DE4139309A1 - Measuring dimensions of hollow bodies, esp. pipes - using fixed and movable parts with sensing arms with stops image separation measured when applied to pipe - Google Patents

Abstract

An arrangement for measuring external and internal dimensions of hollow bodies has a foot section (4) with a sensing arm (12) rigidly mounted on a guide profile (2) and a head section (6) movable w.r.t. the foot section. The head section may have a sensing arm (12). The head section has a measurement device for determining the distance between measurement stops (16) on the sensing arms. The stops are designed to be placed on the measurement hollow body. A dial gauge (23) on the head part moves along a scale (22) on a mesaurement carriage (21). USE/ADVANTAGE - Esp. for measuring external and internal dimensions of concrete or reinforced concrete pipes very simply and with a high degree of accuracy.

Description

The invention relates to a device for measuring External and / or internal dimensions of hollow bodies, especially of pipes made of concrete or reinforced concrete.

Pipes made of concrete or reinforced concrete for pipelines usually made with a socket end and a pointed end, that for making a pipe joint under Interposition of a sealing ring made of elastic material is inserted into the sleeve end of an adjacent pipe. Pipes of this type are usually of nominal diameters manufactured up to about 4 m. To check the production and to be able to control the functional area of the sealing ring and a precise determination of the Sealing area, namely the outer diameter at the tip end and the inner diameter at the end of the socket. Since the Functional area of the sealing rings is very small, it is necessary to take very accurate measurements.

Commercial measuring instruments used to measure the dimensions of concrete and reinforced concrete pipes only have Accuracies of +/- 1.5 mm and are for future ones Unsuitable requirements. Generally usable measuring devices, such as B. calipers are in great variety on the Market, however, can be dealt with here Measurement tasks are not used because they are too difficult are handling.

Against this background, the object of the invention based on creating a measuring device with which simple The outer and inner dimensions of hollow bodies, especially of pipes made of concrete or reinforced concrete with high Accuracy can be measured.

This object is achieved according to the invention by a  Device with the features of the characteristic part of the Claim 1 solved.

Advantageous further developments result from the Subclaims.

The advantage of the invention is seen above all in that the simple and clearly structured device allows indirect length measurement, d. H. the real one Measuring device does not come with the object to be measured in touch; Strain of a slim probe transverse to its longitudinal axis, which is the measurement result do not occur. With the Measuring device according to the invention can thus be a measuring accuracy of +/- 0.1 mm.

The large dimensions of the body to be measured and the high one Measurement accuracy are in the measuring device according to the invention coped with that exactly the distance between the middle part fixable on the guide profile and in contrast, movable head part is measured. The Determination of the respective position of the middle part results from the - known - position of the recess, against which the middle part is fixed. Another Facilitation of coping with large dimensions follows from the fact that the guide profile also detachable from individual interconnectable sections can exist.

The invention is based on one in the drawing illustrated embodiment explained in more detail. It shows

Fig. 1 shows an inventive measuring device, in side view in use for measuring an inner diameter,

Fig. 2, the measuring instrument shown in Fig. 1 in use for measuring an outer diameter,

Fig. 3 is an end view of the measuring instrument,

Fig. 4 shows the essential parts for the measuring device according to the invention in side view in a larger representation and

Fig. 5 is a front view corresponding to FIG. 4.

The measuring device 1 according to the invention consists, as can be seen from the illustrations in FIGS. 1 to 3, of a guide profile 2 , which can optionally also be composed of individual sections 2 a, 2 b and along a surface line with a number of at equal intervals a recesses 3 arranged from each other is provided. A tube can be used as the guide profile 2 , in which the recesses are holes; however, it can also be a rod or a rail that enables exact parallel guidance.

At the lower end of the guide profile 2 there is a foot part 4 and at its upper end a middle part 5 and a head part 6 ; the actual measuring device is arranged between the middle part 5 and the head part 6 . Both the foot part 4 and the middle part 5 can be fixed relative to the guide profile 2 by means of pins which can be brought into a recess 3 in each case for snapping into place. In order to ensure the necessary small tolerances, both the bores of the recesses 3 are very precise with one another and the pins (not shown) are conical.

The measuring apparatus 1 is of a reinforced concrete pipe 8 used in FIG. 1 for measuring the internal diameter in the region of the sleeve 7, in the example of Fig. 2 for measuring the outer diameter of the spigot end 9 of the tube 8. The design of the measuring device and its function are described below with reference to FIGS. 4 and 5.

The foot part 4 is fixed, but can be removed on the guide profile 2 . It consists of a sleeve-like guide body 10 on which an actuating device 11 , for. B. is a spring-loaded bolt for the engaging in one of the recesses 3 pin through which the foot part can be fixed on the guide profile 2 . On the guide body 10 , a probe arm 12 is attached laterally, which consists of a bearing part 13 fastened to the guide body 10 and an eccentric part 15 which continues and which can be pivoted about an axis 14 extending transversely to the guide profile 2 . At the outer end of the eccentric part 15 , a measuring stop 16 is fastened to bear against the object to be measured. The measuring stop 16 consists of a measuring roller which is rotatable about an axis 17 . The axis 17 runs parallel to the axis 14 and is at a distance from it which corresponds to the radius of the measuring roller. By pivoting the eccentric part 15 relative to the bearing part 13 , measurements of the outer and inner diameters can be carried out in relation to the axis 14 .

