DE202008016440U1 - hose coupling - Google Patents

Abstract

Hose coupling (10), in particular for high-pressure hydraulic lines or high-pressure hydraulic lines,
- With a high-pressure hose (11), in which between two coats (12, 14) a metal insert (13) is arranged from a wire mesh or from at least one wire spiral winding,
- With a tubular coupling element (30) which is connectable at the front end (37) to a valve and that at the other end a hose nipple (31) for receiving the high-pressure hose (11),
- With a deformable under radial pressure press fitting (20),
- wherein the connection area for the high-pressure hose (11) in the hose coupling (10) comprises two areas, namely a front securing area (A), and an axially adjacent sealing area (B), wherein in the securing area (A) of the coats ( 12, 14) liberated metal insert (13) and wherein in the sealing region (B) of the outer shell (12) freed high-pressure hose (11) between the hose nipple (31) and press fitting (20) is pressed,
- Wherein the press fitting (20) in the sealing area (B) radially to the high pressure hose ...

Description

The The invention relates to a hose coupling, in particular for use for hydraulic hose lines, the high and highest pressures need to record.

Hose couplings for high pressure hydraulic lines, for example, in manufacturing machines or in the motion hydraulics are known. In these hydraulic drives, the hydraulic medium is preferably transmitted by means of flexible hoses. A universally applicable hose coupling for different types of hose is out EP 1 744 099 A1 known. This UVOS hose coupling comprises a coupling element with a hose nipple, onto which the end of a hydraulic hose is pushed and pressed onto the coupling element by means of a press fitting encompassing the hose. This known hose coupling has a press fitting, which has radially extending to the hose and directed to the hose as projections formed deformations which engage in the case of mounting in the hose. In the area of these deformations recesses are provided on the outside of the press holders. These recesses make it possible to take up material when pressing the UVOS hose coupling, so that during compression the press mount does not expand in the axial direction. By pressing a tight connection between the hydraulic hose and the coupling element is achieved. These hose couplings can be safely used at pressures of up to 100 bar with large nominal diameters, ie with large internal diameters of the hydraulic hoses. For small diameters, these known hose couplings can be used up to pressures of 500 to 600 bar. For the field of heavy hydraulics, however, this hose coupling can not be used, since the press fitting is not designed for the tensile loads occurring there.

It is known in the field of heavy hydraulics hydraulic piping for which there are versatile connection fittings which ensure a secure and tight connection. The high pressures, in particular of some 100 bar to achieve high closing or pressing forces, for example in plastic injection machines, presses or large construction machinery, needed. However, the use of hydraulic pipes has the disadvantage that they can only be laid rigidly, which in complicated constructions multiple bends and the Use of different fittings has resulted. this leads to to pressure losses, so that, for example, to move a digger claw Only 10% of the energy is available, originally was generated by the engine. This low efficiency is not satisfactory.

task The invention is therefore a hose coupling for the Heavy hydraulic to provide, at a maximum Volume flow is achievable, so that the energy efficiency of such Hydraulic system improved. The invention is further the The object is to provide a hose coupling available the very high pressures and in particular also pulse-like pressure peaks can reliably absorb.

These The object is achieved by a hose coupling solved with the features of claim 1. This hose coupling ensures a tight and tight connection of a high-pressure hose on a tubular coupling element. The connection area for the high-pressure hose in the invention Hose coupling comprises two areas, namely a front Secured area and one in the axial direction Sealing area, whereby the high-pressure hose in the securing area and positive fit and thus tensile strength between the hose nipple the coupling element and the hydraulic hose encompassing Pressed press is pressed.

