The present concept relates to pipe joints which accommodate pipe expansion and movement and more particularly to rotary joints between adjacent lengths of pipe which are interconnected to form a pipeline for carrying fluids which are under moderate to high pressure and temperature.
Rotary couplings have been used in the oil and gas industry and also in other fluid handling industries for a number of years. Oil pipelines associated with exploration drilling commonly include a series of interconnected sections of steel pipe each of which include a male connecting piece at one end a female connecting piece at the other end. The inlets and outlets to be connected by such pipelines can be at various positions relative to one another. It is not always possible or practical to provide rigid pipelines particularly suited to all applications.
Consequently it is a common practice to interconnect lengths of pipe of various configurations using a rotary or swivel joint to accommodate dynamic pipe expansion relative axial rotation of adjacent lengths of pipe that can occur.
Rotary couplings often use annular sealing or packing rings axially compressed between adjacent internal radially extended faces of male and female connecting pieces.
In practice the reliability and maneuverability of rotary couplings has been an issue and therefore there is a need for a rotary coupling which is extremely reliable under severe conditions while also being easy to manipulate in the field.
The present concept of a rotary coupling comprising:
Preferably wherein the seal end of connector pipe includes a packing relief defined by a taper.
The present concept a rotary coupling comprising:
Preferably wherein the compression screws moveable between an engaged and disengaged position such that in the dis-engaged position the compression pressure against the z-ring and packing seals is released by backing off the compression screws without disassembly of the rotary coupling.
Preferably wherein the Z-ring including an inner step portion and an outer step portion wherein the diameter of the inner step less than the diameter of the outer step.
Preferably further including a pipe gap between an abutment and a seal end of connector pipe 104.
Preferably wherein one wall of the packing chamber including the outer diameter of connector pipe 104.
Preferably wherein the seal end of connector pipe includes a packing relief defined by a taper.
Preferably wherein the boundaries of the packing chamber defined by the outer diameter of connector pipe, the packing end of the Z-ring, a chamber bottom and a chamber outer diameter of the outer section.
Preferably wherein the inner diameter of the packing relief is less than the outer diameter D2 of connector pipe 104.
Preferably wherein the taper includes a variation in the outer diameter of the connector pipe D2 and D1 wherein D2 is greater than or equal to D1 wherein D2 is closer to the seal end than D1.
The present concept will now be described by way of example only with reference to the following drawings in which:
Referring first of all to
Outer section 102 includes a male end 116, female end 118 abutments 120 and threaded portion 122. Z-ring 108 includes an inner step portion 191 and an outer step portion 193 wherein the diameter of the inner step less than the diameter of the outer step.
Connector pipe 104 includes an outer diameter D1130, and outer diameter D2132, a connector pipe end 134, a connection end 136, a shoulder 138 and a packing relief 140 having an inner diameter 141. Male end 116 and connection end 136 are connected to pipes normally by welding to the ends.
Outer section 102 is machined to accommodate a retainer ring 110 which engages with the threaded portion 122 of outer section 102.
Outer section 102 is furthered shaped with a Z-ring relief 109 to accommodate Z ring 108 as shown in
Outer section 102 together with the seal end 134 of connector pipe 104 as well as the packing end 144 and Z-ring 108 define a packing chamber 150 which is shown in greater detail in
The boundaries of the packing chamber 150 are defined by the outer diameters D1 and/or D2 of connector pipe, the packing end 144 of the Z-ring, a chamber bottom 171 and a chamber outer 173 diameter of the outer section.
In particular a packing relief 140 is defined by a difference in outer diameter of D2 shown as 132 and outer diameter D1130 of connector pipe 104. In practice D2 is greater than D1 thereby creating a taper 160 within seal end 134 of connector pipe 104. Taper 160 may be linear or curved either concave or convex. It is possible that D1 and D2 may be equal i.e. with no taper.
The inventor surprisingly found that the packing relief 140 defined by taper 160 which is developed due to the change in the outer diameter D2132 to D1130 creates a substantially superior seal when using compression packing seals 106 of the type shown in
In use firstly Z-ring 108 is placed onto seal end 134 of connector pipe 104 followed by one or more annular packing seals 106.
