DE10045849A1 - Method for bending a pipe for use in a Coriolis mass flowmeter, in which a flexible support body is placed in the pipe which is then filled with wax, etc. prior to bending in a mold, so that more accurate results are achieved - Google Patents

Abstract

Method in which a pipe of length (L) is bent between a mold. Prior to molding a flexible support body is placed inside the pipe and one end of the pipe closed. The pipe is then filled with a liquid, which is then allowed to harden. The pipe is then placed in the mold which is closed to give the pipe the desired shape. After molding the pipe is heated to remove the liquid and the support is withdrawn. The support body is a spiral spring of smaller outer diameter than the inner diameter of the pipe and has a stop on one end that is used to close the pipe before it is filled with a fluid such as wax, oil, etc.

Description

The invention relates to a method for bending at least one measuring tube of a Coriolis Mass flow sensor.

Such mass flow sensors can be based on the Shape of the measuring tube or tubes in two classes divide, namely mass flow sensor with at least a straight measuring tube and those with at least one curved measuring tube. With mass flow sensors with curved measuring tubes are those of the invention Interest whose measuring tubes are bent in one plane, d. H. where the respective axis of the measuring tubes in this plane lie.

Such measuring tubes are e.g. B. U-shaped (see. The US-A 53 94 758) or only bent very flat (see US-A 57 96 011) or according to the older EP application 00 11 0091.6 V-shaped bent.

Such measuring tubes bent in one plane, the one Have an inside and an outside diameter into the desired shape using a two-part mold bend, which is adapted to the desired shape.

Pipes to be bent are usually used for this purpose be heated with an incompressible as possible Filler that ensures that the shape of the Cross-section, usually a corresponding circular Cross-section, preserved as unchanged as possible after bending stayed.  

It has been shown that this usual procedure in Bending measuring tubes for Coriolis mass flow sensors not with a single incompressible filler alone sufficient to achieve the required high mechanical / - geometric accuracy of the bend and the curved To achieve measuring tubes.

It is also for reasons of manufacturing rationalization absolutely necessary that the curved measuring tubes no longer processed with regard to their length, esp. must be cut. So the length of the straight, unbent measuring tube for a production batch can be specified, and have the curved measuring tubes then all a uniform, shortened accordingly Final length.

To solve these problems, the invention therefore consists in a method for bending a measuring tube for a Coriolis mass flow sensor into a desired shape by means of a pipe piece of a predetermined length and by means of a two-part compression mold, which has an inner diameter and an outer diameter measuring tube and the desired shape is adjusted, with the following steps:

• - a flexible support body is inserted into the pipe section,
• - So attached in a first end of the pipe section is that the end is closed, and
• - of which a maximum outer diameter smaller than that Is the inside diameter of the pipe section,
• - The pipe section is filled with a liquid and then let them solidify completely,
• - that with the support body and with the solidified Liquid-filled pipe section is opened in the Laid mold,
• - The mold is closed and thereby the pipe section bent into the desired shape,  
• - The mold is opened and the bent pipe section taken, and
• - the solidified liquid is allowed to melt and then the support body and the molten liquid removed from the bent pipe section.

According to a first preferred embodiment of the invention a liquid is used that is at a temperature solidified below 280 ° C.

According to a first preferred further embodiment of which molten bismuth is used; in second another preferred embodiment, the liquid solidifies at a temperature below 50 ° C.

According to further preferred embodiments of this is used as Liquid wood metal or an aqueous solution, esp. Water itself, or a wax or oil used.

According to a first preferred embodiment of the invention a coil spring is used as a support body, the preferably centered in the pipe section by means of spacer rings becomes; In both cases, a spiral spring is preferred Used turns that lie together.

It has surprisingly been shown that the sharing a liquid with the Support body a highly precise bending of measuring tubes from Coriolis mass flow sensors.

Since the support body according to a feature of the invention maximum diameter that is smaller than the inside Diameter of the measuring tube, the support body can be after Bends are not easily pulled out of the measuring tube, after the solidified liquid has become liquid again is.  

The high accuracy after bending, that is, completely of it unaffected cross-section of the measuring tube in the bending area, According to the inventors, that the solidified liquid as the filler Major part of this high accuracy is that however the support body solidified a thin layer Liquid carries between the inner wall of the measuring tube and the support body, and that this is the rest Contributes to high accuracy.

The invention is now based on the figures of the drawing explained in more detail in the successive stages of a Method according to the invention as an embodiment is shown. Functionally identical parts are in different figures with the same reference numerals provided, but only then in subsequent figures repeated if it makes sense.

Fig. 1 shows in plan view a, to be bent tube piece

Fig. 2 shows in plan view a support body,

Fig. 3 shows in plan view the pipe section of FIG. 1 with the inserted supporting body of Fig. 2,

FIG. 4 shows a top view of the pipe section of FIG. 3, into which a liquid is filled,

Fig. 5 shows in schematic plan view of an opened mold,

Fig. 6 shows in plan view schematically illustrating the open mold of FIG. 5 with the solidified liquid and the supporting body containing the inserted pipe section,

Fig. 7 shows a top view schematically of the closed mold of Fig. 6 and the tube piece bent by closing, and

FIG. 8 shows a top view schematically of the press mold which has been opened again to take out the bent tube piece.

