve 21 , which extends through a longitudinal slot 22 of the upper housing end wall and thus connects the respective centering jaws 2 with its spindle 16 . You can now turn this bevel gear by hand using a hexagonal tool that is axially inserted from above into an internal hexagon 23 of the drive bevel gear 19 and thereby move all the centering jaws 2 together. The threads of axially identical spindles are each in the same direction and chosen so that with a right turn of the drive bevel gear 19 all centering jaws 2 move inwards and in the opposite direction of rotation outwards.

In order to be able to additionally lock the centering jaws in a desired measuring position, it is provided that only the two guide plates 8 and 10 are attached to the housing 1 , while the guide plates 9 and 11 act as movable clamping parts. With the help of two guide pins 24 ( FIG. 2), which are stuck in the housing 1 , they are guided in a small stroke range in the vertical direction. Ball bushings 25 , which are placed around the guide pins, serve for precise storage. A plug 26 covers the bearing arrangement upwards. A clamping screw 27 presses the respective guide plate against the housing end wall with the interposition of a plate spring 28 . The flange-like protruding edge strips 29 of the guide plates 9 and 11 press on the T-legs of the sliders 14 and clamp them to the housing.

A measuring element 30 is installed in the upper and front part of the centering fingers 15 , the details of which are described in more detail in DE OS 40 23 504 and is therefore only shown briefly and schematically here. In the case of this flat measuring element, a double lever 31 supported by means of a spring bar is provided, which carries a probe tip 32 in the form of a spherical cap at one end. The electrical connecting lines 33 of the two induction coils of this measuring element 30 run through a bore 34 which is introduced in the longitudinal direction into the centering finger and is sealed off at the top by a plug 35 . The bore 34 forms with a further bore 37 , which is closed off by a stopper 36 , in the slide 14 and with the interior of the sleeve 21 a continuous inner channel which leads in the extension 20 to the vicinity of the spindles 16 and from there by means of a tube 38 the transverse wall 5 is connected to the connection chamber 7 . The electrical lines 33 of each measuring element 30 extend through these inner channels and hoses and can be connected in the connection space 7 by means of a terminal strip, which is indicated, with a connecting cable 40 which is guided through the shaft 3 and a grommet 41 to the outside.

The coherent inner channel formed from the individual bores and the hose 38 serve not only for the electrical line routing, but also in this example as a line channel for purge air, which is why a connection 42 for compressed air of relatively low pressure is provided on the connection chamber 7 . This purge air emerges from the inner channel through the measuring elements 30 in a manner described in more detail in the aforementioned document. As a result, the double levers 31 are freed from dirt particles or kept free.

To prevent the penetration of chips and dirt into the gear chamber 6 , the longitudinal slots 22 , which run along the bottom of the guide grooves 12 and 13 , are closed by sliding covers 43 made of spring steel. These covers are also effective when the centering jaws 2 move.

As indicated by dash-dotted lines in Fig. 1, the centering jaws can be moved in a range of about 15 mm each, which means that the smallest bore diameter to be measured, as set, is about 35 mm and the largest bore diameter to be measured is 65 mm . To adjust the clamping screws 27 are loosened and then tightened again. The exact calibration of the measured value set to zero can be carried out with the help of a ring gauge.

1 housing
2 centering jaws
3 shaft
4 spindle
5 transverse wall
6 gearbox
7 connection compartment
8 guide plate
9 guide plate, movable
10 guide plate
11 guide plate, movable
12 guide groove
13 guide groove
14 slider
15 centering fingers
16 spindle
17 bearings
18 bevel gear
19 drive bevel gear
20 extension
21 sleeve
22 longitudinal slot
23 hexagon socket
24 guide pins
25 ball rifle
26 stoppers
27 clamping screw
28 disc spring
29 edge strips
30 measuring elements
31 double lever
32 stylus tip
33 lines
34 hole
35 stoppers
36 stoppers
37 hole
38 hose
39 terminal block
40 connection cables
41 spout
42 Compressed air connection
43 cover

Claims (11)

1. Measuring device for measuring bore diameters in the manner of a measuring mandrel, characterized in that at least two centering fingers ( 15 ) parallel to one another and to a central axis are arranged at equal distances from the central axis on both sides of the same or around the same, that the centering fingers ( 15 ) are adapted in terms of their external shape to the bore to be measured so that they guide the measuring device with play in the bore, that at least two centering fingers ( 15 ) carry measuring elements ( 30 ) which detect the distance to the surface of the bore, and that the centering fingers by means of a common one Actuator ( 19 ) to the same extent and at the same time are radially adjustable. 2. Measuring device according to claim 1, characterized in that the centering fingers ( 15 ) each with a slide ( 14 ) form angular centering jaws ( 2 ) which are slidably mounted in radial guide grooves ( 12 ) on the end face of a housing ( 1 ). 3. Measuring device according to claim 2, characterized in that the centering jaws ( 2 ) with the aid of radially arranged spindles ( 16 ) are movable and the latter via bevel gears ( 18 ) with a common, mounted in the central axis drive bevel gear ( 19 ) in engagement. 4. Measuring device according to claim 3, characterized in that the drive bevel gear ( 19 ) has an internal hexagon ( 23 ) on the housing end face. 5. Measuring device according to claim 2, characterized in that the sliding pieces ( 14 ) are provided with extensions ( 20 ) which pass through elongated openings ( 22 ) at the bottom of the guide grooves ( 12 ) and are designed as spindle nuts. 6. Measuring device according to claim 5, characterized in that the openings ( 22 ) are provided with a displaceable cover ( 43 ). 7. Measuring device according to claim 2, characterized in that four centering jaws ( 2 ) and two perpendicularly crossing guide grooves ( 12 ) are provided and the groove side surfaces are formed by the edges of four quadrant-shaped guide plates ( 8 to 11 ), two diametrically arranged guide plates ( 8, 10) fixedly connected to the housing (1) and the other two are for clamping the slides (14) with the housing (1) braced (27). 8. Measuring device according to claim 5, characterized in that the centering jaws ( 2 ) and their respective extension ( 20 ) with an from the measuring element ( 30 ) to the spindle nut through the inner channel ( 34 , 37 and 38 ) are provided. 9. Measuring device according to claim 3, characterized in that the housing ( 1 ) has a spindle drive system receiving gear space ( 6 ) and one of these by a transverse wall ( 5 ) separated connection space ( 7 ), from which the measuring lines ( 33 ) to the Inner channels and through these to the measuring elements ( 30 ) are guided. 10. Measuring device according to claim 9, characterized in that the inner channels in the region of the centering fingers ( 15 ) or the measuring elements ( 30 ) have outlets for purge air, that hose lines ( 38 ) from the connection space ( 7 ) to the extensions ( 20 ) are and open into the inner channels and that the connection space ( 7 ) is provided with a compressed air connection ( 42 ). 11. Measuring device according to claim 2, characterized in that an actuator for the common actuator of the Centering jaws and a power-operated clamping device for Locking the centering jaws is provided.