阅读说明：本技术 管道连接器、组件和方法 (Pipe connector, assembly and method ) 是由 詹姆斯·爱德华·麦卡尔平 于 2020-03-09 设计创作，主要内容包括：一种用于在包含柔性管段(102)的管道组件(100)中使用的管道连接器(10)。连接器(10)包括连接器本体(12),其具有穿过该连接器本体的轴向通孔(16)。连接器本体(12)包括被构造以用于插入接合柔性管段(102)的内部中和用于接合柔性管段(102)的内部的第一端部(18)和用于联接到第二管段(104)的第二端部(20),以便将柔性管段(102)连接到第二管段(104)。箍套(14)被设置成用于定位在连接器本体(12)的第一端部(18)上。连接器本体(12)的第一端部(18)包括保持器装置,其被构造以接合柔性管段(102)的内部,以将连接器本体(12)固定到柔性管段,并且将箍套(14)保持到连接器本体(12)。(A pipe connector (10) for use in a pipe assembly (100) comprising a flexible pipe segment (102). The connector (10) includes a connector body (12) having an axial through bore (16) therethrough. The connector body (12) includes a first end (18) configured for insertion into and for engaging an interior of the flexible pipe segment (102) and a second end (20) for coupling to a second pipe segment (104) in order to connect the flexible pipe segment (102) to the second pipe segment (104). The ferrule (14) is configured for positioning over a first end (18) of the connector body (12). The first end (18) of the connector body (12) includes a retainer device configured to engage an interior of the flexible pipe segment (102) to secure the connector body (12) to the flexible pipe segment and to retain the ferrule (14) to the connector body (12).)

1. A pipe coupling for use in a pipe assembly comprising a flexible pipe section, the pipe coupling comprising:

a connector body having an axial through bore therethrough, the connector body including a first end configured for insertion into and for engaging an interior of a flexible pipe segment and a second end for coupling to a second pipe segment for connecting the flexible pipe segment to the second pipe segment; and

a ferrule configured for positioning over the first end of the connector body, the ferrule configured to extend over and engage an outer surface of the flexible pipe segment when the connector body is inserted into the flexible pipe segment,

wherein the first end of the connector body includes a retainer device configured to engage an interior of the flexible pipe segment to secure the connector body to the flexible pipe segment and to retain the ferrule to the connector body.

2. The pipe coupling according to claim 1, wherein said retainer device is configured to allow said flexible pipe segment to pass over said retainer device in a first axial direction, but prevent or impede movement of said flexible pipe segment in a second axial direction.

3. A pipe coupling according to claim 1 or 2, wherein the retainer means is configured to allow the ferrule to pass over the retainer means in the first axial direction but prevent or resist movement of the flexible pipe section in the second axial direction.

4. A pipe coupling according to any preceding claim, wherein the retainer means comprises one or more ribs formed on an outer surface of the first end of the coupling body.

5. The pipe coupling according to claim 4, wherein at least one of said ribs defines a ramp or ratchet profile.

6. The pipe connector of any preceding claim, wherein the ferrule comprises a base, the base comprising an aperture configured to allow the ferrule to be positioned over the first end of the connector body.

7. The pipe coupling according to claim 6, wherein said bore has an inner diameter sized to provide an interference fit with said coupling body.

8. A pipe connector according to any preceding claim wherein the bore has an inner diameter dimensioned to provide an interference fit with the retainer means of the connector body.

9. The pipe coupling according to any preceding claim, wherein the ferrule further comprises a wall portion configured to extend over an outer surface of the flexible pipe section when the first end of the coupling body is inserted inside the flexible pipe section.

10. A pipe coupling according to any preceding claim, wherein the wall portion is configured to engage an outer surface of the flexible pipe section.

11. A pipe coupling according to any preceding claim, wherein the ferrule is configured to provide an interference fit with an outer surface of the flexible pipe section.

12. A pipe connector according to any preceding claim when dependent on claim 9, wherein the wall portion of the cuff is configured to provide an interference fit with an outer surface of the flexible pipe section.

13. A pipe coupling according to any preceding claim, wherein the ferrule comprises retainer means for securing or further securing the connection between the ferrule and the flexible pipe section.

14. The pipe connector of claim 13 wherein said retainer means of said ferrule comprises one or more ribs formed on an inner surface of said ferrule.

15. The pipe connector according to claim 13, 14 or 15, wherein at least one of said ribs defines a ramp or ratchet profile.

16. A pipe connector according to any preceding claim wherein the first end defines a male end of the connector body.

17. A pipe coupling according to any preceding claim, wherein the first end portion comprises:

a distal section having an outer diameter;

a proximal section having an outer diameter greater than an outer diameter of the distal section; and

a tapered section interposed between the distal section and the proximal section.

18. A pipe coupling according to any preceding claim, wherein the second end defines a female end.

19. A pipe coupling according to any preceding claim, wherein the second end portion is configured to be coupled to a second pipe segment having the same or substantially the same dimensions as the flexible pipe segment.

