GB2325040A - Tubing with helical reinforcement - Google Patents

Abstract

Corrugated tubing 1, e.g. a milking hose, having a helical reinforcing element 42 with a D-shape section and a strip 45 of a rubber-like material wider than the pitch of the reinforcing element and wound so that it extends on the inside of one turn of the reinforcing element 42 and on the outside of an adjacent turn leaving a compressible air or foam pocket 46 between the inner and outer surfaces 41 and 40 between adjacent turns of the reinforcement element. End fittings (Fig 1) moulded at either end of the hose have stress-relieving portions formed by longitudinal bars extending between a cylindrical portion and a ring embracing the tubing.

Description

TUBES AND TUBING This invention relates to tubes and tubing.

Helical reinforcing elements are incorporated in tubing to make them resistant to kinking and crushing, whilst still enabling them to be flexible. It is difficult, however, to produce tubing having a high flexibility and strength, with a low weight. Another problem with conventional helically-reinforced tubes is that repeated flexing can cause damage at their ends, where the tubing is connected with its end fittings. One application where helicallyreinforced tubes are used and where it is important for the tubing to have strength and low weight is in hoses used to supply milk from a milking cluster to a milking machine. Such a hose is shown, for example, in EP571480A. Other reinforced tubes are described, for example, in EP153739A, DE2345455, EP473045, GB1533204, GB9221 16 and US2798508.

It is an object of the present invention to provide improved tubes and tubing.

According to one aspect of the present invention there is provided tubing having an inner surface, an outer surface, a helical reinforcing element between the inner and outer surfaces, and a compressible pocket between the inner and outer surfaces between adjacent turns of the helical reinforcing element such that when the tubing is bent, the compressible pocket is compressed on the inside of the bend of the tubing.

The compressible pocket is preferably an air pocket. The inner surface is preferably provided by the inner surface of a strip of material having a width greater than the pitch of the helical reinforcing element, the outer surface being provided by the outer surface of the strip. The strip preferably extends on the inside of one turn of the reinforcing element and on the outside of an adjacent turn. The strip may be of a rubber-like material. The tubing may be externally corrugated and internally smooth. The reinforcement member preferably has a Dshape in section and may be of a hard plastics material.

According to a second aspect of the present invention there is provided a method of making tubing according to the above one aspect of the present invention.

According to a third aspect of the invention there is provided a method of making tubing comprising the steps of winding a helical reinforcing element and a strip of flexible material to extend on both sides of the reinforcing element and joining adjacent turns of the strip material to one another such as to leave an air pocket between inner and outer surfaces of the tubing between adjacent turns of the helical reinforcing element.

According to a fourth aspect of the present invention there is provided a machine for use in a method according to the above third aspect of the invention.

According to a fifth aspect of the present invention there is provided tubing made by a method according to the above third aspect of the invention.

According to a sixth aspect of the present invention there is provided tubing made on a machine according to the above fourth aspect of the invention According to a seventh aspect of the present invention there is provided a tube including tubing according to the above one, fifth or sixth aspect of the invention and at least one end fitting at one end of the tubing, which may include a first cylindrical portion extending forwardly of the end of the tubing, a second cylindrical portion encompassing and bonded to the outside of the forward end of the tubing, and a stress-relieving portion extending rearwardly from the second cylindrical portion and bonded to the outside of the tubing. The stress-relieving portion preferably comprises a plurality of longitudinal members extending rearwardly from the rear end of the second cylindrical portion and may include a ring member at its rear end encompassing the tubing, the longitudinal members extending between the second cylindrical portion and the ring member. The end fitting is preferably moulded about the forward end of the tubing.

A tube including tubing and end fittings, for use in milking, and its method and machine for manufacture, will now be described, by way of example, with reference to the accompanying drawing, in which: Figure 1 is a side elevation view of the tube; Figure 2 is a transverse sectional elevation view of the tube along the line II-II of Figure 1; Figure 3 is an enlarged sectional side elevation view of a part of the tubing in the tube; and Figure 4 is a further enlargement of a part of the wall of the tubing.

With reference first to Figures 1 and 2, the milking tube has a length of extemallycorrugated tubing 1 with an end fitting 2 and 3 at opposite ends by which the tube is connected to the milking cluster and to the milking machine respectively. The tubing 1 has an external diameter of about 22mm and may be of any length, depending on the application.

The construction of the tubing 1 will be described in detail later.