The high pressure hose contains in a known manner a metal insert, which is necessary for high pressure applications. This metal insert may consist of a wire mesh or of at least one layer of spirally wound wires. High-pressure hoses with at least three layers of such spiral wire windings are used in particular for high-pressure lines. To protect the metal insert, the high-pressure hoses have an inner and outer sheath made of plastic, in particular elastomeric plastics, such as rubber. These plastic shells protect the metal insert from media influences. The smooth inner jacket also ensures an unimpeded flow during transport of the hydraulic medium. As from the document EP 1 744 090 A1 As is known, the high-pressure hose is pushed onto a hose nipple of a coupling element and held on the coupling element by means of a pressed-on press fitting. The tight connection between the coupling element and the high-pressure hose is achieved in the same way that the press fitting radially to the high-pressure hose and directed to the high-pressure hose formed as projections wall deformations and recesses are provided on the outside of the press frame in the wall deformations, which during radial compression Material of the press frame can absorb, whereby a change in length of the press frame is reduced during pressing. The depressions thus act as compensation zones. The pressing leads to the attachment case to any change in length of the press frame, since the Ma material of the wall deformations can recede into the depression. In an overpressure, a counterforce is generated by the pressing force, which causes the material of the press frame in the depression but also at the end of the press frame in the longitudinal direction and by adjusting the heights of wall deformation evades. An incidence of the hose nipple, ie a reduction in the clear width of the hose nipple is not, at least not up to a certain degree of overpressing. The externally visible axial extension of the press fitting can be considered in the hose coupling as a measure of the sufficient compression and tight connection.

In the axial direction in front of the sealing area a securing area is provided in this hose coupling according to the invention, which ensure a tear-out of the hose under tensile load. Anti-tear devices are known from Interlok hose couplings. In these known Ausreißsicherungen a radially projecting bead is provided on the inside of the press fitting, which presses the metal insert of a hose in an annular groove on the hose nipple in the case of attachment. Such a positive and positive connection between the metallic press fitting, the metallic hose nipple and the metallic insert of the hose, which is freed from its inner and outer sheath in this area, leads to a secure and tensile connection of the hose to the corresponding fitting. However, such a tear-out can not be according to the known hose coupling EP 1 744 090 A1 transferred because a radially projecting on the inside of the press-fitting bead comprises so much material that is to be expected during compression with a change in length of the press fitting, which negates the benefits of the known hose coupling. Furthermore, the press setting would stand out from the hydraulic hose with strong pressing forces in the sealing area.

at the hose coupling according to the invention is in Secured area provided at least one wall deformation. These Wall deformation of the press frame involves more material than wall deformation in the sealing area. Preferably, the wall deformation in the security area is greater dimensioned as the wall deformations in the sealing area. The wall deformation can optionally have a larger cross-section, d. H. extend deeper into the interior of the press version, one own or latitude height or but another cross section is chosen, the more Material includes. In a preferred embodiment for the press version in the security area a larger Wall thickness selected as in the sealing area, being in the whole Securing area and also in the sealing area one evenly thick wall of the press frame is provided.

A designed with a fuse area and a sealing area Press fitting leads during pressing, d. H. the application a uniformly acting on the press frame radial pressure to ensure that the high pressure hose on the one hand d. H. tensile strength and on the other hand tightly connected to the coupling element becomes. The high-pressure hose, which is pushed onto the hose nipple, is in the security area of both its interior and its Outer jacket freed, so that only metallic Components at the connection between press fitting, hose and coupling element are involved and a breakaway for the Ensure high-pressure hose. The metal insert is during pressing through the wall deformation of the press frame into a groove-shaped bulge of the hose nipple pressed and a positive and non-positive connection obtained. In the sealing area the high-pressure hose is freed from the outer jacket, so that in the case of attachment, the wall deformations of the press frame in the Metal insert can intervene. The inner jacket of the high pressure hose sits firmly on the hose nipple supporting with structuring may be provided in the form of projecting ribs that extend into the Inner jacket of the high-pressure hose for a better fit Push.

Also if, during radial compression, the interference fit is uniform is charged in the two different areas of the Pressing a different counterforce generated, so is in the Fuse range with a higher resistance expected because on the one hand more material is deformed and on the other hand exclusively Metallic materials are involved in the formation of compounds. The differently dimensioned wall deformations in the securing and sealing area now allows the press mount on these different resistances in both areas can respond according to their tasks. It becomes one secure connection as a tear-out for the Tube achieved in the security area and on the other hand, a dense Connection in the sealing area. The press version raises even with strong Press forces do not depend on the hydraulic hose. The press takes the radial forces acting on them evenly on, so that the pressing does not cause a hose nipple leads, which reduce the clear width of the hydraulic line would.

