阅读说明：本技术 用于流体管路组件的联接器 (Coupling for fluid line assembly ) 是由 J·W·帕蒂森二世 于 2019-07-10 设计创作，主要内容包括：一种联接器,包括第一联接器、第二联接器、密封件和摩擦构件。第一联接器可连接到第一流体管路,并且包括具有凹槽的第一轴向端面。第二联接器可连接到第二流体管路,并且可与第一联接器联接以限定穿过其中的通路。第二联接器包括具有通道的第二轴向端面。第二轴向端面可与第一轴向端面接触。密封件被接收在凹槽内,并且适于紧靠第二联接器的第二轴向端面,以防止流体从通路中泄漏。摩擦构件被接收在通道内,并且适于接合第一联接器的第一轴向端面,以限制第一联接器和第二联接器之间的扭转运动。(A coupling including a th coupling, a second coupling, a seal, and a friction member, a th coupling is connectable to the th fluid line and includes a th axial end face having a groove, the second coupling is connectable to the second fluid line and is coupleable with the th coupling to define a passage therethrough, the second coupling includes a second axial end face having a channel, the second axial end face is contactable with the th axial end face, the seal is received within the groove and is adapted to abut the second axial end face of the second coupling to prevent fluid leakage from the passage, the friction member is received within the channel and is adapted to engage a th axial end face of the th coupling to limit torsional movement between the th coupling and the second coupling.)

1, A coupler for a fluid line assembly, the fluid line assembly including a th fluid line and a second fluid line, the coupler comprising:

an th coupling adapted to connect to the th fluid line and including a th axial end face having a groove;

a second coupler adapted to be connected to the second fluid line and coupleable with the th coupler to collectively define a passage therethrough for fluidly connecting the th fluid line with the second fluid line, the second coupler including a second axial end face having a channel, the second axial end face contactable with the th axial end face;

a seal at least partially received within the groove and adapted to abut the second axial end face of the second coupling to prevent fluid leakage from the passageway; and

a friction member at least partially received within the channel and adapted to engage the axial end face of the th coupling to limit torsional movement between the th coupling and the second coupling.

2. The coupling of claim 1, wherein:

the recess is an annular groove and the seal comprises an annular seal, an

The channel is an annular channel, and the friction member comprises an annular ring,

the annular groove and the annular channel are both disposed around the passageway.

3. The coupling of claim 1, wherein the seal is disposed radially proximal of the passageway and the friction member is disposed radially distal of the passageway.

4. The coupler of claim 1, further comprising a locking nut for securing the coupler with the second coupler.

5. The coupling of claim 1, wherein the groove has a cross-sectional area less than a cross-sectional area of the channel.

6. The coupling of claim 1, wherein the friction member is formed of an elastomer.

7. The coupling of claim 1, wherein the seal is formed of an elastomer.

8. The coupling of claim 1, wherein the th axial end face includes a th plane, the friction member including a friction face in contact with the th plane.

9. The coupling of claim 1, wherein the second axial end surface includes a second planar surface and the seal includes a sealing surface in contact with the second planar surface.

10, a fluid line assembly, comprising:

a fluid line and a second fluid line, and

a coupling, comprising:

an th coupling adapted to connect to the th fluid line and including a th axial end face having a groove;

a second coupler adapted to be connected to the second fluid line and coupleable with the th coupler to collectively define a passage therethrough for fluidly connecting the th fluid line with the second fluid line, the second coupler including a second axial end face having a channel;

a seal at least partially received within the groove and adapted to abut the second axial end face of the second coupling to prevent fluid leakage from the passageway; and

a friction member at least partially received within the channel and adapted to engage the axial end face of the th coupling to limit torsional movement between the th coupling and the second coupling.

Technical Field

The present invention relates generally to fluid line assemblies and, more particularly, to couplers that fluidly couple fluid lines of fluid line assemblies to .

Background

Fluid systems that facilitate the generation of fluid power may include a plurality of hoses, pipes, and tubes that collectively facilitate the transfer of fluid from portions of the fluid system to another portions to help perform or more functions.

However, some of the currently available couplers lack the robustness of stabilizing the connection between two fluid lines, both during and after assembly of the two fluid lines, for example, fluid lines may twist with respect to the other fluid lines, increasing the likelihood of fluid leakage (or the occurrence of fluid leakage) at the joint between the two fluid lines formed by the coupler.