The end fittings are identical, so only the construction of one fitting 2 will be described. The fitting 2 is made from a rubber-like material such as TPE (thermoplastic elastomer) or TPR (thermoplastic rubber). The fitting 2 has a first, forward portion 20 of cylindrical shape and circular section, being about 30mm long, with an intemal diameter of 16mm and a wall thickness of about 2mm. The internal diameter of the first portion 20 is substantially the same as the intemal diameter of the tubing 1 and the tubing does not extend within this first portion. The first portion 20 provides a resilient fit with a spigot (not shown) pushed into the end of the fitting 2. At the rear end of the first portion 20, the fitting 2 has a second cylindrical portion 21, with an increased diameter of about 24mm. The second portion 21 is about 27mm long and extends rearwardly along the outside of the tubing 1. The end fitting 2 is completed by a stress-relieving portion 22 extending rearwardly from the second cylindrical portion 21 by a distance of about 31 mm. The stress-relieving portion 22 comprises a ring 23 encompassing the tubing 1 and spaced from the second portion 21 by four longitudinally-extending bars 24 to 27. The ring 23 is about 4mm wide and has a rounded external profile. The bars 24 to 27 are each about 4mm wide, are of substantially square profile externally and are equally spaced around the circumference of the tubing 1, so that the outside of the tubing is exposed in the stress-relieving portion 22 in gaps 28 to 31 between the bars.

The end fitting 2 is formed and joined with the tubing 1 by injection moulding the fitting about the forward end of the tubing. In this way, the inside surface of the second portion 21 and the stress-relieving portion 22 follow the extemal contours of the tubing 1 and are securely bonded to it. The moulding operation also fills any gap between the rear of first portion 20 and the forward end of the tubing 1, so that there is a smooth internal transition between the bore of the tubing and the passage through the forward end of the end fitting.

The stress-relieving portion 22 provides less restriction to flexing of the tubing 1 than does the second portion 21, because of the reduced amount of material in the stress-relieving portion. When the tube is flexed in the region of the end fitting 2, the extent of flexing will be greatest in the region of the tubing 1 to the rear of the end fitting, will be less in the stressrelieving portion 22, and will be least in the region of the tubing enclosed by the second portion 21 of the end fitting. In this way, flexing of the tubing 1 is gradually reduced towards its end, avoiding abrupt transitions that can cause damage. Also, the stress-relieving portion 22 of the end fitting 2 itself can flex more freely than the second portion 21, without being damaged. In addition to reducing stress damage to the tubing 1 and end fitting, the end fittings have the advantage that the bars 24 to 27 form a useful grip by which the tube can be held and twisted to fit it on or remove it from a mating coupling. The outer profile of the bars 24 to 27 could be rounded to facilitate gripping.

With reference now to Figures 3 and 4 the tubing 1 will be described in more detail.

The tubing 1 is corrugated on its external surface 40 but is substantially smooth on its inner surface 41, so as to present a smooth path for milk or other fluid flowing along the tube. The tubing 1 is reinforced along its entire length by a helical reinforcing element 42. The reinforcing element 42 is made of a hard plastics, such as polypropylene, and has a D-shape section, with its flat surface 43 presented inwardly and its convex surface 44 presented outwardly. The reinforcing element 42 has a width of about 5mm, a height of about 2mm and is wound with a pitch of about 6mm, so that there is a gap about 2mm wide between adjacent turns.

The tubing 1 is completed by a single, thin strip 45 of a flexible rubber-like material such as TPE or TPR. The strip 45 is about 25mm wide, that is, wider than three pitches of the reinforcing element 42. The strip 45 is wound in such a way that it covers both the outer and inner surfaces of the reinforcing element 42, to provide the external and internal surfaces of the tubing, and so that it leaves a resilient, compressible air pocket 46 between the outer and inner surfaces. The compressible air pocket 46 occupies the entire distance between adjacent turns of the reinforcing element. More particularly, as shown in Figure 4, there is shown a section of the tubing comprising five turns of the reinforcing element 42, labelled A to E respectively, and four turns of the strip 45 labelled W to Z respectively (turns Y and Z only being shown in part). The right-hand edge of the first turn W of the strip 45 lies at the lefthand edge of the first turn A of the reinforcing element 42 and extends to the left beneath the next adjacent turn B of the reinforcing element. The adjacent region across the width of the turn W of the strip 45 continues across the space between the turns B and C of the reinforcing element 42, on top of the right-hand edge of the next adjacent turn X of the strip, to which it is bonded. The width then extends up the right-hand side of the turn C of the reinforcing element 42, following its contour closely to the top of the element and then down the lefthand side by about one-third the thickness of the strip. The turn W then extends horizontally across the space between the two turns X and Y of the reinforcing element 42, leaving a gap above the next turn X of the strip, which provides the air pocket 46. The region along the lefthand of the turn W of the strip 45 lies on top of the adjacent turn X where it extends over the turn Y of the coil. The left-hand edge of the turn W lies midway between the two turns Y and Z on the outside of the tubing 1. In this way, each turn of the reinforcing element 42 is overlaid by two plies of the strip, whereas the inside of the reinforcing element is covered by a single ply of the strip. In the space between adjacent turns of the reinforcing element 42 there are at least three plies of the strip 45. The outer surface of the tubing 1 is provided by the outer surface of the left-hand part of the strip 45: the inner surface of the tubing is provided by the inner surface of the right-hand part of the strip. The relatively small space between adjacent turns of the reinforcing element 42, which is a result of the small pitch/width ratio of the reinforcing element, and the relatively large thickness of the element prevents the strip, where it extends along the outside of the element, coming into contact with the strip extending along the inside of the element.

