CLAYTON R DALLAS (US)
CLAYTON R DALLAS (US)
| US0646590A | 1900-04-03 | |||
| US2478818A | 1949-08-09 | |||
| US3792878A | 1974-02-19 | |||
| US4027901A | 1977-06-07 | |||
| US4066281A | 1978-01-03 | |||
| US4705307A | 1987-11-10 | |||
| CA461456A | 1949-11-29 |
| 1. | In a plastic vacuumcomponent for use in a vacuum system, said vacuumcomponent comprising at least one main bodyportion having a first end portion, a second endportion, an outer surface , an inner surface , and a hollow, interior volume bounded by said inner surface , at least said first endportion defining an opening into said hollow, interior volume, at least said first endportion being capable of vacuumsealed connection to a mating part of a vacuum system, the improvement comprising: said first endportion of said main body portion comprising groove means comprising a groove formed in, and extending about, a portion of the outer surface of said first endportion; and elastomericsealing means for sealing the connection of said first endportion with a mating part of another part of a vacuum system; said elastomeric sealing means comprising an elastomeric ringmember at least a portion of which is received in said groove of said first end portion. |
| 2. | CLAIM. |
| 3. | The plastic vacuumcomponent for use in a vacuum system according to claim 1, wherein said groove means comprises a first, interior, vertical, annular wall having an upper end and a lower end; a second, intermediate, annular wall having a first end and a second end, said first end of said second wall being connected to, and forming an acute angle with, said lower end of said first wall; said groove SUBSTITUTE SHEET of said groove means being located between said first and second walls; and a third, exterior, sloping, annular wall having an interior end and an exterior end, said interior end being connected to said second end of said second wall and forming an acute angle with respect to said second end of said, intermediate wall, said third wall extending in a direction from said second wall opposite to the direction that said second wall extends from said first wall. |
| 4. | CLAIM. |
| 5. | The plastic vacuumcomponent for use in a vacuum system according to claim 3, wherein said elastomeric ringmember comprises an interiorfacing annular portion and an exteriorfacing annular portion; said interiorfacing annular portion comprising a first, interior, vertical, annular wallsurface for abutment against said first, interior, vertical annular wall of said groove means, said first, interior, vertical, annular wall surface having an upper end and a lower end; and a second, intermediate, annular wallsurface having a first end and a second end, said first end of said second, annular wallsurface being connected to, and forming an acute angle with, said lower end of said first, annular wallsurface, said interior facing annular portion being received in and retained by said groove means. |
| 6. | CLAIM. |
| 7. | The plastic vacuumcomponent for use in a vacuum system according to claim 3, wherein said exteriorfacing annular portion comprises a third. SUBSTITUTE SHEET exterior, sloping annular wallsurface having an interior end and an exterior end, for abutment against said third, exterior, sloping annular wall of said groove means; and a fourth, exteriorfacing, annular wallsurface having an upper end and a lower end, which is used for abutment against a portion of a mating part of a vacuum system; said interior end of said third wallsurface being connected to said second end of said second wallsurface. |
| 8. | CLAIM. |
| 9. | The plastic vacuumcomponent for use in a vacuum system according to claim 4, wherein said exteriorfacing annular portion of said elastomeric member comprises a fifth, annular wallsurface connecting said exterior end of said third wall surface to said lower end of said fourth wall surface. |
| 10. | CLAIM. |
| 11. | The plastic vacuumcomponent for use in a vacuum system according to claim 5, wherein said fifth, annular wallsurface has an inner diameter substantially equal to the inner diameter of said main bodyportion, said inner diameter of said main bodyportion being the diameter of said hollow, interior volume, whereby said main body portion does not itself contact against a mating part of a vacuum system in which it is emplaced. |
| 12. | CLAIM. |
| 13. | The plastic vacuumcomponent for use in a vacuum system according to claim 5, wherein said fourth, exteriorfacing annular wallsurface of said elastomeric ringmember forms an acute angle with respect a vertical plane, so that, when the vacuum SUBST.TUTE SHEET component is emplaced in a vacuum system, said fourth annular wallsurface is drawn into a contact against a mating surface in stages in order to prevent virtual gas leaks; said fourth, annular wallsurface sloping outwardly from said first end of said main body portion, with said upper end thereof lying in a vertical plane spaced from a vertical plane in which lies said lower end thereof. |
| 14. | CLAIM. |