20. The pipe coupling according to any one of claims 1 to 18, wherein said second end is configured to couple to a second pipe segment having a different size than said flexible pipe segment, said first end being configured to couple to said flexible pipe segment.

21. A pipe coupling according to any preceding claim, wherein the second end comprises:

a connector means for securing the second end to the second pipe section; or

A flat end for securing the second end to the second tube segment.

22. A pipe assembly comprising a pipe connector according to any one of claims 1 to 21, and a flexible pipe segment.

23. A kit of parts comprising a pipe connector according to any one of claims 1 to 21, and a flexible pipe segment.

24. The conduit assembly of claim 22 or the kit of parts of claim 23, comprising a second conduit connector, wherein the second conduit connector has the same or a different configuration than the first conduit connector.

25. A method for forming a pipe assembly using the pipe connector according to any one of claims 1 to 21.

Technical Field

The present disclosure relates to pipe connectors, assemblies, and methods. In particular, the present disclosure relates to a pipe connector, a pipe assembly comprising the pipe connector and a flexible and/or expandable pipe segment, and a method for forming a pipe assembly.

Background

The pipe fittings are provided in a variety of different forms, sizes and materials to accommodate different applications and regional differences in pipe codes.

In the case of non-pressurized waste plumbing assemblies for use with sinks, appliances, and the like, forming the plumbing assembly may typically involve cutting rigid pipe sections to a desired length and connecting them together using one or more plumbing fittings in the form of angular connectors (e.g., 90 degree bends, 45 degree bends, etc.).

More recently, pipe assemblies using flexible pipe sections have been developed for use with such waste water fittings. However, while the use of a pipe assembly using flexible pipe segments provides advantages over conventional assemblies in some instances, many challenges remain.

For example, while the use of flexible pipe sections reduces or avoids the requirements for corner connectors and cutting the pipe sections to field size, the use of flexible pipe sections to form an assembly can take a significant amount of time for the installer and thereby increase customer costs.

In applications where access restrictions make conventional corner connectors impractical or unfeasible, the use of flexible pipe sections has the advantage over conventional fittings that the pipe can be adapted to the desired shape. However, such connections still require access to form an assembly, which may mean that the use of such assemblies using flexible tubing is still impractical or unfeasible due to the same limitations on access described above.

Furthermore, as with conventional corner connectors, the tubing assemblies using flexible tubing segments expand and contract during use due to fluid flow and/or thermal effects of the environment, such that any errors in forming the assembly can result in leaks that require significant time and expense to be remedied.

Disclosure of Invention

According to a first aspect, there is provided a pipe connector for use in a pipe assembly comprising a flexible pipe section, the pipe connector comprising:

a connector body having an axial through bore therethrough, the connector body including a first end configured for insertion into and for engaging an interior of a flexible pipe segment and a second end for coupling to a second pipe segment for connecting the flexible pipe segment to the second pipe segment; and

a ferrule configured for positioning over the first end of the connector body, the ferrule configured to extend over and engage the outer surface of the flexible pipe segment when the connector body is inserted into the flexible pipe segment,

wherein the first end of the connector body includes a retainer device configured to engage an interior of the flexible pipe segment to secure the connector body to the flexible pipe segment and to retain the ferrule to the connector body.

The pipe connector may be configured such that in use the first end of the pipe connector may be pushed into and retained within the flexible pipe section without rotation between the pipe connector and the flexible pipe section. It should be understood that the term "flexible pipe section" is used herein to refer to a pipe section that is adaptable in terms of its shape and/or axial length. For example, a user may adjust the flexible tube segment to define a selected angle, shape, or length. Thus, the assembled conduit connector and flexible conduit segment provide a conduit assembly suitable for a waste connection (e.g., a non-pressurized waste connection for a basin, bathtub, appliance such as a washing machine, dishwasher, etc.).

Advantageously, the pipe coupling provides a compact, quick, reliable and safe coupling for a pipe assembly comprising a flexible pipe section, which has a number of advantages over conventional fittings. For example, the ability to join the inside and outside of the flexible pipe section provides a secure connection to the flexible pipe section, which can, for example, resist forces encountered during installation and/or use due to expansion and/or contraction due to thermal effects, reducing the risk of leaks that require significant time and expense to be remedied due to errors in forming the assembly. Furthermore, the pipe connector only requires a pushing force to make a connection with the flexible pipe section, and therefore does not require rotation of the connector body and/or the ferrule (or flexible pipe section) to make a connection with the flexible pipe section. This allows for quick connections in applications where restrictions on access would make swivel connections impractical or otherwise require significant additional time and cost. The pipe connector also allows connections to be made without the need to cut field pipe sections or provide additional angle connectors, thereby having a smaller space requirement than conventional fittings.

As mentioned above, the first end of the connector body includes a retainer device configured to engage the interior of the flexible pipe segment to secure the connector body to the flexible pipe segment.

The retainer device may be configured to allow the flexible tube segment to pass over the retainer device in the first axial direction, but prevent or impede movement of the flexible tube segment in the second axial direction.