U.S. patent No. 5,645,301 (' 301 reference) relates to a fitting that includes and a second coupler, the and second couplers being held at by a nut with their front end surfaces in contact with each other one or more tongue and groove sealing mechanisms are interposed between the front end surfaces of the interfaces to provide a fluid tight seal.

Disclosure of Invention

In aspects, the present invention is directed to a coupler for a fluid conduit assembly of the type comprising a th fluid conduit and a second fluid conduit, the coupler comprising a th coupler, a second coupler, a seal, and a friction member, the th coupler being adapted for connection to the th fluid conduit and comprising a th axial end face having a groove, the second coupler being adapted for connection to the second fluid conduit and being coupleable with the th coupler to collectively define a passage for fluidly connecting the th fluid conduit with the second fluid conduit, the second coupler comprising a second axial end face having a channel, the second axial end face being contactable with the th axial end face, the seal being at least partially received within the groove and adapted to abut against the second axial end face of the second coupler to prevent fluid leakage from the passage.

In another aspect, the invention relates to a fluid line assembly including a 0 th fluid line, a second fluid line, and a coupler, the coupler including a 1 th coupler, a second coupler, a seal, and a friction member, the th coupler being adapted to be connected to the th fluid line and including a th axial end face having a groove, the second coupler being adapted to be connected to the second fluid line and being coupleable with the th coupler to collectively define a passageway for fluidly connecting the th fluid line with the second fluid line, the second coupler including a second axial end face having a channel, the seal being at least partially received within the groove and adapted to abut against the second axial end face of the second coupler to prevent fluid leakage from the passageway, the friction member being at least partially received within the channel and adapted to engage the th axial end face of the th coupler to limit torsional movement between the second coupler and the second coupler.

Drawings

FIG. 1 is an exemplary fluid circuit assembly depicted in partial cross-sectional view in accordance with an embodiment of the present invention; and

fig. 2 is a side cross-sectional view of the fluid line assembly of fig. 1, in accordance with an embodiment of the present invention.

Detailed Description

Referring to fig. 1 and 2, a fluid line assembly 100 is shown. The fluid circuit assembly 100 may be employed in a fluid system that may be configured to perform various functions in a variety of environments. For example, the fluid system may include a hydraulic system that may be used to perform functions related to implement control, linkage control, braking, and the like in construction machines, forestry machines, marine machines, agricultural machines, mining machines, generator sets, and the like. Aspects of the invention may also be applied in various other environments, such as in fluid systems in homes and commercial establishments.

Fluid line assembly 100 includes a second fluid line 110, a second fluid line 112, and a coupler 114 fluidly connecting the two fluid lines 110, 112 to one another fluid connection between the second fluid line 110 and the second fluid line 112, obtained through use of coupler 114, is such that fluid may be transferred between the fluid line 110 and the second fluid line 112 through the coupler 100. more specifically, coupler 114 may define a passageway 118 to facilitate transfer of fluid therethrough. both the fluid line 110 and the second fluid line 112 may include and/or represent tubes, pipes, hoses, etc. in embodiments, or both of the fluid line 110 and the second fluid line 112 may include and/or represent inlets (not shown) and/or outlets (not shown) of different components/elements of an associated fluid system. coupler 100 includes a second coupler 130, a second coupler 132, a seal 134, and a friction member 136. coupler 100 also includes a lock nut 132 for securing the second coupler 130 to the second coupler .

The th coupler 130 is adapted to be coupled to the th fluid line 110. the 0 th coupler 130 may include a generally cylindrical shape, although other shapes and contours of the 1 th coupler 130 are also contemplated 2 th coupler 130 includes a 3 th axial end 152, a second axial end 154, and a st generally cylindrical conduit 158 defining a axis 160. the th conduit 158 extends from the th axial end 152 to the second axial end 154. the th axial end 152 includes a th axial end face 162, and the th conduit 158 leads to the th axial end face 162.

The th coupler 130 includes a groove 168 formed on the th axial end face 162. the groove 168 may be an annular groove configured around the th conduit 158 (or the passageway 118). in the embodiments, the groove 168 is concentrically formed around the th conduit 158 and defines a th average diameter D1. although not limited, the cross-section of the groove 168 may include a rectangular profile (or a square profile), as shown.

Additionally, the -th coupler 130 may include a -th threaded portion 190 and a second threaded portion 192, the -th threaded portion 190 may be formed relatively adjacent the -th axial end 152 and the second threaded portion 192 may be formed relatively adjacent the second axial end 154, the -th threaded portion 190 may be adapted to engage the lock nut 138 and the second threaded portion 192 may be adapted to engage the threaded end 198 of the -th fluid line 110.