| 15. | The plastic vacuumcomponent for use in a vacuum system according to claim 1, wherein said second endportion of said main body portion comprises another groove means comprising another groove formed in, and extending about, the outer surface of said second endportion; and another elastomericsealing means for sealing the connection of said second endportion with a mating part of another part of a vacuum system; said another elastomeric sealing means comprising an another elastomeric ringmember at least a portion of which is received in said groove of said second endportion. |
| 16. | CLAIM. |
| 17. | In a plastic vacuumcomponent for use in a vacuum system, said vacuumcomponent comprising at least one main bodyportion having a first end portion, a second endportion, an outer surface , an inner surface , and a hollow, interior volume bounded by said inner surface , at least said first endportion defining an opening into said hollow, interior volume, said first endportion being capable of vacuumsealed connection to a mating part SUBSTITUTE SHEET of a vacuum system, the improvement comprising: said first endportion of said vacuum component comprising groove means comprising an annular groove formed in, and extending about, a portion of the outer surface of said first end portion in which may be received an elastomeric sealing for sealing the connection of said first endportion with a mating part of a vacuum system. |
| 18. | CLAIM. |
| 19. | The plastic vacuumcomponent for use in a vacuum system according to claim 9, wherein said groove means comprises a first, interior, vertical, annular wall having an upper end and a lower end; a second, intermediate, annular wall having a first end and a second end, said first end of said second wall being connected to, and forming an acute angle with, said lower end of said first wall; said groove of said groove means being located between said first and second walls; and a third, exterior, sloping, annular wall having an interior end and an exterior, said interior end being connected to said second end of said second wall and forming an acute angle with respect to said second end of said, intermediate wall, said third wall extending in a direction from said second wall opposite to the direction that said second wall extends from said first wall. |
| 20. | CLAIM. |
| 21. | The plastic vacuumcomponent for use in a vacuum system according to claim 9, wherein said vacuumcomponent is a tubular pipe, each of said first and second endportions being open to said SUBSTITUTE SHEET hollow, interior volume. |
| 22. | CLAIM. |
| 23. | The plastic vacuumcomponent for use in a vacuum system according to claim 9, wherein said vacuumcomponent is one of a crossconnector and a valveconnector; said main bodyportion being a tubular element forming part of said vacuum component. |
| 24. | CLAIM. |
| 25. | An elastomeric, sealing ring for use with an end of a plastic vacuumcomponent for coupling the end of the plastic vacuumcomponent to a mating part of a vacuum system, comprising: an interiorfacing annular portion and an exteriorfacing annular portion; said interior facing annular portion comprising a first, interior, annular wallsurface having an upper end and a lower end; and a second, intermediate, annular wall surface having a first end and a second end, said first end of said second, annular wallsurface being connected to, and forming an acute angle with, said lower end of said first, annular wallsurface. |
| 26. | CLAIM. |
| 27. | The plastic vacuumcomponent for use in a vacuum system according to claim 13, wherein said exteriorfacing annular portion comprises a third, exterior, sloping annular wallsurface having an interior end and an exterior end; and a fourth, exteriorfacing, annular wallsurface having an upper end and a lower end, which is used for abutment against a portion of a mating part of a SUBSTITUTE SHEET vacuum system; said interior end of said third wall surface being connected to said second end of said second wallsurface. |
| 28. | CLAIM. |
| 29. | The plastic vacuumcomponent for use in a vacuum system according to claim 14, wherein said exteriorfacing annular portion of said elastomeric member further comprises a fifth, annular wall surface connecting said exterior end of said third wallsurface to said lower end of said fourth wall surface. |
| 30. | CLAIM. |
| 31. | The plastic vacuumcomponent for use in a vacuum system according to claim 14, wherein said fourth, exteriorfacing annular wallsurface of said elastomeric ring forms an acute angle with respect a vertical plane, so that, when the vacuumcomponent is emplaced in a vacuum system, said fourth annular wallsurface is drawn into a contact against a mating surface in stages in order to prevent virtual gas leaks; said upper end thereof lying in a vertical plane spaced farther away from said interiorfacing annular portion of said elastomeric ring than a vertical plane in which lies said lower end thereof. |
| 32. | CLAIM. |