In use, upon insertion of the first end of the connector body into the end of the flexible pipe section, the retainer device may allow the flexible pipe section to pass over the retainer device in a first axial direction (i.e. the direction in which the flexible pipe section and the connector body are connected together), but prevent or resist movement of the flexible pipe section in a second axial direction (i.e. the direction in which the connector body and the flexible pipe section are moved apart).

Advantageously, the retainer device may be configured to engage the interior of the flexible pipe segment without the need to rotate the connector body.

As described above, the retainer device may be configured to retain the ferrule on the connector body.

The retainer device may be configured to allow the ferrule to pass over the retainer device in the first axial direction, but prevent or resist movement of the ferrule in the second axial direction.

In use, when positioning the ferrule on the first end of the connector body, the retainer device may allow the ferrule to pass over the retainer device in a first axial direction (i.e., the direction that connects the ferrule and the connector body together), but prevent or inhibit movement of the ferrule in a second axial direction (i.e., the direction that moves the connector body and the ferrule apart).

The retainer means may comprise mechanical fastening means.

The retainer means may comprise a snap-fit retainer.

The retainer means may comprise one or more ribs.

One or more ribs may be integrally formed with the connector body.

For example, one or more ribs may be formed on an outer surface of the first end of the connector body. The one or more ribs may define a ramp or ratchet profile to allow movement of the flexible tube segment and/or the cuff in the first axial direction but prevent or impede movement of the flexible tube segment and/or the cuff in the second axial direction.

As described above, the ferrule is configured for positioning over the first end of the connector body and is configured to extend over and engage the outer surface of the flexible pipe segment when the connector body is inserted into the flexible pipe segment.

The cuff may include a base.

The base may include an aperture configured to allow the ferrule to be positioned over the first end of the connector body. For example, the aperture may be sized to allow the ferrule to be positioned over the first end of the connector body.

In particular embodiments, the bore may have an inner diameter sized to provide an interference fit with the connector body, more particularly with the retainer device.

The cuff may be annular. For example, the base of the cuff may define a loop.

The cuff may also include a wall portion extending from the base. In use, the wall portion may be configured to extend over, i.e. may be disposed on, the outer surface of the flexible pipe section when the first end of the connector body is inserted into the interior of the flexible pipe section.

The wall portion may be configured to engage an outer surface of the flexible pipe segment.

The engagement between the wall portion and the outer surface of the flexible pipe section may secure or further secure the connection between the cuff and the flexible pipe section.

The internal dimension (e.g., diameter) defined by the wall portion may be sized to secure or further secure the connection between the cuff and the flexible pipe segment. For example, an inner dimension (e.g., diameter) defined by the wall portion may be sized to provide an interference fit with the outer surface of the flexible pipe segment.

Alternatively or additionally, the wall portion of the cuff may be provided with retainer means for securing or further securing the connection between the cuff and the flexible pipe section.

The retainer means of the cuff may comprise one or more ribs.

As described above, the connector body includes a first end portion adapted to be inserted into an end of a flexible pipe segment.

The first end may define a male end of the connector body.

The first end portion may define a constant outer diameter. However, in certain embodiments, the first end portion may include different segments having different outer diameters.

The first end may include a distal segment.

The first end may include a proximal segment.

The outer diameter of the proximal section may be greater than the outer diameter of the distal section.

A retainer device for engaging the interior of the flexible tube segment may be provided on the proximal segment.

The first end may include a tapered section.

The tapered section may be interposed between the distal section and the proximal section.

The tapered section may define a bevel angle.

The bevel angle may secure or assist in securing the first end of the connector body to the interior of the flexible pipe section. In use, friction between the tapered section and the interior of the flexible pipe section as the first end is inserted into the flexible pipe section may secure or assist in securing the first end of the connector body to the interior of the flexible pipe section.

The first end of the connector body may define a constant inner diameter along its length. For example, in embodiments where the first end has different sections with different outer diameters, the proximal section, the distal section, and the tapered section may have the same inner diameter.

The first end portion may be configured to couple to a metric-made flexible pipe segment, for example, a flexible pipe segment having a diameter of 32mm, 40mm, 50mm, or 65 mm.

The first end may be configured to couple to a second pipe segment that is not metric, such as a second pipe segment having a diameter of 11/4 inches (31.75mm), 11/2 inches (38.1mm), or 2 inches (50.8 mm). However, it will be appreciated that the first end portion may be configured to be coupled to any suitably configured flexible pipe segment.

As described above, the connector body includes a second end for coupling to a second pipe segment to connect the flexible pipe segment to the second pipe segment.

The second end may be configured to couple to a second tube segment having the same or substantially the same dimensions as the flexible tube segment.

For example, the second end may be configured to couple to a metric second pipe segment, such as a second pipe segment having a diameter of 32mm, 40mm, 50mm, or 65 mm.

Alternatively, the second end may be configured to couple to a second pipe segment that is not metric, such as a second pipe segment having a diameter of 11/4 inches (31.75mm), 11/2 inches (38.1mm), or 2 inches (50.8 mm).