In embodiments, as shown, the coupler 130 may include a radially extending flange 210, the flange 210 being configured and arranged between the th threaded portion 190 and the second threaded portion 192 the flange 210 may include a polygonal shape that may be engaged by a wrench or spanner (not shown) to facilitate tightening/loosening of the coupler 130 relative to the th fluid line 110 and/or relative to the locking nut 114.

Second connector 132 may be adapted to be coupled to second fluid line 112. for example, second connector 132 may be coupled to second fluid line 112 via threaded connection 212. in addition, second connector 132 may also be coupled (e.g., retentively coupleable) with third coupler 130 to in combination define passage 118 therethrough (fluidly connect third fluid line 110 with second fluid line 112 as described above.) for example, second connector 132 includes a generally cylindrical shape and has a generally cylindrical second conduit 224 configured therein. second conduit 224 defines second axis 218, and second conduit 224 and third conduit 158 collectively define passage 118 of coupler 114. in embodiments, upon assembly of third coupler 130 with second coupler 132, third axis 160 may be aligned with second axis 218.

The coupling between the second coupling 132 and the coupling 130 may define a joint 290 therein, the first axial end face 162 and the second axial end face 240 may meet and/or contact each other at the joint 290 to facilitate fluid transfer through the passageway 118, as shown by the enlarged designation 310 of the joint 290 in fig. 2, the gap between the second axial end face 162 and the second axial end face 240 is generally enlarged.

Second coupler 132 includes a flanged end 234 defining a second axial end face 240 of second coupler 132, second conduit 224 leading to second axial end face 240. second coupler 132 may include a channel 246 formed on second axial end face 240. channel 246 may be an annular channel configured around second conduit 224 (or passage 118. in embodiments, channel 246 is formed concentrically around second conduit 224 and defines a second average diameter D2. in accordance with aspects of the present invention, second average diameter D2 is greater than average diameter D1 as with cross-section of groove 168, the cross-section of channel 246 may also include a rectangular (or square) profile.

The lock nut 138 may be used to effect assembly and engagement between the coupler 130 and the second coupler 132. the lock nut 138 may include an L-shaped cross-section as shown that defines a nut-shaped body 262 and a locking edge 264 extending radially inward from of the axial end 270 of the nut-shaped body 262. the nut-shaped body 262 may include internal threads 276. when the coupler 130 is assembled to the second coupler 132, the threaded portion 190 may engage the internal threads 276 of the nut-shaped body 262 and the locking edge 264 may engage the flange end 234 of the second coupler 132. thus, the coupler 130 and the second coupler 132 may be coupled together at .

It may be noted that in embodiments, the coupler 130 may be formed integrally with the fluid line 110 . in this case, the second axial end 154 and the second threaded portion 192 of the coupler 130 may not be present. additionally, or alternatively, the second coupler 132 may also be formed integrally with the second fluid line 112 . in this case, the threaded connection 212 may not be present, and the coupling between the coupler 130 and the second coupler 132 may be accomplished solely through the use of the locking nut 138.

Seal 134 may be adapted to be positioned between axial end face 162 and second axial end face 240 to seal a joint 290 formed by assembling coupler 130 to second coupler 132. in this manner, seal 134 may prevent fluid from leaking from passageway 118. for example, seal 134 may be an annular seal that may be at least partially received within groove 168 of coupler 130 and may be adapted to abut against second axial end face 240 of second coupler 132 to obtain an effective seal at joint 290. for example, seal 134 may include a sealing surface 294 that may contact second planar surface 258 of second axial end face 240. in exemplary embodiments, seal 134 may include an elastomeric material and may form an O-ring. in embodiments of further , seal 134 may be formed from an elastomeric material, including but not limited to rubber (e.g., nitrile rubber) and/or other elastomers.

Friction member 136 may be an anti-rotation device and may be positioned between coupler 130 and second coupler 132, adapted to limit rotation between coupler 130 and second coupler 132. for example, friction member 136 may be positioned between axial end face 162 and second axial end face 240. according to one or more aspects of the invention , friction member 136 is at least partially received within channel 246 and is adapted to engage axial end face 162 of coupler 130 to limit torsional movement between coupler 130 and second coupler 132. for example, friction member 136 may include friction face 306, which friction face 306 may contact flat face 184 of axial end face 162.