| 33. | In a plastic vacuumcomponent for use in a vacuum system, said vacuumcomponent comprising at least one main bodyportion having a first end portion, a second endportion, an outer surface , an inner surface , and a hollow, interior volume bounded by said inner surface , at least said first endportion defining an opening into said hollow, interior volume, at least said first endportion being capable of vacuumsealed connection to a mating part of a vacuum system, the improvement comprising: elastomericsealing means for sealing the connection of said first endportion with a mating part of another part of a vacuum system. |
| 34. | CLAIM. |
| 35. | The plastic vacuumcomponent for use in a vacuum system according to claim 17, wherein said first endportion of said main body portion comprises groove means comprising a groove formed in, and extending about, a portion of the outer surface of said first endportion; said elastomericsealing means comprising an elastomeric ringmember at least a portion of which is received in said groove of said first end portion. |
| 36. | CLAIM. |
| 37. | The plastic vacuumcomponent for use in a vacuum system according to claim 17, comprising another elastomericsealing means for sealing the connection of said second endportion with a mating part of another part of a vacuum system. |
| 38. | CLAIM. |
| 39. | The plastic vacuumcomponent for use in a vacuum system according to claim 19, wherein said second endportion comprises another groove means comprising another groove formed in, and extending about, the outer surface of said second endportion for receiving at least a part of said another elastomericsealing means. |
| 40. | CLAIM. |
| 41. | A method of connecting an end of a plastic, male vacuumcomponent to a female component in a vacuum system in order to prevent real and virtual leaks therebetween, comprising: a) attaching an elastomeric sealing member to the end of the male vacuumcomponent; b) after said step (a) , inserting the end of the male vacuumcomponent into a female vacuum component until the elastomeric sealing member is in at least partial contact with a mating surface portion of the female vacuumcomponent; c) creating at least a partial vacuum in the vacuumsystem in which the male vacuumcomponent has become part of during said step (b) ; d) said step (c) causing the elastomeric sealing member to be drawn completely against the mating surfaceportion of the female vacuum component. |
| 42. | CLAIM. |
| 43. | The method according to claim 21, wherein said step (b) comprises contacting an outer, annular surfaceportion of the elastomeric sealing member against the mating surfaceportion of the female vacuumcomponent, and allowing the remainder of the exterior surface of the elastomeric sealing member to be spaced from the mating surface portion of the female vacuumcomponent; said step (d) causing the remainder of the exterior surface of the elastomeric sealing member that is spaced from the mating surfaceportion of the female vacuumcomponent to be drawn into contact SUBSTIT against corresponding parts of the mating surface portion of the female vacuumcomponent, in order to prevent virtual leaks in the vacuumsystem at the connection of the end of the male vacuumpart with the female vacuumpart. |
| 44. | CLAIM. |
| 45. | The method according to claim 22, wherein the elastomeric sealing member has an inwardlysloping, exterior, annular surface, whereby, when said step (b) is performed, the an outer, annular portion of the inwardlysloping, exterior, annular surface contacts against a corresponding surface of the female vacuum component; said step (d) causing the inwardlysloping, exterior, annular surface to be gradually and increasingly drawn, in a wedgelike manner, into contact against mating surfaceportions of the female vacuumcomponent, until all of the inwardly sloping, exterior, annular surface comes into contact with mating surfaceportions of the female vacuumcomponent, whereby gas molecules located between the juxtapositioned surfaces of the end of the male vacuumcomponent and female vacuum component are forced outwardly into the hollow interior of the vacuumcomponents in order to be pumped away. SUBSTITUTE SHEET. |
BACKGROUND OF THE INVENTION
Field of The Invention (Technical Field)
The Invention relates specifically to an improved method of joining plastic socket fit piping components for vacuum, pressure, and structural applications where a leak and contamination free connection is needed. Background Art
Plastic socket fit components are commonly used in the assembly of piping systems. Traditional socket fit components require permanent cemented or welded assembly. This type of assembly is not well suited for clean vacuum or pressure piping systems due to the potential for contamination entrapment voids between the female socket inside diameter and the inserted male component outside diameter. Often, the cement used to join the male component to the female socket is a source of contamination to the process vacuum, gas or fluid. In addition, cemented joints have been known to fail in certain basic applications, such as compressed air service, where the integrity of the cement is compromised by oil in the compressed air.