The second portion may be configured to couple to a second pipe segment having a different size than the flexible pipe segment to which the first end portion is configured to couple.

For example, the first end may be configured to couple to a flexible pipe segment of a metric having a given diameter, and the second end may be configured to couple to a second pipe segment of a metric having a different diameter.

Alternatively, the first end may be configured to couple to a non-metric flexible pipe segment having a given diameter, and the second end may be configured to couple to a non-metric second pipe segment having a different diameter.

Alternatively, the first end may be configured to couple to a metric flexible pipe segment having a given diameter, and the second end may be configured to couple to a non-metric second pipe segment having a different diameter.

Alternatively, the first end may be configured to couple to a non-metric flexible pipe segment having a given diameter, and the second end may be configured to couple to a second pipe segment having a metric of different diameter.

The given and different diameters may include one or more of the above dimensions, or another suitable diameter.

In some embodiments, the second end may define a female end.

The female end may be configured to receive an end of a second pipe segment. The inner dimension (e.g., diameter) of the second end portion may be sized to receive an end of a second tube segment.

Alternatively, the second end may define a male end for insertion into the second pipe section.

For example, in some cases, the second pipe section may include a waste connection, such as a non-pressurized waste connection for a tub, bathtub, appliance such as a washing machine, dishwasher, or the like, and the second end may be directly coupled to the waste connection.

The second end may comprise connector means for securing the second end to the second pipe section.

The connector means may comprise a threaded connector means or the like. The connector means may be provided on an outer surface of the second end portion. The connector means may be formed on an outer surface of the second end portion.

In certain embodiments, the connector means may comprise a compression fitting or the like.

In such embodiments, the connector may also include a compression ring or the like.

Alternatively, the connector means may comprise a push-fit connector.

For example, the connector device may form an interference fit with the second tube segment.

The connector device may be configured to engage and secure a nut of the second pipe segment.

In such embodiments, the connector may also include a compression ring or the like.

The connector device may be configured to directly engage and secure to the second pipe segment.

The second end may define a base for receiving an end of a second pipe segment.

The connector body may include a flange portion.

The flange portion may be interposed between the first end and the second end of the connector body.

The flange portion may define an interface between the first end and the second end.

In use, the flange portion may form an end stop or shoulder for the ferrule.

In certain embodiments, the connector body is a unitary construction.

Alternatively, the connector body may comprise a plurality of members coupled together.

In certain embodiments, the cuff is a one-piece construction.

Alternatively, the cuff may comprise a plurality of members coupled together.

The pipe connector may be formed as an assembly. For example, the ferrule and the connector body may be formed together as an assembly using an additive manufacturing method.

At least a portion of the pipe connector may be constructed of a polymeric material, particularly but not exclusively polypropylene.

The connector body may be constructed of a polymeric material, particularly but not exclusively polypropylene.

The cuff may be constructed from a polymeric material, particularly but not exclusively polypropylene.

The connector may comprise a sealing arrangement comprising one or more sealing elements, such as O-ring sealing elements or the like.

According to a second aspect, there is provided a pipe assembly comprising:

a pipe connector according to the first aspect; and

a flexible tube segment.

As mentioned above, the term "flexible pipe section" is used herein to refer to a pipe section that is adaptable in terms of its shape and/or axial length. For example, a user may adjust the flexible tube segment to define a selected angle, shape, or length. Thus, the assembled conduit connector and flexible conduit segment provide a conduit assembly that may be suitable for a waste connection (e.g., a non-pressurized waste connection for a basin, bathtub, appliance such as a washing machine, dishwasher, etc.).

The flexible tube section may be expandable, i.e. the flexible tube section may be configured such that its axial length may be increased. The flexible tube section may be collapsible, i.e. the flexible tube section may be configured such that its axial length may be reduced.

The flexible tubing segment may comprise a plurality of segments.

The segments may be coupled together or formed to allow one or more of the segments to collapse together to reduce the overall length of the flexible pipe section, or vice versa to allow one or more of the segments to expand/move apart to axially increase the overall length of the flexible pipe section.

Alternatively or additionally, the segments may be coupled together or formed to allow one or more of the segments to pivot relative to another segment to adapt to the shape of the flexible pipe segment.

The pipe assembly may include a second pipe connector.

The second pipe connector may further comprise a pipe connector according to the first aspect.

The second pipe connector may be the same as or different from the first pipe connector.

According to a third aspect, there is provided a kit of parts comprising a pipe connector according to the first aspect, and a flexible pipe segment.

The pipe assembly may include a second pipe connector.

The second pipe connector may further comprise a pipe connector according to the first aspect.

The second pipe connector may be the same as or different from the first pipe connector.

According to a fourth aspect, there is provided a method for forming a pipe assembly using the pipe connector of the first aspect.

Where not already so provided, the method may include positioning a ferrule on the first end of the connector body.

The method may include pushing the first end of the connector body into the end of the flexible pipe segment until the retainer device engages and secures the connector body to the flexible pipe segment.

It will be appreciated that features defined above or described below may be used alone or in combination with any other defined feature.