In addition, in an advantageous embodiment of the hose coupling can be increased by an appropriate choice of material for the press fitting and the coupling element of the inner diameter of the hose nipple. In known hose couplings is a both for the press fitting and for the coupling element Steel alloy, for example, free cutting steel used. This material has the advantage that by alloying phosphorus, sulfur or lead a material is obtained which can be easily machined by machining processes, such as turning, milling or drilling. Other materials can also be used if they meet the requirements of a fitting. These requirements are as load profiles in the relevant standards EN 856 or SAEJ 517 100 R 15. If a hose coupling is used with a press fitting made of known material and a material with higher tensile strength and elongation is selected for the coupling element, then the material of the hose nipple can be better distributed during pressing. In one embodiment, a press fit was made of free cutting steel and a steel alloy with chromium and molybdenum additives was used for the coupling element. The addition of chromium in particular, but also of molybdenum, this steel alloy has an increased strength and yield strength, whereby the tensile strength is significantly increased. In the coupling element of such a material, the hose nipple may have a smaller wall thickness, whereby an enlargement of the clear cross-section, ie the inner diameter of the coupling element, can be achieved when using the same high-pressure hose. The requirements for such a hose coupling for high-pressure applications with up to 20% increased clear cross-section is fulfilled by the hose coupling. Thus, in such a hose coupling according to the invention a larger volume flow of hydraulic medium is possible, which leads to an improvement in energy efficiency in the overall device.

In the drawing is the subject invention set forth in an embodiment and indeed shows

1 a hose coupling according to the invention before pressing and

2 the hose coupling according to the invention 1 after pressing.

In 1 is a hose coupling according to the invention 10 shown. It consists of the coupling element 30 and a press version 20 , To this hose coupling 10 is a high pressure hose 11 connected. This high pressure hose 11 is with an outer coat 12 , preferably a rubber coat, provided. Likewise, the material of the inner shell 14 from a rubber material. The outer coat 12 and the inner coat 14 cover a metal insert 13 , which in this example consists of three layers of helically wound wires. Such a high pressure hose 11 is suitable for very high pressures and high impulse loads. As in 1 to see is the high pressure hose 11 peeled in the front area inside and outside, ie has in this front area, which is referred to as security area A, no outer rubber jacket 12 and no inner rubber coat 14 , In the adjoining sealing region B is the high-pressure hose 11 from his outer coat 12 freed. The thus prepared high pressure hose 11 comes together with a high pressure hose 11 encompassing press version 20 on the hose nipple 31 of the coupling element 30 postponed.

In the 1 and 2 is the press version 20 extended in the rear area. In this extension region C is also the outer shell 12 of the high pressure hose 11 from the press version 20 involved. In this way it is ensured that the metal insert 13 is protected from external influences.

The coupling element 30 is with a union nut 40 provided to the coupling element 30 at the front end 37 at a desired fitting set. The hose nipple 31 of the coupling element 30 carries on its outer surface in the sealing region B structuring in the form of ribs 32 , which occurs when sliding the high-pressure hose 11 in the inner coat 14 Push. In the fuse area A is on the coupling element 30 a bulge 34 In the form of an annular groove formed by two shoulders 33 and 35 is limited. The radial of the coupling element 30 protruding shoulders 33 and 35 are sized so big that they are the ribs 32 of the hose nipple 31 significantly beyond. On the shoulders 33 . 35 lies after assembly, see 1 , the free-peeled high-pressure hose 11 , namely the metal insert 13 , on. The high pressure hose 11 can be combined with the press version 20 so far on the coupling element 30 postpone until an inwardly directed collar 28 at the front end 27 the press version 20 in a circumferential groove 36 of the coupling element 30 positionally engaged. The high pressure hose 11 can be up to the collar 28 the press version 20 slide. In the in 1 shown mounting position is the press version 20 to be seen in their original form. It has starting from the front end 27 which from the collar 28 is formed, in the security area A a larger-sized wall deformation 24 and in the axially adjacent sealing region B several smaller wall deformations 21 , All these wall deformations 21 . 24 are folding areas of the press version 20 and can be made by upsetting a cylindrical sleeve. It is of course also possible to provide spirally arranged wall deformations that can be generated via a rolling process. The wall deformations 21 and 24 represent projections that are radially toward the high pressure hose 11 from the press version 20 protrude. Opposite to the wall deformations 21 and 24 are on the outside of the press mount 20 wells 22 respectively. 25 Provided as compensation zones that can absorb material during pressing. The press version 20 has both in the security area A and in the sealing area B each have a uniform wall thickness D2 or D1. The wall thickness D1 of the press frame 20 in the sealing area B, however, is less than the wall thickness of the D2 of the press fitting 20 in the backup area A.