SUMMARY OF THE INVENTION The invention is an improved method of joining plastic socket fit piping components for vacuum, pressure and structural applications. The Clean Socket Fit Connection provides a leak and contamination free connection that is easy and economical to make. A unique Dual
SUBSTITUTE SHEET
Face/Circumferential Elastomer Seal is installed in a special Seal Groove located on the end of the male component. The male components are then inserted into the female sockets until contact is made between the Dual Face/Circumferential Elastomer Seals and the Female Socket Base Surfaces. The final assembly is evacuated with a vacuum pump to actuate and fully compress the seals. The final assembly is then checked for leaks. If the connections are to remain under vacuum and the ability to disassemble is advantageous, no further work is required. If the assembly is to contain positive pressure or withstand heavy structural forces, a hollow, Heated Retaining Plug is inserted through a Female Socket Retaining Collar and the Female Socket Wall into the Male Component Wall, while the assembly is still under Vacuum Seal Actuation/Compression. The number of Heated Retaining Plugs that are inserted is determined by the amount of pressure and structural force that the assembly is required to contain.
BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated into and form a part of the specification, illustrate the preferred embodiment of the invention and, subsequently, are not to be construed as limiting the invention.
Fig. 1 is an elevation view of a Socket Fit Valve, a Socket Fit Cross, and a Pipe Section;
Fig. 2 is an elevation view of a Pipe Section with the invention Seal Groove installed and with an enlarged view of the invention Seal Groove geometry;
SUBSTITUTE SHEET
Fig. 3 is an elevation view of the Pipe Section shown in Fig. 2 with the invention Dual Face/Circumferential Elastomer Seal installed with an enlarged view of the Seal Circumferential Surface 11 and the Seal Face Surface 10;
Fig. 4 is a cross-sectional elevation view taken on line 4-4 of Fig. 3, with an enlarged view of the Seal Groove and Dual Face/Circumferential Elastomer Seal geometry;
Fig. 5 is an elevation view of a Socket Fit Cross with Female Socket Retaining Collars installed;
Fig. 6 is a plan view of the Socket Fit Cross in Fig. 5 with the Pipe Section shown in Fig. 3 installed;
Fig. 7 is a cross-sectional elevation view taken on line 7-7 of Fig. 6, with an enlarged view of the Dual Face/Circumferential Elastomer Seal relationship to the Female Socket Base Surface 24 prior to Vacuum Seal Actuation/Compression;
Fig. 8 is an elevation view of the Socket Fit Cross in Fig. 7, with an enlarged view of the Dual Face/Circumferential Elastomer Seal after Vacuum Seal Actuation/Compression;
Fig. 9 is an elevation view of the Socket Fit Cross in Fig. 8, with an enlarged view of the installed Heated Retaining Plugs;
DESCRIPTION OF THE PREFERRED EMBODIMENTS
Referring to Fig. 1, a plastic Socket Fit Valve 1, a plastic Socket Fit Cross 2 and a plastic Pipe Section 3 are shown to illustrate some of the
SUBSTITUTE SHEET
socket fit components which can utilize the Clean Socket Fit Connection.
Referring to Fig. 2, a plastic Pipe Section With Seal Groove 4 is shown with enlarged detail of the Seal Groove 5 geometry that is installed on the end of male components through cutting or molding. The Seal Groove 5 geometry consists of three basic surfaces; a Seal Groove Primary Compression Surface 6 , a Seal Groove Secondary Compression Surface 7 and a Seal Groove Retaining Surface 8. The function of these surfaces will be explained in later figures.
Referring to Fig. 3, a plastic Pipe Section With Seal Groove 4 is shown with the Dual Face/Circumferential Elastomer Seal 9 stretch installed over the Seal Groove 5 to insure that a tight fit is created. The enlarged detail shows the Seal Circumferential Surface 11 and the Seal Face Surface 10, which will be described further in later figures.
Referring to Fig. 4, a cross section of the plastic Pipe Section With Seal Groove 4 and Dual Face/Circumferential Elastomer Seal 9 in Fig. 3 is shown. The enlarged detail in this figure shows the geometry of the Dual Face/Circumferential Elastomer Seal 9, which consists of the following surfaces; a Seal Face Surface 10, a Seal Circumferential Surface 11 that is slightly larger in diameter than the Male Component Outside Diameter Surface 18, a Seal Primary Compression Surface 12, a Seal Secondary Compression Surface 13, a Seal Retaining Surface 14, a Seal Process Contact Surface 15 that is flush with
SUBSTITUTE SHEET
the Male Component Process Contact Inside Surface 19, a Seal Primary Contact Corner 16 and a Seal Secondary Contact Corner 17. The function of these surfaces will be explained in later figures.
Referring to Fig. 5, the plastic Socket Fit Cross 2 from Fig. 1 is shown with Female Socket Retaining Collars 20. These collars are installed at this stage if the Clean Socket Fit Connection is to contain positive pressure or withstand structural forces. The Female Socket Retaining Collar 20 provides multiple Retaining Plug Guide Holes 21, which will be described further in later figures.
