DE10021306C2 - pipe coupling - Google Patents

Description

The invention relates to a pipe coupling according to the preamble of Claim 1.

A generic pipe coupling is known from EP 0 521 064 B1. she consists from a rotationally symmetrical coupling body with an inner surface that is designed to receive a tube and with an outer surface. To the pipe coupling belongs at least one rotationally symmetrical press ring, which over the outer surface of the Coupling body is axially constrained. At least part of the inner surface of the coupling body on the outer surface of the tube pressed to a metallic To form a seal. On the inner surface of the coupling body is a first tooth medium defined, which bites firmly into the tube when the press ring over the outer surface of the Coupling body is forced. Furthermore, a second is on the inner surface Defined tooth means, which is at a distance from the first tooth means and the insertion side of the Pipe is arranged facing. This second tooth remedy bites minimally into that Pipe on when the press ring is forced over the outer surface of the coupling body becomes. A region is provided lying in the vertical axis of symmetry, which as Flange is formed. On the side facing the flange is on the Inner surface of the coupling body still defines a third tooth means, which also only bites minimally into the pipe if the press ring is over the outer surface of the Coupling body is forced. Is between the first and second tooth means an annular groove is provided which has a bottom and a depth which the Distance of the first tooth means from the floor. The length of the groove is greater than a multiple of the height of the first tooth medium. The coupling body has two Sections, being in the first section facing the insertion side of the tube in the middle area the second tooth medium and in the subsequent second  Section in the beginning area the first tooth medium and in the middle area the third Tooth means are arranged. The transition between the first and second sections is conical. The outer surface of the first section is cylindrical. The The starting area of the second section is cylindrical and has a larger one Diameter than the outer surface of the first section. On this short cylindrical section is followed by a conical outer surface, which in Is inclined towards the flange. At the end of this second section is the outer surface increasingly conical.

A disadvantage of this construction is that the required axial forces for Sliding on the press ring are very large, so that toothless parts of the Coupling body come to rest on the pipe and the further axial displacement hinder. The transition between the first and second sections is like a flat one Hump formed, which are partially displaced axially when the press ring is forced on got to.

A generic pipe coupling is known from DE 198 56 523 C1. it consists of a rotationally symmetrical hollow coupling body with an inner surface that is designed to receive a tube. She still has one rotationally symmetrical hollow press ring on the outer surface of the Coupling body is axially constrained so that at least part of the inner surface of the Coupling body is pushed onto the outer surface of the tube to a pressure tight To form connection. There is a first main tooth on the inner surface of the coupling body defined, which comes to bear on the outer surface of the pipe under high radial pressure, when the press ring is forced over the outer surface of the coupling body. On the The inner surface of the coupling body is arranged at a distance from the first main tooth second main tooth defined, which is under a slightly lower radial pressure on the Outer surface of the pipe comes to rest when the press ring over the outer surface of the Coupling body is forced, the height of the main teeth depends on Outer diameter of the pipe, increasing with increasing outer diameter.

The pipe coupling is still in the vertical plane of symmetry Flange designed, the coupling body five adjoining the flange area has different sections. The outer surfaces of the five sections are cylindrical  and have different outer diameters, whereby after the second and the fourth section is followed by a section with a smaller outer diameter. The Transitions from one section to the next are conical. The main and Support teeth are formed at an acute angle, the main teeth preferably one included angle of 60 ° and the support teeth have an angle of 90 °. The Groove depth in the recesses of the individual sections depends on Outer diameter of the pipe, increasing with increasing outer diameter.

The object of the invention is to provide a pipe coupling which, taking into account the Tolerances with regard to the pipe and the coupling body even for high internal pressures greater than 16 bar ensures a secure metallic seal.

This task is based on the generic term in conjunction with the characteristic ones Features of claim 1 solved. Advantageous further developments are the subject matter of subclaims.

According to the teaching of the invention, the coupling body points to the flange area adjoining three different sections, whose wall thicknesses in a certain Relation to the outer diameter of the tube and their almost cylindrical Outer surfaces on different as seen in the direction of insertion of the tube Outside diameters. The one furthest from the insertion side of the pipe The third section has the first tooth means designed as the first main tooth and the one on it Subsequent second section in the initial area that is formed as the second main tooth second tooth remedy. The transition from the first to the second and from the second to the the third section is curved in cross-section and the complementary one Transition area of the press ring is  arranged in mirror image. In at least one of the three sections Arrangement of a support tooth is provided, preferably each of the three Sections at least one support tooth. The height of the main teeth is dependent from the outside diameter of the pipe, increasing with increasing Outer diameter.

