SYSTEM AND METHOD FOR CHARGING AND SEALING PRESSURE VESSELS
A redundant sealing system includes a seal assembly for a vacuum or pressurized gas or liquid container, where the container has a fill port opening and a boss extending from a surface of the container. The boss has a passage aligned with the opening, and the passage has a threaded portion. The seal assembly includes a port plug having a nose portion with a surface shaped to mate with the fill port opening in the container and a set screw portion with external threads for engaging the threaded portion of the passage through the boss to press the nose portion into the fill port opening to form a first seal. The seal assembly further includes a weld plug sized to close the distal end of the passage through the boss, the weld plug is welded to the boss to form a second seal.
Latest RAYTHEON COMPANY Patents:
- Ultra high entropy material-based non-reversible spectral signature generation via quantum dots
- Coaxial-to-waveguide power combiner/divider comprising two fins disposed in a plane of the waveguide and connected to plural coaxial inputs/outputs
- Anti-fragile software systems
- Photonic integrated circuit-based transmissive/reflective wavefront optical phase control
- Bolometer readout integrated circuit (ROIC) with energy detection
This invention is directed to a pressure or vacuum container, and more particularly to a high pressure gas container having an improved seal for extended shelf life.
BACKGROUNDHigh pressure gas containers find many uses, including in guided missiles. In a missile, the pressurized gas provides a compact source of energy that can be used, for example, for uncaging gyros, cooling detector elements of infrared seekers, moving control surfaces, etc. These containers can be very small, making them difficult to fill and seal while maintaining a low leak rate.
One commonly used fill method involves a small diameter tube which breaches the inner volume of the bottle. After the container is filled with gas through the tube, it is resistance welded in several places and then welded shut at its distal end. This general design has been in use for more than 20 years throughout the industry.
Other preceding pressurized containers for missiles relied principally on a metal-to-metal seal to confine the gas within the container. Some of these seals depended upon a threaded union, while others have used a pressed in plug. Both of these designs require an extremely good surface finish to obtain a seal that will retain the gas in the container. Other seals were formed by molding a soft metal over the opening of the container.
SUMMARY OF THE INVENTIONMetal-to-metal seals can be imperfect, allowing the confined gas to slowly leak out of the container, shortening its shelf life. Since guided missiles are often stored for a long time before they are used, the potential of a shortened shelf life increases the risk that the container will not contain sufficient gas when it is needed, which can render the missile useless. Additionally, preceding seals were often not physically robust to mishandling, were not robust to environmental conditions, and/or were not robust to contamination. Despite these shortcomings, they continued to be used because other techniques were unavailable, did not fit into the available volume, or were more expensive and therefore not suitable for typical qualities of missile subsystems.
The present invention provides a redundant sealing system that uses both a deformable plug to fill the opening and form an initial seal and a secondary welded seal that can be formed with the addition of a metal cap and an inexpensive orbital welder.
More particularly, the present invention provides a seal assembly for a pressure container, where the container has a fill port opening and a boss extending from a surface of the container. The boss has a passage aligned with the opening, and the passage has a threaded portion. The seal assembly includes a port plug having a nose portion with a surface shaped to mate with the fill port opening in the container and a set screw portion with external threads for engaging the threaded portion of the passage through the boss to press the nose portion into the fill port opening to form a seal. The seal is an initial or first seal and the seal assembly further includes a weld plug, sized to close the distal end of the passage through the boss. The weld plug is welded to the boss to form a second seal. Naturally, the present invention also provides a pressurized container having such a seal assembly for sealing the opening and the passage.
The present invention also provides a method of charging a container and then sealing the container to provide an extended shelf life. The method includes the following steps: (a) providing a container having an opening therein and a boss extending from a surface of the container adjacent the opening, the boss having a passage aligned with the opening in the container, the passage being at least partially threaded with internal threads, a port plug that includes a nose portion for closing the fill port opening in the container and a set screw portion with external threads for engaging the threaded portion of the boss; (b) inserting the port plug in the passage with the nose portion closer to the opening than the set screw portion; (c) charging the container via the passage; (d) torquing the threaded port plug to advance the port plug in the passage until the nose portion engages the surface of the container adjacent the opening to create the initial or first seal; (e) installing a weld plug into an outer end of the boss to close the passage through the boss; and (f) welding the weld plug to the boss to create a second seal.
According to another aspect of the invention, the invention provides a container with a seal assembly, where the container has an opening therein and a boss extending from a surface of the container adjacent the opening. The boss has a passage aligned with the opening in the container, and the passage is at least partially threaded with internal threads. The container and seal assembly further include means for sealing the opening in the container, adjacent the opening at a proximal end of the passage through the boss, and means for sealing the passage through the boss, adjacent a distal end of the passage through the boss.