In Fig. 1, a tube section 1 is schematically shown in plan view, which has been cut off from a straight tube rod with a desired length L, not shown. The length L results in a simple manner from the length of the bent tube piece to be used as the measuring tube, which is desired after the bending. The pipe section 1 has an inner diameter d1 and is usually made of a stainless steel.

In Fig. 2 in top view a flexible support body 2 is shown, which is longer than the length L of the pipe section 1 of Fig. 1. The support body 2 has a maximum outer diameter d2 which is smaller than the inner diameter d1 of the tubular piece 1 is. At one end of the support body 2 , a closure 21 is screwed, which is suitable for closing the pipe section 1 .

However, other forms of support bodies are also possible; these only have to be able to bend the Pipe piece to follow and their cross-sectional shape as well the distance in the not yet bent state between the inner wall of the pipe section and the support body maintain.

In Fig. 3, the pipe section 1 is shown in plan view after the support body 2 has been inserted into it. The closure 21 is now located at one end of the pipe section 1 , and at its other end an end of the support body 2 opposite the end carrying the closure 21 protrudes because of its greater length than the length L of the pipe section 1 . Thus, the pipe section 1 has been closed liquid-tight at the end mentioned.

In Fig. 4, the pipe section is shown again with the support body 2 inserted; However, the arrow now shows that the space between the tube piece and the support body and, if this is hollow, it itself has been filled with a liquid fx. The liquid fx is then allowed to solidify completely. In this state, the pipe section is designated 1 '.

In FIGS. 3 and 4 is shown by dashed that can be centered in a preferred embodiment of the support body 2 by means of spacer rings 22 in the pipe pieces 1.

In Figs. 2 to 4, a spiral spring is shown in each case as a preferred support body 2; their turns are preferably against each other.

Any liquid whose solidification temperature is a few hundred degrees Celsius lower than the melting temperature of the pipe section 1 and the support body 2 is suitable as the liquid fx. Metals with a low melting point in this sense, such as. B. said bismuth or said wood metal, but also aqueous solutions, especially water itself, or organic compounds, such as. B. waxes or oils can be used.

In Fig. 5, an open mold 3 is schematically shown in plan view, which comprises an upper part 31 and a lower part 32 . The mold 3 is adapted to the outer diameter and the desired shape of the bent pipe section 1 .

For this purpose, there is a first groove 311 in the upper part 31 and a second groove 321 in the lower part 32 . Both channels have a cross section in the form of a semicircular surface, the diameter of which is equal to the outer diameter of the pipe section 1 . The cross section of the upper part 31 , when the mold is closed, supplements the cross section of the lower part 32 to form a full circle surface. A stop 33 for the pipe sections 1 'to be bent is attached to the lower part.

The two grooves 311 , 321 of the compression mold 3 and thus the desired shape of the bent pipe section contain a plane in which an axis of the bent pipe section lies and are V-shaped in this plane.

FIG. 6 shows a schematic plan view of the opened mold of FIG. 5, on the lower part of which the pipe section 1 ′ of FIG. 4 containing the supporting body 2 and the solidified liquid fx is inserted up to the stop 33 .

FIG. 7 shows a schematic top view of the closed mold 3 of FIG. 6 with the tube section bent by closing, which is now designated 1 ". It can be seen that, as already explained above, the problems on which the invention is based was mentioned, the bent pipe section 1 "by bending has become shorter than the length L of the straight pipe section 1 .

Finally, FIG. 8 schematically shows a top view of the opened mold 3 , from which the bent pipe section 1 "is about to be removed. The solidified liquid is allowed to melt and then the support body 2 and the liquid fx are removed, which is caused by the The bent pipe section 1 "can now be used as a measuring pipe without any processing.

Claims (10)

1. A method for bending a measuring tube for a Coriolis mass flow sensor into a desired shape by means of a pipe section ( 1 ) of a predetermined length (L) and by means of a two-part press mold ( 3 ) which has an inside diameter (d1) and an outside -Diameter measuring tube and the desired shape is adjusted with the following steps:
a flexible support body ( 2 ) is inserted into the pipe section (I),
which is fastened in a first end of the tube piece in such a way that the end is closed, and
of which a maximum outside diameter (d2) is smaller than the inside diameter (d1) of the pipe section,
the pipe section ( 1 ) is filled with a liquid (fx) and then allowed to solidify completely,
the pipe section ( 1 ') filled with the support body and with the solidified liquid is placed in the opened mold ( 3 ),
the mold is closed and the pipe section is bent into the desired shape,
the mold is opened and the bent pipe section ( 1 ") removed, and
the solidified liquid is allowed to melt and then the support body ( 2 ) and the melted liquid (fx) are removed from the bent pipe section ( 1 "). 2. The method according to claim 1, wherein a liquid (fx) is used at a temperature less than 280 ° C stiffens.   3. The method according to claim 2, wherein the liquid (fx) molten bismuth is used. 4. The method of claim 2, wherein a liquid (fx) is used at a temperature less than 50 ° C stiffens. 5. The method according to claim 4, wherein the liquid (fx) molten wood metal is used. 6. The method according to claim 4, in which the liquid (fx) an aqueous solution, especially water, is used. 7. The method according to claim 4, wherein the liquid (fx) a wax or an oil is used. 8. The method according to claim 1, wherein a spiral spring is used as the support body ( 2 ). 9. The method according to claim 8, wherein the coil spring is centered by means of spacer rings ( 22 ) in the pipe section ( 2 ). 10. The method of claim 8, wherein a relaxed Coil spring with turns that are used together lie.