DE9102796U1 - Device for measuring external and/or internal dimensions of hollow bodies - Google Patents

Description

Description:

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

Concrete or reinforced concrete pipes for pipelines are usually manufactured with a socket end and a spigot end, which is inserted into the socket end of an adjacent pipe to create a pipe connection with the interposition of a sealing ring made of elastic material. Pipes of this type are usually manufactured with nominal diameters of up to about 4 m. In order to be able to check production and to control and guarantee the functional range of the sealing ring, it is necessary to determine the sealing range precisely, namely the external diameter at the spigot end and the internal diameter at the socket end. Since the functional range of the sealing rings is very small, it is necessary to carry out very precise measurements.

Commercially available measuring devices used to measure the dimensions of concrete and reinforced concrete pipes only have an accuracy of +/- 1.5 mm and are unsuitable for future requirements. Generally applicable measuring devices, such as calipers, are available in a wide variety on the market, but cannot be used for the measuring tasks to be carried out here because they are too difficult to handle.

Against this background, the invention is based on the object of creating a measuring device with which the external and internal dimensions of hollow bodies, in particular of pipes made of concrete or reinforced concrete, can be measured in a simple manner with high accuracy.

This object is achieved according to the invention by a

Device with the features of the characterizing part of claim 1.

Advantageous further training results from the subclaims.

The advantage of the invention is primarily seen in the fact that the simple and clearly structured device enables indirect length measurement, i.e. the actual measuring device does not come into contact with the object to be measured; stresses on a slim measuring sensor transverse to its longitudinal axis, which could affect the measurement result, therefore do not occur. With the measuring device according to the invention, a measurement accuracy of +/- 0.1 mm can be achieved.

The large dimensions of the bodies to be measured and the high measurement accuracy are managed with the measuring device according to the invention by precisely measuring only the distance between the middle part, which can be fixed to the guide profile, and the head part, which can be moved relative to it. The determination of the respective position of the middle part results from the - known - position of the recess, opposite which the middle part is fixed. A further simplification of managing large dimensions results from the fact that the guide profile can also consist of individual sections that can be detachably connected to one another.

The invention is explained in more detail below using an embodiment shown in the drawing. It shows

Fig. 1 shows a measuring device according to the invention in side view in application for measuring an inner diameter,

Fig. 2 the measuring device shown in Fig. 1 in use for measuring an outside diameter,

Fig. 3 a front view of the measuring device,

Fig. 4 shows the essential parts of the measuring device according to the invention in a 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 representations in Figs. 1 to 3, of a guide profile 2, which can optionally also be composed of individual sections 2a, 2b and which is provided along a surface line with a number of recesses 3 arranged at equal distances a from one another. A tube in which the recesses are holes can serve as the guide profile 2; however, it can also be a rod or a rail, which enable 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 to the guide profile 2 by pins, which can be snapped into a recess 3. In order to ensure the necessary low tolerances, the holes in the recesses 3 are very precise and the pins (not shown) are conical.

The measuring device 1 is used in Fig. 1 to measure the inner diameter in the area of the socket 7 of a reinforced concrete pipe 8, in the example in Fig. 2 to measure the outer diameter of the spigot end 9 of a pipe 8. The design of the measuring device and its function are

described below with reference to Figs. 4 and 5.

The foot part 4 sits firmly but can be removed on the guide profile 2. It consists of a sleeve-like guide body 10 on which there is an actuating device 11, e.g. a spring-loaded bolt for the pin engaging in one of the recesses 3, by means of which the foot part can be fixed on the guide profile 2. A probe arm 12 is attached to the side of the guide body 10, which consists of a bearing part 13 fastened to the guide body 10 and an eccentric part 15 which continues this and can pivot about an axis 14 running transversely to the guide profile 2. A measuring stop 16 is attached to the outer end of the eccentric part 15 for contact with the object to be measured. The measuring stop 16 consists of a measuring roller which can be rotated about an axis 17. The axis 17 runs parallel to the axis 14 and is at a distance from it that corresponds to the radius of the measuring roller. By pivoting the eccentric part 15 relative to the bearing part 13, measurements of external and internal diameters can be carried out with reference to the axis 14.