Thereafter connector pipe 104 slips into female end 118 of outer section 102 followed by retainer ring 110 which is thread-ably received by threaded portion 122. Thereafter compression screws 112 are thread-ably engaged into retainer ring 110 and finally annular snap ring 114 is placed into ring groove 115.
Annular packing seals 106 are compressed by the thread-ably engaging compression screws 112 which abut against screw end 142 of Z-ring 108 which in turn abuts against packing seals 106 at packing end 144 of Z-ring 108. An advantage in the current design is the ability to tighten engage and loosen disengage compression screws 112. For example compression screws 112 could be tightened in place for pressure testing of the joint and then subsequently loosened for shipping an A-frame configuration 200 in a collapsed position and after on site installation retightening the compression screws 112.
By using the Z-ring 108 configuration one is able to locate the packing seals 106 as close as possible to the outer diameter of connector pipe 104, thereby reducing overall joint torque resistance. In comparison to ball and socket joints the present rotary joint 100 creates less rotational resistance even when compression screws 112 are fully engaged. In other words it takes significantly less torque to rotate rotary joint 100 than an ball and socket joint in the same application.
Further by utilizing a packing relief 140 namely by machining in a taper 160 wherein outer diameter D2132 is greater than outer diameter D1130 of connector pipe 104. This packing chamber 150 geometry improves seal performance.
In this manner annular packing seals 106 are compressed not only in the longitudinal direction 162 but there is also some movement or urging of the annular packing seal in the lateral direction 164 against the outer diameter D2132 of connector pipe 104.
Referring now to
Referring now to
In practice A frame configuration 200 and/or two coupling configuration 300 may be used in order to accommodate thermal expansion contraction and movement of interconnecting pipes in a piping system.
Some of the advantages of the rotary coupling are as follows.
The rotary coupling can be adjusted to relieve the load on the packing member while not affecting the length & orientation of inner or outer section by backing off the compression screws.
The rotary coupling can be adjusted to compensate for seal degradation over time while not affecting the length & orientation of the inner or outer sections by tightening the compression screws
The rotary coupling uses a packing relief 140 in seal end 134 of connector pipe 104 to create a pressure activated seal from the internal media pressure.
The rotatory coupling uses compression packing to create an internal seal containing hot and corrosive media. This is possible through careful selection of material for packing seals 106. The simple annular ring shape and design of packing seals allows a multitude of different materials to be used for packing seals 106.
The rotary coupling employs an offset gland ring or Z-ring 108 to allow for a packing chamber 150 as close as possible to the OD of connector pipe 104.
The rotary coupling provides a smooth internal flow path with allowing a full 360 degree of rotation between the connector pipe 104 and outer section 102 for pipe sizes larger than 2″.
The rotary coupling arranged in such a manner to allow for thermal growth between two ends of a system by providing a pipe gap 181 and a shoulder gap 183.
It should be apparent to persons skilled in the arts that various modifications and adaptation of this structure described above are possible without departure from the spirit of the invention the scope of which defined in the appended claim.
Number | Name | Date | Kind |
---|---|---|---|
1204822 | Roylance | Nov 1916 | A |
1525101 | McWane | Feb 1925 | A |
1575259 | Fisher | Mar 1926 | A |
1831956 | Harrington | Nov 1931 | A |
2901273 | Morris, Jr. | Aug 1959 | A |
3411526 | Schaefer | Nov 1968 | A |
3420555 | Faccou | Jan 1969 | A |
3679235 | Faccou | Jul 1972 | A |
3724877 | Thut | Apr 1973 | A |
3840264 | Bennett | Oct 1974 | A |
4221408 | Lochte | Sep 1980 | A |
4229024 | Oberrecht | Oct 1980 | A |
Number | Date | Country |
---|---|---|
696784 | Jan 1931 | FR |
1246290 | Nov 1960 | FR |
978461 | Dec 1964 | GB |
2132297 | Jul 1984 | GB |
Number | Date | Country | |
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20160341345 A1 | Nov 2016 | US |