Drawings

These and other aspects of the invention will now be described, by way of example only, with reference to the accompanying drawings, in which:

FIG. 1 shows an exploded view of a pipe connector;

FIG. 2 shows an enlarged view of the connector body of the pipe connector shown in FIG. 1;

FIG. 3 shows an enlarged view of the ferrule of the pipe connector shown in FIG. 1;

FIG. 4 illustrates a pipe assembly using the pipe connector shown in FIG. 1;

FIG. 5 illustrates an alternative pipe connector to the pipe connector shown in FIG. 1;

FIG. 6 shows an enlarged view of a portion of the pipe connector shown in FIG. 5;

FIG. 7 illustrates a pipe assembly using the pipe connector shown in FIG. 5;

FIG. 8 illustrates an alternative conduit connector to the conduit connector shown in FIGS. 1 and 5;

FIG. 9 shows an enlarged view of a portion of the pipe connector shown in FIG. 8; and

fig. 10 illustrates a pipe assembly using the pipe connector shown in fig. 8.

Detailed Description

Referring initially to fig. 1 of the drawings, there is shown a pipe coupling 10 for use in a pipe assembly comprising a flexible pipe segment, such as the assembly 100 and flexible pipe segment 102 shown in fig. 4 and described below.

As shown in fig. 1, the pipe connector 10 includes a connector body 12 and a ferrule 14, the ferrule 14 being configured for positioning on the connector body 12. In use, and as will be described below, a portion of the connector body 12 is configured to be inserted into an end of the flexible pipe segment 102 to engage and secure the pipe connector 10 to the flexible pipe segment 102, and the ferrule 14 is configured to extend over and engage an outer surface of the flexible pipe segment 102.

Referring now also to fig. 2 of the drawings, fig. 2 shows an enlarged view of the connector body 12 shown in fig. 1, the connector body 12 being generally tubular in construction with an axial through bore 16 therethrough, the axial through bore 16 defining an axial flow passage through the connector body 12.

The connector body 12 has a first male end 18 configured for insertion into the interior of a flexible pipe segment 102 (shown in fig. 4) and for engaging the interior of the flexible pipe segment 102, and a second end 20 for coupling to a second pipe segment 104 (shown in fig. 4) for connecting the flexible pipe segment 102 to the second pipe segment 104. The first end 18 and the second end 20 are separated by a flange portion 22, the flange portion 22 providing an end stop for the ferrule 14 in use.

In the illustrated pipe connector 10, the first end 18 of the connector body 12 has a distal section 24, a proximal section 26, and a tapered section 28, the tapered section 28 being interposed between the distal section 24 and the proximal section 26 and forming a transition between the distal section 24 and the proximal section 26. In use, the distal segment 24 forms a leading end of the connector 12 for insertion into the flexible tube segment 102. The proximal section 26 is adjacent to the flange portion 22.

As shown in fig. 2, the proximal section 26 has an outer diameter greater than the outer diameter of the distal section 24, and the tapered section 28 defines a ramp angle.

In use, the bevel angle may secure or assist in securing the first end 18 of the connector body 12 to the interior of the flexible pipe segment 102, the friction between the tapered section 28 and the interior of the flexible pipe segment 102 securing or assisting in securing the first end 18 of the connector body 12 to the interior of the flexible pipe segment 102 upon insertion of the first end 18 into the flexible pipe segment 102.

As shown in fig. 2, first end 18 of connector body 12 has a constant inner diameter along its length, although the outer diameter of first end 18 varies along its length.

Formed on an outer surface of the first end portion 18 is a retainer device 30, the retainer device 30 being configured to engage an interior of the flexible pipe segment 102. In the illustrated connector 10, the retainer device 30 is formed on the proximal section 26 of the first end 18.

In use, upon insertion of the first end portion 18 of the connector body 12 into the end of the flexible pipe segment 102, the retainer device 30 allows the flexible pipe segment 102 to pass over the retainer device 30 in a first axial direction (i.e., the direction that connects the flexible pipe segment 102 and the connector body 12 together), but prevents or inhibits movement of the flexible pipe segment 102 in a second axial direction (i.e., the direction that moves the connector body 12 and the flexible pipe segment 102 apart).

Advantageously, the retainer device 30 is configured to engage the interior of the flexible pipe segment 102 without rotating the connector body 12.

As shown in fig. 2, in the illustrated connector 10, the retainer device 30 takes the form of a plurality of ribs 32. Each rib 32 defines a ramp or ratchet profile that allows the flexible tube segment to pass over the rib 32 in a first axial direction (i.e., the direction that couples the flexible tube segment 102 and the connector body 12 together), but prevents or inhibits movement of the flexible tube segment 102 in a second axial direction (i.e., the direction that moves the connector body 12 and the flexible tube segment 102 apart).

As described above, the ferrule 14 is configured for positioning on the first end 18, and the retainer device 30 is also configured to retain the ferrule 14 on the connector body 12, the ribs 32 allowing the ferrule 14 to pass over the retainer device 30 in the first axial direction but preventing or inhibiting movement of the ferrule in the second axial direction.