Is now even in a special press a radial pressure on the press frame 20 exercised, the hose coupling 10 transferred to their attachment case, the off 2 can be seen. The high pressure hose 11 is safe between press version 20 and coupling element 30 involved. On the one hand, an optimal positive and positive connection between the coupling element 30 and the press version 20 achieved in the fuse area A. How good 2 can be seen, by the wall deformation 24 the press version 20 when pressing the metal insert 13 in the groove-shaped bulge 34 on the coupling element 30 pressed. The metal insert 13 fills this bulge 34 out. At the same time the wall deformation attacks 24 with her tip 26 in the metal insert. By the pressing force in addition to the positive and a frictional connection between the metal components of the compound is achieved. In the sealing area B grab in the same way the wall deformations 21 in the metal insert 13 one. Due to the between the wall deformations 21 and 24 existing spaces 29 . 29 ' . 29 '' can the metal insert 13 when pressing into these spaces 29 . 29 ' . 29 '' Dodge, which in both the security area A and in the sealing area B to a positive connection between press frame 20 and high pressure hose 11 leads. In this radial compression of the press frame 20 a counterforce is generated by the pressing force in both the sealing area B and the securing area A, which leads to the wall deformations 21 . 24 can be deformed. Due to the outside of the press frame 20 opposite to the wall deformations 21 and 24 provided wells 22 . 25 can the deformed material from these depressions 22 . 25 be absorbed, whereby a change in length of the press frame 20 is prevented.

In the 1 drawn different wall thicknesses D1 and D2 of the press frame 20 prove to be advantageous during pressing. Thus, the pressing force generated in the fuse area A, where the metallic press frame 20 on the metal insert 13 impinges only for a short time by adapting to the shape of the bulge 34 the coupling element 30 can dodge, then a higher drag than, for example, this by the press fit 20 caused in the sealing area B. Thus this higher counterforce of the press version 20 can be absorbed in the security area A, comparatively more material in this security area A on the press fitting 20 this is provided by a greater wall thickness D2 in the securing area A in comparison to the wall thickness D1 in the sealing area B. The increase in the wall thickness D2 in the securing area A should be at least 5 to 20%. Particularly preferred are wall thicknesses D2, which are greater by 8 to 12% than the wall thickness D1. In this way, a uniform integration of the high-pressure hose 11 at the hose coupling 10 achieved.

In the prior art, the nipple incidence is measured after compression. A nipple incidence of a maximum of 10% is considered a measure of a secure technical connection. Whether a constriction in the area of the hose nipple 31 occurs during pressing, can be determined by means of a Prüfdornes. This test mandrel has successively areas of different diameters in the axial direction. Depending on how far the test spike from the front end 37 the hose coupling 30 into the interior of the hose nipple 31 can be measured, it can be measured whether the compression has led to a Einhürung, ie to a reduction in the inner diameter. Even a slight constriction has the disadvantage that by reducing the inner diameter of the hose nipple 31 only a smaller volume flow can be done, resulting in several hose couplings used in a hydraulic device to a significant reduction in efficiency and thus a reduction in energy efficiency. In the hose coupling according to the invention 10 A safe technical connection is achieved for the high-pressure and high-pressure area and this without a nipple incidence being determined after pressing. So was the inner diameter of the hose nipple 31 before pressing 14.8 mm and after pressing unchanged 14.8 mm. This enlarges the through the hose nipple 31 flowing volume flow due to the constant inner diameter. As a result, this internal diameter is up to 10% larger than in the case of prior art hose couplings with nipple incidence.