In embodiments, friction member 136 may comprise an annular ring or O-ring formed of an industry standard elastomeric material or elastomeric material, such as rubber (e.g., nitrile rubber) and/or other elastomers.in embodiments, friction member 136 comprises a smaller cross-sectional area than the cross-sectional area of seal 134. however, in some cases, friction member 136 may comprise a larger cross-sectional area than the cross-sectional area of seal 134. in some cases, the cross-sectional area of friction member 136 may be equal to the cross-sectional area of seal 134. in embodiments, friction member 136 may also act as a seal between axial end face 162 and second axial end face 240. in this way, friction member 136 may define a second level leakage checkpoint (after seal 134 defines a level leakage checkpoint) for checking and preventing fluid leakage from passageway 118.

Further, where second average diameter D2 is greater than average diameter D1, seal 134 may be disposed radially proximal of conduit 158 (and thus proximal of passageway 118 defined by coupler 114) and friction member 136 may be disposed relatively distal of second conduit 224 (and thus distal of passageway 118 defined by coupler 114). accordingly, in examples, friction member 136 may include a diameter greater than the diameter of seal 134. in embodiments, friction face 306 of friction member 136 may include knurling, high friction coating, or the like, to increase the coefficient of friction between friction face 306 and plane 184 during operation and/or assembly and to limit torsional movement or rotation between axial end face 162 and second axial end face 240, as well as torsional movement or rotation between coupler 130 and second coupler 132.

In exemplary embodiments, the friction members 136 may comprise an intermittent array of friction members (not shown) formed over the entire curvature of the friction members 136 and may be in contact with the th planar surface 184 of the axial end face 162. for example, the friction members may be formed and aligned in a manner that facilitates unidirectional torsional movement of the th coupler 130 with respect to the second coupler 132 assembly while preventing reverse torsional movement between the second coupler 130 and the second coupler 132. in this case, the friction members 136 may act as sacrificial elements suitable for disassembly in the event that the th coupler 130 needs to be disassembled from the second coupler 132.

Industrial applicability

During assembly, an operator may first couple second coupler 130 with fluid line 110 to couple 0 th coupler 130 with 1 th fluid line 110, the operator may engage flange 210 of th coupler 130 using a wrench to tighten and secure coupler 130 to th fluid line 110. second connector 132 may be coupled to second fluid line 112 via threaded connection 212. in some embodiments, th coupler 130 may be in body with th fluid line 110 and therefore may not require a coupling therebetween, similarly, in some cases, second coupler 132 may be in body with second fluid line 112, and in such cases, second coupler 132 need not be coupled to second fluid line 112 via threaded connection 212.

After coupling the coupler 130 with the th fluid line 110 and the second coupler 132 with the second fluid line 112, the locking edge 264 of the locking nut 138 may be engaged with the flanged end 234 of the second coupler 132 and the internal threads 276 of the nut-shaped body 262 may be in contact and engaged with the th threaded portion 190 of the coupler 130, and then the internal threads 276 of the locking nut 138 may be threadably coupled with the th threaded portion 190 of the th coupler 130. thus, the th coupler 130 is coupled to the second coupler 132. further, the axis 160 may be aligned with the second axis 218 and the joint 290 may be defined by the coupler 114. in this manner, a fluid coupling may be established between the th fluid line 110 and the second fluid line 112.

Additionally, upon assembly being established between -th coupling 130 and second coupling 132, seal 134 may contact second axial end face 240 (or second flat surface 258) and friction member 136 may contact -th axial end face 162 (or -th flat surface 184.) specifically, sealing surface 294 may contact second flat surface 258 of second axial end face 240 and friction face 306 may contact -th flat surface 184 of -effectively, seal 134 may provide a positive seal between -th axial end face 162 and second axial end face 240, and thus may establish a sealed joint or connection between -th fluid conduit 110 and second fluid conduit 112 to facilitate fluid transfer from -th fluid conduit 110 through passageway 118 to second fluid conduit 112 or from second fluid conduit 112 to -th fluid conduit 110.

In addition, the friction member 136 may be used to limit rotation between the axial end face 162 and the second axial end face 240 (or between the th coupling 130 and the second coupling 132.) by using the friction member 136, the joint 290 formed between the th coupling 130 and the second coupling 132 may not be altered by various adverse factors, including operating vibrations, etc., experienced by the coupling 114 during operation (and/or during assembly).

It will be apparent to those skilled in the art that various modifications and variations can be made in the system of the present invention without departing from the scope of the invention. Other embodiments will be apparent to those skilled in the art from consideration of the specification and practice of the system disclosed herein. It is intended that the specification and examples be considered as exemplary only, with a true scope of the disclosure being indicated by the following claims and their equivalents.