Referring to Fig. 6, a plan view of the plastic Socket Fit Cross 2 in Fig. 5 is shown with the plastic Pipe Sections With Seal Grooves 4 from Fig. 3 inserted into each female socket.
Referring to Fig. 7, a cross section of the assembly in Fig. 6 is shown. This figure shows the relationship of the inserted plastic Pipe Section male components to the female sockets prior to Vacuum Seal Actuation/Compression. The enlarged detail shows the Seal Circumferential Surface 11 in contact with the Female Socket Inside Diameter Surface 22 and the Seal Primary Contact Corner 16 touching the Female Socket Primary Contact Base Corner 23. The contact of these surfaces provides a preliminary seal for final Vacuum Seal Actuation/Compression. At this point there is a contamination entrapment area between the Seal Face Surface 10 and the Female Socket Base Surface 24. When the assembly is evacuated with a vacuum pump, the male component is pulled into the female socket
SUBSTITUTE SHEET
until the Seal Secondary Contact Corner 17 contacts the Female Socket Secondary Contact Base Corner 25. The progressive elimination of the gap between the primary seal contact corner and the secondary contact corner minimizes the potential for trapped gas pockets in the Seal Face Surface 10. This substantially reduces the potential for a vacuum virtual leak. A vacuum virtual leak is a leak that is not external in nature but, rather, a trapped gas volume that slowly leaks into the assembly interior vacuum space. Vacuum virtual leaks are difficult to locate with conventional leak detection equipment that is designed to detect a leak from the exterior of the assembly to the interior or visa-versa. The Seal Process Contact Surface 15 separates the Male Component Process Contact Inside Surface 19 from the Female Component Process Contact Inside Surface 26. Any contact between the component inside surfaces prior to a seal surface would create a contamination entrapment area. The Seal Process Contact Surface 15 prevents the creation of a contamination entrapment area while presenting a minimum amount of elastomer surface area to the contained process. This provides a smooth boreline transition between the Male Component Process Contact Inside Surface 19 and the Female Component Process Contact Inside Surface 26. The minimal amount of exposed elastomer reduces the amount of gas that is able to permeate through the Dual Face/Circumferential Elastomer Seal 9 material. Referring to Fig. 8, the assembly in Fig. 7 is shown after the assembly has been evacuated with a vacuum pump until full Vacuum Seal
SUBSTITUTE
Actuation/Compression 32 has been achieved. Full Vacuum Seal Actuation/Compression 32 is accomplished through the following sequence of events. When vacuum is applied to the assembly, the male component is drawn into the female socket actuating the seal in three stages. In the first stage, the Seal Groove Primary Compression Surface 6 pushes against the Seal Primary Compression Surface 12. This progressively eliminates the gap between the Seal Face SurfacelO and the Female Socket Base Surface 24 from the Seal Primary Contact Corner 16 towards the Seal Secondary Contact Corner 17. When this gap elimination is approximately half completed, the second stage Seal Groove Secondary Compression Surface 7 pushes against the Seal Secondary Compression Surface 13 which completes the elimination of the gap between the Seal Face Surface 10 and the Female Socket Base Surface 24 while directing the compression force on the Dual Face/Circumferential Elastomer Seal 9 toward the Seal Primary Compression Area 27. In the final stage of Vacuum Seal Actuation/Compression 32, the Dual Face/Circumferential Elastomer Seal 9 is extruded toward the Seal Secondary Compression Area 28 until the Vacuum Seal Actuation/Compression 32 force is equal to the force of the vacuum pressure on the male component surface area causing the Seal Process Contact Surface 15 to bulge slightly. The Seal Process Contact Surface 15 bulge indicates full Vacuum Seal Actuation/Compression 32.
Referring to Fig. 9, the assembly in Fig. 8 is shown with the addition of Heated Retaining
SUBSTITUTE SHEET
Plugs 29 that are inserted through Retaining Plug Guide Holes 21 in the Female Socket Retaining Collars 20 until the plugs fully penetrate the Female Socket Wall 30 and partially penetrate the Male Component Wall 31 while the Dual Face/Circumferential Elastomer Seal 9 is under full Vacuum Seal Actuation/Compression 32. The number of Heated Retaining Plugs 29 that are inserted is determined by the amount of pressure the connection is required to contain and/or the amount of structural force the connection is required to withstand.
SUBSTITUTE SHEET