In the present example, there is the press version 20 from free-cutting steel and has a galvanizing and conversion coating on the surface for corrosion protection. The coupling element 30 consists of a 42CrMo4 steel alloy. This has in comparison to free cutting steel to a much higher strength and a higher elongation, resulting in the pressing during the Material of the coupling element 30 especially in the security area A better and easier to distribute for a non-positive connection. How out 2 to see are in the security area A on the coupling element 30 two trapezoidal shaped shoulders 33 and 35 provided the bulge 34 limit. In the bulge 34 when pressing the metal insert 13 of the high-pressure hose 11 pressed, in particular by the radially inwardly projecting wall deformation 24 with her point of attack 26 in the metal insert 13 intervenes. These trapezoidal shoulders 33 . 35 reduce their width with increasing height. In this way, sloping surfaces are generated around which the metal insert 13 easy to lay around, furthermore correspond to these shoulders 33 . 35 in an advantageous way with the gaps 29 ' . 29 '' at the press version 20 , This advantageous embodiment leads to a fast positive connection. A secure non-positive connection is achieved during compression, without changing the length of the press fitting 20 changed by the material of the wall deformation 24 into the depression 25 can retreat.

The wall deformations 21 and 24 in this embodiment are triangular in cross-section and thus have peak attack points 23 and 26 , However, other cross-sectional shapes are conceivable. The wall deformations 21 and 25 are symmetrical in this example. It can also asymmetric wall deformations 21 . 24 be used, preferably wall deformations 21 in which the attack points 23 towards the front end 27 the press version 20 are arranged offset. These wall deformations 21 would be at tensile load on the high pressure hose 11 If necessary, straighten up and stronger in the metal insert 13 intervene, which supports the tightness.

By using the CrMo steel alloy for the coupling element 30 can the hose nipple 31 be made with a smaller wall thickness, resulting in the enlargement of the clear cross-section of the coupling element 30 leads. Compared to a coupling element 30 from free cutting steel for the same application with a clear width before and after the compression of 14.8 mm, a clear width of 16.0 mm has been achieved in this embodiment, which corresponds to an increase in the clear width by about 10.8%. This enlarges the through such a hose nipple 31 flowing volume flow due to the larger inner diameter before compression and due to the constant inner diameter after compression. As a result, this inner diameter is 20% or more than 20% larger than prior art nipple hose connectors. With the advantageous consequence that a correspondingly larger hydraulic fluid flow through this hose coupling 10 is possible.

The invention is not limited to the exemplary embodiment shown, in particular not to the materials used or specified dimensions. There are also many other modifications possible. A larger dimensioned wall deformation 24 can also be achieved in other ways. The wall deformations 21 . 24 are not limited to the cross section shown. It can be more than a wall deformation 24 be provided. The design of the coupling element 30 in fuse area A or the structuring of the hose nipple 31 is not limited to the shapes and cross sections shown.

10

hose coupling

11

High pressure hose

12

outer sheath

13

metal insert

14

inner sheath

20

Press version

21

wall deformation

22

deepening

23

attackpoint

24

Wall deformation, nose

25

deepening

26

top

27

front The End

28

collar

29

gap

29 '

gap

29 ''

gap

30

coupling member

31

hose nipple

32

ribs

33

shoulder

34

bulge

35

shoulder

36

circumferential groove

37

front The End

40

Nut

A

security area

B

sealing area

D1

wall thickness

D2

wall thickness

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• EP 1744099 A1 [0002]
• - EP 1744090 A1 [0006, 0007]

Cited non-patent literature

• - EN 856 [0011]

Claims (15)