On the guide body 10, above and below the probe arm 12, there are approximately U-shaped support parts 18 that can be extended transversely to the guide profile and secured by means of locking screws 19. Using these support parts 18, which can also be provided with a scale, the position of a measuring point from the end of a pipe can be made adjustable for both external and internal measurements.

The head part 6, like the foot part 4, also consists of a sleeve-like guide body 20, which is arranged so that it can move easily, but largely without play, on the guide profile 2. The guide body 20 of the head part 6 is also provided 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. A caliper 21 is attached to the head part 6 as a measuring device.
which consists of a measuring rod 22 and a dial gauge.

The measuring rod 22 is fixed with its lower end 24 to the
Middle part 5, which also consists of a
sleeve-like guide body 25 and can be fixed relative to the guide profile 2 by means of an actuating device 26 for a pin. The head part 6, which can be moved relative to the middle part 5, is secured against twisting and
Falling out is secured by a sliding tube 27, which
on the one hand is fastened 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.

On the head part 6 is a handle 30 with a
Locking device 31 is provided, which by means of a
spring-loaded handle part 32 and a clamping fixation of the head part against the
Guide profile 2 enables.

In the measuring device according to the invention, the distance between

the - fixed - middle part 5 and the - movable - head part 6. The caliper 21 is not moved directly on the object to be measured, so that stresses transverse to its longitudinal axis do not occur. This also prevents wear and tear and possible damage to the caliper. The caliper 21 can be equipped with a microprocessor that can programmatically store and print out all the data to be measured; length changes due to
Temperature differences can easily
The contact with the object to be measured

Body is measured exclusively via the hardened measuring rollers 16.

To carry out a measurement, for example an internal measurement according to Fig. 1, proceed as follows: First, the position of the measuring point on the sleeve 7 is set using 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 into the caliper. It corresponds to the total measurement of the distances between the recesses plus the fixed measurement between the middle part 5 and the head part 6 according to the position of the measuring rollers 16 for internal and external measurements. 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 measurement is determined by pendulum movements, which can be read directly on the dial gauge 23; the length read is the actual measurement.

A second measurement option is to measure the exact Diameter or the exact length (nominal dimension) and

to measure the deviations from zero using the caliper 21.

Claims (9)

Protection claims: 1. Device for measuring external and/or internal dimensions of hollow bodies, in particular of pipes made of concrete or reinforced concrete, characterized in that a base part (4) provided with a probe arm (12) is fixedly arranged on a guide profile (2) and a head part (6) also provided with a probe arm (12) is displaceable relative to the base part (4), the head part (6) being connected to a measuring device for determining the distance between measuring stops (16) provided on the probe arms (12) - intended for contact with the hollow body to be measured. 2. Device according to claim 1, characterized in that the measuring device is a caliper (21) with a measuring rod (22) running parallel to the guide profile (2), which can be fixed at a position of a certain length relative to the guide profile (2) and along which a dial gauge (23) arranged on the head part (6) can be moved. 3. Device according to claim 2, characterized in that the measuring rod (22) is fastened with one end to a middle part (5) arranged between the foot part (4) and the head part (6) on the guide profile (2), which middle part can be moved along the guide profile (2) and can be fixed relative to it at points determined in terms of length. 4. Device according to one of claims 1 to 3, characterized in that the head part (6) can be fixed in a clamping manner relative to the guide profile (2). 5. Device according to one of claims 1 to 4, characterized in that recesses (3) are provided along the guide profile (2) at certain distances from one another. and that the base part (4) and the middle part (5) are secured against the
Leadership Professional I (2) can be fixed. 6. Device according to one of claims 1 to 5, characterized in that the guide profile (2) consists of individual,
detachably connectable sections (2a, 2b)
consists. 7. Device according to one of claims 1 to 6, characterized in that the contact surfaces for the
Hollow body specific measuring stops (16) on the probe arms
(12) are designed as rollers, each of which is rotatable about an axis (17) running transversely to the guide profile (2). 8. Device according to claim 7, characterized in
that each probe arm (12) consists of a bearing part (13) attached to the foot or head part and a
and about whose axis (14) running transversely to the guide profile (2) there is an eccentric part (15) pivotable, on which the
Measuring roller (16) is mounted so that the distance between its
Rotation axis (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) transversely to the guide profile (2) extending and
lockable system parts (18) for attachment to the
measuring hollow bodies are arranged.