This arrangement has the advantage that the forces that are required to the To be able to push the press ring axially are reduced and the displacement forces in the act essentially only radially and thus the effect of the plastic deformation of the of the main teeth contacted area increase, leading to an increase the axial securing against pushing the pipe out at high pressures.

The arrangement of at least one support tooth stabilizes the respective section, so that the displacement force acts almost completely on the respective main tooth. The support teeth are essentially pointed in cross section with an opening angle of 70-90 degrees. The tip itself is flat with a width of 0.2-0.5 mm.

Further features, advantages and details of the invention result from the following description of shown in a drawing Embodiments. Show it:

Fig. 1 and 2, a hälftigen longitudinal section through a coupling according to the invention formed body

Fig. 3 on an enlarged scale the first main tooth

Fig. 4 on an enlarged scale the second main tooth

Fig. 5 on a larger scale a supporting tooth

Fig. 6 in half longitudinal section an inventive press ring

Fig. 7 in half longitudinal section the coupling body with the press ring attached

Fig. 8 in half longitudinal section, the coupling body with a press ring

In Fig. 1, the left part of the coupling body, a pipe coupling designed according to the invention is shown in a half longitudinal section. The coupling body 1 is characterized by a rotational symmetry with respect to the longitudinal axis 26 and by a mirror image of the vertical axis 27 . The main elements are, on the one hand, the area located in the vertical axis 27 and designed as a flange 2 . The thick-walled flange 2 is followed by a thin-walled sleeve which has three characteristic sections 3 , 10 , 16 . The third section 16 directly adjacent to the flange 2 is provided with a first main tooth 20 on the inner surface in the starting area and the second section 10 adjoining it is provided with a second main tooth 12 also located in the starting area. The first section 3 facing the insertion side of the tube 4 ( FIG. 2) has a support tooth 7 in the central region and an inwardly extending collar 5 in the front region, which is provided with a cylindrical bore 25 . The inner diameter 28 of the bore 25 is almost the same size as the outer diameter 29 of the pipe 4 to be received ( FIG. 2), taking into account the permissible tolerances. Both main teeth 12 , 20 are flanked on the right and left by a supporting tooth 15 , 21 and 8 , 13 , respectively, the supporting tooth 15 , 8 facing the insertion side of the tube 4 ( FIG. 2) lying in another section 10 , 3 .

In the first section 3 , an annular groove 6 , 6 'is provided on the right and left next to the support tooth 7 , the depth of which corresponds to the tooth height of the support tooth 7 . Another annular groove 14 is provided in the second section 10 between the two support teeth 13 , 15 . The third section 16 also has an annular groove 22 which is delimited on the left by a supporting tooth 21 and on the right by a cylindrical bore 23 in the flange 2 . The inserted tube 4 comes to rest on the inner end face 24 of the flange 2 ( FIG. 2). Recesses 11 , 11 'and 19 , 19 ' are provided to the right and left of the main teeth 12 , 20 , respectively. Details of this are shown in FIGS. 3 and 4. The outer transitions 9 , 17 between the first 3 and the second section 10 and between the second 10 and the third section 16 are parabolic in cross section. The flange 2 has an abutment side 18 on the outside, against which the pressing ring 30 shown in FIG. 6 comes to rest.

In Fig. 2 the same coupling body 1 is shown with an inserted tube 4 in a same half longitudinal section. In order not to overload the illustration in FIG. 1, the essential parameters relating to wall thickness, height and diameter are entered in FIG. 2.

The first section 3 defines the wall thickness s ₁ and the depth n _{1 of} the annular groove 6 , 6 ', the depth n ₁ corresponding to the height of the two support teeth 7 , 8 . The predeterminable wall thickness s _{1 of} the first section 3 is dependent on the outer diameter 29 of the tube 4 .