Thus, in use, when positioning the ferrule 14 on the first end 18 of the connector body 12, the retainer device 30 allows the ferrule 14 to pass over the retainer device 30 in a first axial direction (i.e., the direction that connects the ferrule 14 and the connector body 12 together), but prevents or inhibits movement of the ferrule 14 in a second axial direction (i.e., the direction that moves the connector body 12 and the ferrule 14 apart).

As described above, the second end 20 of the connector body 12 is for coupling to the second tube segment 104 to connect the flexible tube segment 102 to the second tube segment 104.

In the illustrated connector 10, the second end 20 defines a female end for receiving an end of a second pipe segment 104, the second end 20 having an inner diameter sized to receive the end of the second pipe segment 104. The base 34 forms an end stop for insertion of the second tube segment 104.

As shown in fig. 2, a connector means in the form of a threaded connection 34 is formed on the outer surface of the second end 20, the connection 34 being configured to engage a nut (106 shown schematically in fig. 4) of the second pipe segment 104 to secure the connector body 12 to the second pipe segment 104 and, thus, the flexible pipe segment 102 to the second pipe segment 104.

It will be appreciated that while in the illustrated connector 12 the coupling 34 engages the nut 106 associated with the second pipe segment 104, the coupling 34 may instead directly engage the second pipe segment 104.

Referring now also to fig. 3 of the drawings, fig. 3 shows an enlarged view of the ferrule 14, and it can be seen that the ferrule 14 includes an annular base portion 36 and a wall portion 40, the annular base portion 36 having an aperture 38, the aperture 38 being configured to allow the ferrule 14 to be positioned over the first end 18 of the connector body 12, the wall portion 40 extending from the base portion 36. In use, the wall portion 40 is configured to extend over, i.e., be disposed on, the outer surface of the flexible pipe segment 102 when the first end 18 of the connector body 12 is inserted inside the flexible pipe segment 104.

In the illustrated connector 10, the bore 38 has an inner diameter sized to provide an interference fit with the connector body 12, and more particularly with the ribs 32 of the retainer device 30.

As shown in fig. 3, the wall portion 40 is configured to engage the outer surface of the flexible pipe segment 102 and has a retainer device 42 to secure or further secure the connection between the cuff 14 and the flexible pipe segment 102.

In the illustrated connector 10, the retainer device 42 of the ferrule 14 takes the form of a plurality of ribs 44 having a ramped or ratchet profile that allows the retainer device 42 to pass over the flexible tubing segment 102, but prevents or resists movement in the opposite direction.

Referring now also to fig. 4 of the drawings, fig. 4 shows the conduit assembly 100 briefly described above. While fig. 4 shows the pipe coupling 10 and flexible pipe segment 102 in an assembled form, the second end 20 and its associated components are shown in an exploded view to better illustrate the components of the assembly 100.

As described above, the assembly 100 includes the pipe coupling 10 and the flexible pipe segment 102 described above. The flexible pipe segment 102 has segments 106 formed to allow one or more of the segments 106 to collapse together to reduce the overall length of the flexible pipe segment 102 or vice versa to allow the one or more segments to expand/move apart to axially increase the overall length of the flexible pipe segment 102. The segments 106 are also formed to allow one or more of the segments 106 to pivot relative to another segment 106 to accommodate the shape of the flexible pipe segment 102.

As shown in fig. 4, the first end 18 of the connector body 12 has been inserted into the end of the flexible pipe segment 102, i.e., pushed into the end of the flexible pipe segment 102. Retainer device 30 engages and secures tubing connector 10 to flexible tubing segment 102 and ferrule 14 to connector body 12.

The ferrule 14 is configured to extend over and engage the outer surface of the flexible pipe segment 102. The retainer device 42 engages and secures the ferrule 14 to the flexible pipe segment 102.

In the assembly 100 shown in fig. 4, the second end 20 defines a compression-type connector, the inner diameter of the second end 20 is sized to receive the end of the second pipe segment 104, and the threaded connection 34 engages a corresponding threaded connection 108 on a nut 110.

As shown in fig. 4, a compression ring 112 can be disposed about the second pipe segment 104, and the compression ring 112 is inserted between the second end 20 of the connector body 12 and the second pipe segment 104 when assembled to provide a secure engagement between the second end 20 and the second pipe segment 104 when the threaded connections 34 and 108 are engaged. A sealing device in the form of an O-ring sealing element 114 may be disposed around the second pipe segment 104 and interposed between the compression ring 112 and the nut 110 when assembled.

Referring now to FIG. 5 of the drawings, an alternative pipe connector 1010 is shown.

As shown in fig. 5, the pipe connector 1010 includes a connector body 1012 and a ferrule 1014, the ferrule 1014 being configured for positioning on the connector body 1012. The connector body 1012 is generally tubular in construction, having an axial through bore 1016 therethrough, the axial through bore 1016 defining an axial flow passage through the connector body 1012. The connector body 1012 has a first male end 1018 configured for insertion into an interior of the flexible pipe segment 102 (shown in fig. 7) and for engaging the interior of the flexible pipe segment 102, and a second end 1020 for coupling to the second pipe segment 104 (shown in fig. 7) to connect the flexible pipe segment 102 to the second pipe segment 104. The first end 1018 and the second end 1020 are separated by a flanged portion 1022, the flanged portion 1022 providing an end stop for the cuff 1014 in use.