On the guide body 10 there are approximately U-shaped contact parts 18 above and below the feeler arm 12 , which can be extended transversely to the guide profile and can be fixed by means of locking screws 19 . By means of these system parts 18 , which can also be provided with a scale, the position of a measuring point can be made adjustable from the end of a tube for both external and internal measurement.

The head part 6 , similar to the foot part 4 , also consists of a sleeve-like guide body 20 which is arranged on the guide profile 2 so as to be smooth but largely free of play. The guide body 20 of the head part 6 is also equipped in the same way as the foot part 4 with a probe arm 12 with a measuring stop 16 formed from a measuring roller and system parts 18 . On the head part 6 , a caliper 21 is arranged as a measuring device, which consists of a measuring rod 22 and a dial gauge 23 .

The measuring rod 22 is fixed with its lower end 24 to the central portion 5, which also consists of a sleeve-like guide body 25 and by an actuating device 26 can be fixed for a pin relative to the guide profile. 2 The head part 6, which is displaceable relative to the central part 5, is secured against rotation and falling out by a sliding tube 27 which is fastened on the one hand in a holder 28 on the guide body 25 and on the other hand is guided in a guide 29 on the guide body 20 .

A handle 30 with a locking device 31 is provided on the head part 6 , which can be actuated by means of a spring-loaded handle part 32 and enables the head part to be fixed in a clamped manner relative to the guide profile 2 .

In the measuring device according to the invention, the distance between the - fixed - middle part 5 and the - on the other hand displaceable - head part 6 is measured with the help of the caliper 21 . The caliper 21 is not moved directly on the object to be measured, so that stresses do not occur transversely to its longitudinal axis. This also prevents wear and possible damage to the caliper. A microprocessor can be added to the caliper 21 , which can program-save and print out all the data to be measured; Changes in length due to temperature differences can be easily taken into account. The contact to the body to be measured takes place exclusively via the hardened measuring rollers 16 .

To carry out a measurement, for example an internal measurement according to FIG. 1, the procedure is as follows: First, the position of the measuring point on the sleeve 7 is set via the system parts 18 . Then the head part 6 is brought up to the middle part 5 and the caliper 21 is brought into the zero position. The length can then be entered in the caliper. It corresponds to the total dimension of the spacing of the recesses plus the fixed dimension between the middle part 5 and the head part 6 corresponding to the position of the measuring rollers 16 for inside and outside measurement. Finally, the device is brought up to the body to be measured and the head part 6 is extended or retracted until the measuring roller 16 stops. The maximum dimension is determined by pendulum movements, which can be read off on dial gauge 23 ; the length read is the actual size.

A second measurement possibility is to set the exact diameter or length (nominal dimension) and to measure the deviations from zero by means of the caliper 21 .

Claims (9)

1. Device for measuring the outer and / or inner dimensions of hollow bodies, in particular pipes made of concrete or reinforced concrete, characterized in that a foot part ( 4 ) provided with a probe arm ( 12 ) is fixed on a guide profile ( 2 ) and also with a head part ( 6 ) provided with a probe arm ( 12 ) is arranged displaceably relative to the foot part ( 4 ), the head part ( 6 ) with a measuring device for determining the distance between - determined for contact with the hollow body to be measured - on the probe arms ( 12 ) provided measuring stops ( 16 ) is connected. 2. Device according to claim 1, characterized in that a measuring slide ( 21 ) with a parallel to the guide profile ( 2 ) extending measuring rod ( 22 ) is provided as a measuring device, which can be fixed at a length-specific point relative to the guide profile ( 2 ) and on which a dial gauge ( 23 ) arranged on the head part ( 6 ) can be moved along. 3. Apparatus according to claim 2, characterized in that the measuring rod ( 22 ) is attached at one end to a between the foot part ( 4 ) and the head part ( 6 ) on the guide profile ( 2 ) arranged central part ( 5 ) which along the Guide profile ( 2 ) is displaceable and fixable relative to it at length-specific points. 4. Device according to one of claims 1 to 3, characterized in that the head part ( 6 ) relative to the guide profile ( 2 ) can be fixed by clamping. 5. Device according to one of claims 1 to 4, characterized in that along the guide profile ( 2 ) at certain intervals from each other recesses ( 3 ) are provided and that the foot part ( 4 ) and the central part ( 5 ) by means of these measuring holes ( 3rd ) Lockable pins can be fixed in relation to the guide profile ( 2 ). 6. Device according to one of claims 1 to 5, characterized in that the guide profile ( 2 ) consists of individual, releasably connectable sections ( 2 a, 2 b). 7. Device according to one of claims 1 to 6, characterized in that the measuring stops ( 16 ) for contact with the hollow body to be measured are formed on the probe arms ( 12 ) as rollers, each extending transversely to the guide profile ( 2 ) Axis ( 17 ) are rotatable. 8. The device according to claim 7, characterized in that each probe arm ( 12 ) from a fixed to the foot or head part bearing part ( 13 ) and this continuing and about its transverse to the guide profile ( 2 ) axis ( 14 ) pivotable eccentric part ( 15 ), on which the measuring roller ( 16 ) is mounted so that the distance of its axis of rotation ( 17 ) from the pivot axis ( 14 ) of the probe arm ( 12 ) corresponds to its radius. 9. Device according to one of claims 1 to 8, characterized in that both on the foot part ( 4 ) and on the head part ( 6 ) transverse to the guide profile ( 2 ) and lockable system parts ( 18 ) for contact with the measuring hollow body are arranged.