The following applies:

s ₁ = k _a1 × AD _tube + k _a2

with (0.01222 <k _a1 <0.2) and (0.35 mm <k _a2 <2.0 mm)

The following applies to the radial displacement s ₁ 'of the first section 3 of the coupling body 1 by the first section 40 of the pressed compression ring 30 :

s ₁ '= k _a3 × AD _tube + k _a4

with (0 <k _a3 <0.3) and (0 mm <k _a4 <2.0 mm)

s ₁ '= (Di + s ₁ ) - di ₁

di ₁ = inner diameter 44 of the press ring 30 in the first section 40 .
Di = inner diameter 28 of the bore 25 of the collar 5 of the coupling body 1 .

The following applies to the depth n1 of the groove 6 , 6 ′ or depth n2 of the groove 14 and depth n3 of the groove 22 :

n2 = n3 = k _n1 × AD _tube + k _n2

n1 = 0.5.n2

with (0 <k _n1 <0.00376) and (0 mm <k _n2 <0.45 mm).

Furthermore, the section 3 is provided on the insertion side of the tube 4 toward the outside with a bevel of 45 ° over a length of l = 0.5s. ₁

The predeterminable wall thickness s ₂ in the second section is also dependent on the outer diameter 29 of the tube 4 .

The following applies:

S ₂ = s ₂ '+ s ₁

s ₂ '= k _c1 × AD _tube + k _c2

with (0.01564 <k _c1 <0.2) and (0.7 mm <K _c2 <3.0 mm)

Comparable dependencies apply to the predetermined wall thickness s ₃ in the third section 16 .

The following applies:

S ₃ = s ₃ '+ s ₂

S ₃ '= k _e1 × AD _tube + k _e2

with (0.0149 <k _e1 <2.0) and (0.625 mm <k _e2 <3.0 mm)

The heights of the main teeth 12 , 20 are also dependent on the outer diameter 29 of the tube 4 .

The following applies to the first main tooth 20 :

h ₁ = k _h1 × AD _tube + k _h2

with (0.01708 <k _h1 <0.2) and (0.7 mm <k _h2 <5.0 mm)

The following applies to the second main tooth 12 :

h ₂ = k _h3 × AD _tube + k _h4

with (0.01591 <k _h3 <0.2) and (0.35 mm <k _h4 <3.0 mm)

In Fig. 3 in an enlarged scale, of the first main gear 20 is illustrated. It is characterized by a trapezoidal shape seen in cross section with a taper in the direction of the tube 4 . The tooth flanks 31 , 31 'are inclined at an angle α1 with respect to the vertical. This is in the range of 12-15 degrees. The tooth flank 31 , 31 merges into a bevel 33 , 33 'over a radius 32 , 32 ', the radius 32 , 32 'being in a range from 0.5 to 2 mm. The bevels 33 and 33 'form an angle of 45 ° with the pipe surface. The tooth flank 31 , the radius 32 and the bevel 33 delimit the aforementioned recess 19 . The head of the main tooth 20 is flat with a width b ₁ of 0.5 to 2.0 mm depending on the outer diameter 29 of the tube 4 .

In FIG. 4, the conditions for the second main gear 12 are shown. The cross section is also trapezoidal and the tooth flanks 34 , 34 'run at an angle α2 in the range of 12-15 degrees. The tooth head is also flat with a width b ₂ of 0.5 to 2 mm. This width b ₂ is also dependent on the respective outer diameter 29 of the tube 4 . The tooth flanks 34 , 34 'pass over a radius 35 , 35 ' into a bevel 36 , 36 ', the radius 35 , 35 ' being in a range from 0.5 to 2.0 mm. The bevels 36 , 36 'form an angle of 45 ° with the pipe surface. The recess 11 is delimited by the tooth flank 34 , the radius 35 and the bevel 36 .

Fig. 5 shows an example of a support tooth 7 , 8 , 13 , 15 , 21 with its geometric conditions. In cross section, the support tooth is formed at an acute angle, the tooth head being blunt. The width b _n is in the range of 0.2-0.5 mm. Half the opening angle α _n is in the range between 35-45 degrees.