Hose coupling ( 10 ), in particular for high-pressure hydraulic lines or high-pressure hydraulic lines, - with a high-pressure hose ( 11 ), in which between two coats ( 12 . 14 ) a metal insert ( 13 ) is arranged from a wire mesh or from at least one wire spiral winding, - with a tubular coupling element ( 30 ) at the front end ( 37 ) is connectable to a valve and that at the other end a hose nipple ( 31 ) for receiving the high-pressure hose ( 11 ), - with a deformable under radial pressure press mount ( 20 ), - where the connection area for the high-pressure hose ( 11 ) in the hose coupling ( 10 ) comprises two areas, namely a front securing area (A), and an axially adjoining sealing area (B), wherein in the securing area (A) that of the coats (A) 12 . 14 ) liberated metal insert ( 13 ) and wherein in the sealing region (B) of the outer shell ( 12 ) freed high pressure hose ( 11 ) between hose nipples ( 31 ) and press version ( 20 ) is pressed, - whereby the press version ( 20 ) in the sealing area (B) radially to the high-pressure hose ( 11 ) and to the high-pressure hose ( 11 ) directed as projections formed wall deformations ( 21 ) and on the outside of the press frame ( 20 ) in the region of these wall deformations ( 21 ) Wells ( 22 ) and the press version ( 20 ) in the securing area (A) at least one radial to the high-pressure hose ( 11 ) and to the high-pressure hose ( 11 ) directed wall deformation ( 24 ) and on the outside of the press frame ( 20 ) in the area of wall deformation ( 24 ) a wells ( 25 ) is provided, - wherein in the securing area (A) provided wall deformation ( 24 ) comprises more material than a wall deformation ( 21 ) in the sealing region (B), - wherein the hose nipple ( 31 ) in the securing area (A) opposite to the wall deformation ( 24 ) a bulge ( 34 ) having. Hose coupling according to claim 1, characterized in that the one-piece press fitting ( 20 ) in the securing area (A) has a uniform wall thickness D2 and in the sealing area (B) a uniform wall thickness D1, wherein the wall thickness D2 is greater than the wall thickness D1, preferably the wall thickness D2 by 5 to 20% greater than the wall thickness D1, especially Preferably, the wall thickness D2 by 8 to 12% greater than the wall thickness D1. Hose coupling according to claim 1 or 2, characterized in that the press frame ( 20 ) at the front end ( 27 ) a radially inwardly directed collar ( 28 ), which in a circumferential groove ( 36 ) of the coupling element ( 30 ) intervenes. Hose coupling according to one of claims 1 to 3, characterized in that the press frame ( 20 ) is extended with its rear end beyond the sealing region (B) and with this extension region (C) the entire hydraulic hose ( 11 ) with its two coats ( 12 . 14 ) and the metal insert ( 13 ). Hose coupling according to one of claims 1 to 4, characterized in that a structuring of the hose nipple ( 31 ) is provided, preferably in the form of radially projecting ribs ( 32 ). Hose coupling according to one of claims 1 to 5, characterized in that the hose nipple ( 31 ) adjacent to the bulge ( 34 ) one shoulder each ( 33 . 35 ), these shoulders ( 33 . 35 ) the structuring of the hose nipple ( 31 ). Hose coupling according to one of claims 1 to 6, characterized in that the press frame ( 20 ) and the coupling element ( 30 ) are made of different materials, preferably made of different steel materials. Hose coupling according to claim 7, characterized in that the material of the coupling element ( 30 ) of the press version ( 20 ) compared to the material of the press frame ( 20 ) has a higher tensile strength. Hose coupling according to claim 7 or 8, characterized in that for the coupling element ( 30 ) a chromium-molybdenum steel alloy and for the press mount ( 20 ) a free cutting steel is used. Hose coupling according to one of claims 1 to 9, characterized in that in the case of installation, the press socket ( 20 ) the hose nipple ( 31 ) with the hydraulic hose ( 11 ) and in the case of attachment, the press socket ( 20 ) with the wall deformations ( 21 ) to the hydraulic hose ( 11 ), wherein the hose coupling ( 10 ) by applying an external radial pressure to the press fitting ( 20 ) can be transferred from the installation case in the fastening case. Hose coupling according to one of claims 7 to 10, characterized in that the inside diameter of the entire hose nipple ( 31 ) in the case of attachment, so after the radial compression, unchanged. Hose coupling according to Ansprü che 1 to 11, characterized in that the wall deformations ( 21 . 24 ) and the associated recesses ( 22 . 25 ) Folding areas of the press version ( 20 ). Hose coupling according to claim 12, characterized in that the wall deformations ( 21 . 24 ) and the associated recesses ( 22 . 25 ) are formed by upsetting. Hose coupling according to one of claims 1 to 13, characterized in that the wall deformations ( 21 . 24 ) are asymmetrically shaped in cross-section, namely one towards the front end ( 27 ) of the press version ( 20 ) offset point of attack ( 23 . 26 ) exhibit. Hose coupling according to one of claims 1 to 14, characterized in that in the securing area (A) provided wall deformation ( 24 ) is larger than a wall deformation ( 21 ) in the sealing area (B).