Referring now also to fig. 6 of the drawings, fig. 6 shows an enlarged view of a portion of the connector body 1012 shown in fig. 5, the first end 1018 of the connector body 1012 being substantially identical to the first end 18 described above.

As with the first end 18, the first end 1018 of the connector body 1012 has a distal section 1024, a proximal section 1026, and a tapered section 1028 that is interposed between the distal and proximal sections 1024, 1026 and forms a transition between the distal and proximal sections 1024, 1026. In use, the distal segment 1024 forms a leading end of the connector 1012 for insertion into the flexible tube segment 102. The proximal section 1026 is adjacent to the flange portion 1022.

As shown in fig. 6, the outer diameter of the proximal section 1026 is greater than the outer diameter of the distal section 1024, and the tapered section 1028 defines a ramp angle. In use, the bevel angle may secure or assist in securing the first end 1018 of the connector body 1012 to the interior of the flexible pipe segment 102, the friction between the tapered section 1028 and the interior of the flexible pipe segment 102 securing or assisting in securing the first end 18 of the connector body 1012 to the interior of the flexible pipe segment 102 as the first end 1018 is inserted into the flexible pipe segment 102. First end 1018 of connector body 1012 has a constant inner diameter along its length, although the outer diameter of first end 1018 varies along its length.

A retainer device 1030 is formed on an outer surface of the first end 1018, the retainer device 1030 being configured to engage an interior of the flexible pipe segment 102. In the illustrated connector 1010, a retainer device 1030 is formed on the proximal section 1026 of the first end 1018.

In use, upon insertion of the first end 1018 of the connector body 1012 into the end of the flexible pipe segment 102, the retainer device 1030 allows the flexible pipe segment 102 to pass over the retainer device 1030 in a first axial direction (i.e., the direction that connects the flexible pipe segment 102 and the connector body 1012 together), but prevents or inhibits movement of the flexible pipe segment 102 in a second axial direction (i.e., the direction that moves the connector body 1012 and the flexible pipe segment 102 apart).

Advantageously, the retainer device 1030 is configured to engage the interior of the flexible pipe segment 102 without rotating the connector body 1012.

As shown in fig. 6, in the illustrated connector 1010, the retainer device 1030 takes the form of a plurality of ribs 1032. Each rib 1032 defines a ramp or ratchet profile that allows the flexible tube segment to pass over the rib 1032 in a first axial direction (i.e., the direction that connects the flexible tube segment 102 and the connector body 1012 together), but prevents or inhibits movement of the flexible tube segment 102 in a second axial direction (i.e., the direction that moves the connector body 1012 and the flexible tube segment 102 apart).

As described above, collar 1014 is configured for positioning over first end 1018, and retainer device 1030 is also configured to retain collar 1014 on connector body 1012, ribs 1032 allowing collar 1014 to pass over retainer device 1030 in a first axial direction but preventing or inhibiting movement of collar 1014 in a second axial direction.

Thus, in use, when ferrule 1014 is positioned over first end 1018 of connector body 1012, retainer device 1030 allows ferrule 1014 to pass over retainer device 1030 in a first axial direction (i.e., the direction that couples ferrule 1014 and connector body 1012 together), but prevents or inhibits movement of ferrule 1014 in a second axial direction (i.e., the direction that moves connector body 1012 and ferrule 1014 apart).

As described above, the second end 1020 of the connector body 1012 is used to couple to the second tube segment 104 to connect the flexible tube segment 102 to the second tube segment 104.

In the illustrated connector 1010 shown in fig. 5 and 6, the second end 1020 defines a flat end. In use, the second end 1020 is secured to the second pipe segment 104 by an interference fit and/or by fasteners such as glue.

Fig. 7 illustrates a pipe assembly 1100 incorporating the pipe connector 1010 shown in fig. 5.

As shown in fig. 7, the assembly 1100 includes the pipe coupling 1010 and the flexible pipe segment 102 described above. The first end 1018 of the connector body 1012 has been inserted into the end of the flexible pipe segment 102, i.e., pushed into the end of the flexible pipe segment 102. Retainer device 1030 engages and secures tubing connector 1010 to flexible tubing segment 102 and ferrule 1014 to connector body 1012.

The collar 1014 is configured to extend over and engage the outer surface of the flexible pipe segment 102. The retainer device 1042 engages and secures the collar 1014 to the flexible pipe segment 102.

In the assembly 1100 shown in fig. 7, the second end 1020 defines a flat end, and the inner diameter of the second end 1020 is sized to receive the end of the second pipe segment 104. However, it will be appreciated that the second end 1020 may alternatively define a male end for insertion into the second pipe segment 104. In the assembly 1100, the second end 1020 is secured to the second tube segment 104 by an interference fit and/or by glue.