In Fig. 6 in a longitudinal section, a hälftigen according to the invention formed press ring 30 is shown, whose inner contour is adapted to the outer contour of the joint body 1. The press ring 30 consists of a thick-walled cylindrical base body 37 , which jumps on one side into a thin-walled cylindrical sleeve section 38 . The base body 37 is provided on the inside with a step-like inner contour. Comparable to the coupling body 1 , three different sections can be distinguished on the inside of the base body 37 of the press ring 30 . When viewed from the insertion side of the pipe to be connected ( FIG. 2), a first cylindrical section 40 extends from the front side 39 . This first section 40 is followed by a second section 42, likewise of cylindrical design, with a transition region 41 , which is conical in this exemplary embodiment. The cone rises so that the inner diameter 43 of the second section 42 is larger than the inner section 44 of the first section 40 . A third section 46, which is also cylindrical, adjoins the second with a transition area 45 . The transition 45 from the second section 42 to the third section 46 is curved. The third section 46 ends on the inside end face 48 of the base body 37 with an intermediate transition area 49 , which also has a curved contour. The inside diameter 50 of the sleeve section 38 is adapted to the outside diameter of the flange 2 of the coupling body 1 ( FIG. 2). The length 51 of the sleeve section 38 corresponds approximately to the length of the flange 2 of the coupling body 1 .

The interaction of press ring 30 and coupling body 1 is shown in the two following FIGS. 7 and 8.

FIG. 7 shows the state in which the press ring 30 is placed on the coupling body 1 and in FIG. 8 the final state, ie the complete imposition of the press ring 30 on the coupling body 1, is shown.

In Fig. 7 it can be seen that the pressing ring of the press ring 30 is associated with playing the first portion 3 of the joint body 1 is in the mounted state, the third portion 46 with clearance 30 to the second section 10 and the second portion 42. The first section 40 of the press ring 30 has no contact with the coupling body 1 when it is in the attached state.

The final state is shown in FIG. 8. The surfaces s ₁ ', s ₂ ' and s ₃ 'are intended to illustrate the radial displacement of the sections 3 , 10 , 16 of the coupling body 1 which is caused by the constraint. Due to the radial displacement, the three sections 3 , 10 , 16 of the coupling body 1 are pressed radially against the outer surface 52 of the tube 4, and in particular the main teeth 12 , 20 dig into the outer surface 52 of the tube. The contact points plasticized when buried then form the axial securing means and the seal for the pipe coupling designed according to the invention.

LIST OF REFERENCE NUMBERS

1

clutch body

2

flange

3

first section coupling body

4

pipe

5

collar

6

.

6

'' annular groove

7

.

8th

supporting tooth

9

Transition area first / second section

10

second section coupling body

11

.

11

'Recess

12

second main tooth

13

.

15

supporting tooth

14

annular groove

16

third section clutch body

17

Transitional area second / third section

18

outer stop flange (press ring)

19

.

19

'Recess

20

first main tooth

21

supporting tooth

22

annular groove

23

cylindrical bore (inside)

24

inner end face flange (tube)

25

cylindrical bore (end face)

26

longitudinal axis

27

vertical axis

28

Inner diameter bore

25

29

Outside diameter tube

4

30

press ring

31

.

31

'Flank of the first main tooth

20

32

.

32

'Radius of the first main tooth

20

33

.

33

'Sloping recess

19

.

19

'

34

.

34

'Tooth flank second main tooth

12

35

.

35

'Second main tooth radius

12

36

.

36

'Sloping recess

11

.

11

'

37

Base body press ring

38

sleeve section

39

front

40

First section press ring

41

Transition area first / second section

42

Second section press ring

43

Inner diameter of the second section

44

Inside diameter of the first section

45

Transitional area second / third section

46

Third section press ring

47

Third section inner diameter

48

face

49

Transitional area third section

50

Inner diameter sleeve section

51

Length of the sleeve section

52

External surface of the pipe

Claims (10)