The tubing 1 may be made in various different ways. For example, the strip 45 and the reinforcing element 42 may both be extruded and wound, close to where they emerge from the extruder heads about a rotating mandrel, such as one formed by the outside of several rotating, flexible rods extending helically about a common axis. The reinforcing element 42 may be extruded in a circular shape and deformed to the D-shape by contact with the outside of the mandrel. Because the strip 45 and the reinforcing element 42 are not fully cured when they are wound around the mandrel, the overlapping turns of the strip bond with one another and to the reinforcing element.

The tubing of the present invention can be light in weight yet resistant to kinking and crushing. The tubing can also withstand the negative pressures used in milking equipment without collapsing. Although the tubing has a helical reinforcing element, it can still have a substantially smooth inner surface, which improves flow and makes cleaning easier. The smooth internal surface reduces the risk of turbulence in the milk flow and reduces the risk that milk residues will be deposited in the tubing. The tubing can be highly flexible compared with conventional helically-reinforced tubing because of the compressible air pocket between the outer and inner surfaces of the tubing between adjacent turns of the reinforcing element.

This is an important advantage in milking applications because it enables the milking cluster to be placed in an ideal position in relation to the udder to ensure an equal loading on the udder. This in turn ensures an equal milking of the teats and reduces the risk that any cup of the cluster will fall off during milking. The compressible pocket need not contain air but could, for example, contain a light, compressible foam, or the like.

Claims (24)

1. Tubing having an inner surface, an outer surface, a helical reinforcing element between the inner and outer surfaces, and a compressible pocket between the inner and outer surfaces between adjacent turns of the helical reinforcing element such that when the tubing is bent, the compressible pocket is compressed on the inside of the bend of the tubing.

2. Tubing according to Claim 1, wherein the compressible pocket is an air pocket.

3. Tubing according to Claim 1 or 2, wherein the said inner surface is provided by the inner surface of a strip of material having a width greater than the pitch of the helical reinforcing element.

4. Tubing according to Claim 3, wherein the said outer surface is provided by the outer surface of said strip.

5. Tubing according to Claim 3 or 4, wherein said strip extends on the inside of one turn of the reinforcing element and on the outside of an adjacent turn.

6. Tubing according to any one of Claims 3 to 5, wherein said strip is of a rubber-like material.

7. Tubing according to any one of the preceding claims, wherein the tubing is externally corrugated and internally smooth.

8. Tubing according to Claim 7, wherein the reinforcing member has a D-shape in section.

9. Tubing according to any one of the preceding claims, wherein the reinforcing member is of a hard plastics material.

10. Tubing substantially as hereinbefore described with reference to the accompanying drawing.

11. A method of making tubing according to any one of Claims 1 to 10.

12. A method of making tubing comprising the steps of winding a helical reinforcing element and a strip of flexible material to extend on both sides of the reinforcing element and joining adjacent turns of the strip material to one another such as to leave an air pocket between inner and outer surfaces of the tubing between adjacent turns of the helical reinforcing element.

13. A method substantially as hereinbefore described with reference to the accompanying drawing.

14. A machine for use in the method of any one of Claims 11 to 13.

15. A machine substantially as hereinbefore described with reference to the accompanying drawing.

16. Tubing made by a method according to any one of Claims 11 to 13.

17. Tubing made on a machine according to Claim 14 or 15.

18. A tube including tubing according to any one of Claims 1 to 10, 16 or 17 and at least one end fitting at one end of the tubing.

19. A tube according to Claim 18, wherein said end fitting includes a first cylindrical portion extending forwardly of the end of the tubing, a second cylindrical portion encompassing and bonded to the outside of the forward end of the tubing, and a stress-relieving portion extending rearwardly from the second cylindrical portion and bonded to the outside of the tubing.

20. A tube according to Claim 19, wherein said stress-relieving portion comprises a plurality of longitudinal members extending rearwardly from the rear end of the second cylindrical portion.

21. A tube according to Claim 20, wherein the stress-relieving portion includes a ring member at its rear end encompassing the tubing, and wherein the longitudinal members extend between said second cylindrical portion and the ring member.

22. A tube according to any one of Claims 18 to 21, wherein said end fitting is moulded about the end of the tubing.

23. A tube substantially as hereinbefore described with reference to the accompanying drawing.

24. Any novel and inventive feature or combination of features as hereinbefore described.