Referring now to fig. 8 of the drawings, an alternative conduit connector 2010 is shown.

As shown in fig. 8, the pipe connector 2010 includes a connector body 2012 and a ferrule 2014, the ferrule 2014 being configured for positioning on the connector body 2012. The connector body 2012 is generally tubular in construction with an axial through bore 2016 passing therethrough, the axial through bore 2016 defining an axial flow passage through the connector body 2012. The connector body 2012 has a first male end 2018 configured for insertion into the interior of the flexible pipe segment 102 (shown in fig. 10) and for engaging the interior of the flexible pipe segment 102, and a second end 2020 for coupling to the second pipe segment 104 (shown in fig. 10) to connect the flexible pipe segment 102 to the second pipe segment 104. The first end 2018 and the second end 2020 are separated by a flange portion 2022, which flange portion 2022 provides an end stop for the ferrule 2014 in use.

Referring now also to fig. 9 of the drawings, fig. 9 shows an enlarged view of a portion of the connector body 2012 shown in fig. 8, the first end 2018 of the connector body 2012 being substantially identical to the first end 18 described above.

As with the first end 18, the first end 2018 of the connector body 2012 has a distal section 2024, a proximal section 2026, and a tapered section 2028, the tapered section 2028 being interposed between the distal section 2024 and the proximal section 2026 and forming a transition between the distal section 2024 and the proximal section 2026. In use, the distal segment 2024 forms a leading end of the connector 2012 for insertion into the flexible tube segment 102. The proximal section 2026 is adjacent to the flange portion 2022.

As shown in fig. 9, the proximal section 2026 has an outer diameter that is greater than the outer diameter of the distal section 2024, and the tapered section 2028 defines a bevel angle. In use, the bevel angle may secure or assist in securing the first end 2018 of the connector body 2012 to the interior of the flexible tube segment 102, the friction between the tapered section 2028 and the interior of the flexible tube segment 102 securing or assisting in securing the first end 2018 of the connector body 2012 to the interior of the flexible tube segment 102 when the first end 2018 is inserted into the flexible tube segment 102. While the outer diameter of first end 2018 varies along its length, first end 2018 of connector body 2012 has a constant inner diameter along its length.

Formed on the outer surface of the first end 2018 is a retainer device 2030 that is configured to engage the interior of the flexible tube segment 102. In the illustrated connector 2010, a retainer device 2030 is formed on a proximal section 2026 of the first end 2018.

In use, upon insertion of the first end 2018 of the connector body 2012 into the end of the flexible pipe segment 102, the retainer device 2030 allows the flexible pipe segment 102 to pass over the retainer device 2030 in a first axial direction (i.e., the direction that connects the flexible pipe segment 102 and the connector body 2012 together), but prevents or inhibits movement of the flexible pipe segment 102 in a second axial direction (i.e., the direction that moves the connector body 2012 and the flexible pipe segment 102 apart).

Advantageously, the retainer device 2030 is configured to engage the interior of the flexible tubing segment 102 without rotating the connector body 2012.

As shown in fig. 9, in the illustrated connector 2010, the retainer device 2030 is in the form of a plurality of ribs 2032. Each rib 2032 defines a ramp or ratchet profile that allows the flexible tube segment 102 to pass over the rib 2032 in a first axial direction (i.e., the direction that connects the flexible tube segment 102 and the connector body 2012 together), but prevents or inhibits movement of the flexible tube segment 102 in a second axial direction (i.e., the direction that moves the connector body 2012 and the flexible tube segment 102 apart).

As described above, ferrule 2014 is configured for positioning on the first end 2018, and the retainer device 2030 is further configured to retain the ferrule 2014 on the connector body 2012, the rib 2032 allowing the ferrule 2014 to pass over the retainer device 2030 in the first axial direction but preventing or inhibiting movement of the ferrule 2014 in the second axial direction.

Thus, in use, when the ferrule 2014 is positioned at the first end 2018 of the connector body 2012, the retainer device 2030 allows the ferrule 2014 to pass over the retainer device 2030 in a first axial direction (i.e., the direction that connects the ferrule 2014 and the connector body 2012 together), but prevents or inhibits movement of the ferrule 2014 in a second axial direction (i.e., the direction that moves the connector body 2012 and the ferrule 2014 apart).

As described above, the second end 2020 of the connector body 2012 is for coupling to the second tube segment 104 to connect the flexible tube segment 102 to the second tube segment 104.

In the illustrated connector 1010 shown in fig. 8 and 9, the second end 2020 has an inner diameter sized to receive an end of the second pipe segment 104. Nut 2110 is disposed about second end 2020. The compression ring 2112 is disposed on the end of the second end 2020 and is inserted between the nut 2110 and the second pipe segment 104 such that rotation of the nut 2110 compresses the compression ring 2112 into fixed engagement with the second pipe segment 104.

It will be appreciated that the above embodiments are merely exemplary and that various modifications may be made thereto without departing from the scope of the invention as defined by the claims.