1. Pipe coupling consisting of
a metallic, rotationally symmetrical hollow coupling body with an inner surface which is designed to receive a metallic tube and with an outer surface,
at least one rotationally symmetrical hollow press ring which can be axially forced over the outer surface of the coupling body, so that at least a part of the inner surface of the coupling body is pressed onto the outer surface of the tube in order to form a metallic seal,
wherein the inner surface of the coupling body defines a first tooth means that comes to bear under great radial pressure on the outer surface of the tube when the press ring is forced over the outer surface of the coupling body,
the inner surface defining a second tooth means arranged at a distance from the first, which comes to bear on the outer surface of the tube under a slightly lower radial pressure when the press ring is forced over the outer surface of the coupling body and the height of the tooth means is dependent on the outer diameter of the tube, and that with increasing outside diameter,
an area of the coupling body which is in the form of a flange and lies in the vertical axis of symmetry,
the coupling body having a plurality of different sections adjoining the flange region with cylindrical outer surfaces and different outer diameters,
characterized by
that the coupling body ( 1 ) on the flange region ( 2 ) then has three different sections ( 3 , 10 , 16 ), the wall thicknesses (s ₁ , s ₂ , s ₃ ) of which in a certain ratio to the outside diameter ( 28 ) of the tube ( 4 ) are provided and their nearly cylindrical outer surfaces are located on different as viewed in the insertion direction of the pipe (4), increasing outer diameters, wherein the portion (16) furthest from the insertion side of the tube (4), third in the initial region which as the first main gear (20 ) formed first tooth means and the adjoining second section ( 10 ) in the starting area has the second tooth means designed as second main tooth ( 12 ) and the external transition ( 9 , 17 ) from the first ( 3 ) to the second ( 10 ) and from the second ( 10 ) to the third ( 16 ) section, seen in cross-section, and the transition regions ( 41 , 45 ) of the press ring ( 30 ) that interact with it are designed to match and in each of the three sections ( 3 , 10 , 16 ) the arrangement of at least one supporting tooth ( 7 , 13 , 21 ) is provided. 2. Pipe coupling according to claim 1, characterized in that the first section ( 3 ) has two support teeth ( 7 , 8 ). 3. Pipe coupling according to claim 1, characterized in that the second section ( 10 ) has two support teeth ( 13 , 15 ). 4. Pipe coupling according to claim 2 and 3, characterized in that a supporting tooth ( 7 , 13 ) in the central region of the respective section ( 3 , 10 ) and the second supporting tooth ( 8 , 15 ) in the vicinity of the transition region ( 9 , 17 ) to the subsequent section ( 10 , 16 ) is arranged. 5. Pipe coupling according to one of claims 1-4, characterized in that the end region of the coupling body ( 1 ) is designed as an inwardly directed collar ( 5 ) whose cylindrical bore ( 25 ) has a diameter ( 28 ) which is approximately the same is the outer diameter ( 29 ) of the pipe ( 4 ) to be accommodated. 6. Pipe coupling according to one of claims 1-5, characterized in that between the support teeth ( 7 , 8 , 13 , 15 , 21 ) or the collar ( 5 ) lying annular grooves ( 6 , 6 ', 14 , 22 ) have a depth which is dependent on the outside diameter ( 29 ) of the tube ( 4 ) and increases with increasing outside diameter, the two annular grooves ( 6 , 6 ') lying in the first section ( 3 ) having the same depth, but is less than the annular groove ( 14 , 22 ) in the second ( 10 ) and in the third section ( 16 ). 7. Pipe coupling according to one of claims 1-6, characterized in that the first ( 20 ) and the second ( 12 ) main tooth are trapezoidal in cross-section with a taper towards the tube ( 4 ) and a flat tooth head. 8. Pipe coupling according to one of claims 1-7, characterized in that a recess ( 11 , 11 '; 19 , 19 ') is defined on the right and left of the respective main tooth ( 12 , 20 ), which is limited on the inside by the tooth flank ( 31 , 3134 , 34 ') and on the outside by a bevel ( 33 , 33 ', 36 , 36 ') which is flatter than the tooth flank and which merges seamlessly into the flank of the respective adjacent supporting tooth ( 8 , 13 , 15 , 21 ), the transition from the tooth flank ( 31 , 31 ', 34 , 34 ') to the bevel 33 , 33 ', 36 , 36 ') is greatly rounded. 9. Pipe coupling according to one of claims 1-6, characterized in that the support teeth ( 7 , 8 , 13 , 15 , 21 ) seen in cross section are all formed with an acute angle with an opening angle in the range of 70-90 degrees, the tip of the Support tooth ( 7 , 8 , 13 , 15 , 21 ) has a flat. 10. Pipe coupling according to claim 9 characterized, that the width of the flat is in the range of 0.2-0.5 mm.