In an exemplary embodiment, the opening-sealing means includes a port plug having a nose portion with a surface shaped to mate with the fill port opening in the container and a set screw portion with external threads for engaging the threaded portion of the passage through the boss to press the nose portion into the fill port opening to form a seal. And the passage-sealing means includes a weld plug sized to close the distal end of the passage, the weld plug being welded to the boss to form a second seal.
The foregoing and other features of the invention are hereinafter fully described and particularly pointed out in the claims, the following description and annexed drawings setting forth in detail certain illustrative embodiments of the invention, these embodiments being indicative, however, of but a few of the various ways in which the principles of the invention may be employed.
As discussed above, prior pressure containers suffered from a number of problems in providing a hermetic seal. For example, some containers were not robust to mishandling, environmental conditions, or contamination, or the sealing method required a high capital cost to implement. In addition, previous sealing methods for pressure containers often leak excessively over time, were not compact and occupied a large volume, or provided no redundancy in the sealing method.
In contrast, the present invention provides a compact, inexpensive, and redundant sealing method. The pressure container includes an opening for filling with a pressurized gas or liquid. A first element is pressed against an annular surface adjacent the opening and fills and closes the opening itself. In the process, this first element deforms to mate with the annular surface and provide an initial or a first seal. A second element holds the first element against the container and is removable to release or replace the first element in the event that this initial seal is ineffective or otherwise compromised. A third element is then mounted over the first and second elements and welded in-place to provide a second seal in the event that the initial seal is breached.
The resulting pressure container is physically small, uses common manufacturing methods, and provides a robust, redundant seal that can be made in the field. Factory conditions are not required to establish either the first seal or the second seal. Moreover, the first seal can be tested before creating the second seal and if the initial first seal fails, the first seal can be reworked before the second seal is applied.
An exemplary system and method for sealing a container 10 is shown in
An exemplary container 10 is made of steel, such as stainless steel, and has a wall thickness of approximately 0.07 inches (about 1.8 mm). An exemplary stainless steel for the container is Carpenter Custom 455 stainless steel, from Carpenter Technology Corporation of Wyomising, Pa., U.S. Such a container has been found to withstand high internal pressures, up to approximately 25,000 psig (about 172,400 kPa). The boss 16 is in effect a short, permanent tube secured to or formed as an integral part of the container 10. An exemplary boss 16 is cylindrical and has a diameter of approximately 0.25 inches (about 6.4 mm) and a length or height of about 0.30 (about 7.6 mm) in length.
The passage 20 through the boss 16 to the fill port opening 14 has a threaded portion 22 at a distal end 24 thereof for receiving a port plug 26. The illustrated port plug 26 has a nose portion 30 and a set screw portion 32. In the illustrated embodiment the nose portion 30 and the set screw portion 32 are separate components, but they could be formed as a single part. The nose portion 30 can be made of a malleable material, such as a plastic or a metal, and in the illustrated embodiment the nose-portion 30 has a generally cone-like shape. Other shapes can work as well. An exemplary nose portion 30 is made of brass, such as brass 360. The illustrated nose portion 30 also has a support post or shank 34 extending from a base or distal end of the cone-like shape.
Referring now to
A distal end 46 of the set screw portion 32 includes a driving feature 50 for engaging and driving the set screw portion 32 along the threaded portion 22 of the passage 20 through the boss 16. For example, an exemplary driving feature 50 includes a hexagonal socket formed in a distal end of the set screw portion 32. An exemplary socket 50 is sized to receive a nominal 1/16 inch (approximately 1.6 mm) hexagonal wrench or key. Other types of driving features, such as for receiving a screwdriver, are alternative options. An exemplary set screw portion 32 is made of stainless steel and, more particularly, Nitronic® 60, available from AK Steel Corporation of West Chester, Ohio, United States. Nitronic® 60 is an austenitic stainless steel. The illustrated set screw portion 32 is tubular, and the socket 36 is formed by a hole or passage that extends part or all the way through the set screw portion 32, facilitating the delivery of pressurized gas to the container 10 when the port plug 26 is in the passage 20 in the boss 16. A slot 48 in the side of the set screw portion 26 provides another path for gas to flow past the set screw portion 26 and into the container 10.
After the container 10 is filled with pressurized gas or evacuated, the port plug 26, inserted in the passage in the boss 16 either before or after charging with or evacuating the gas, is advanced by torqueing the set screw portion 32 to press the nose portion 30 against the surface of the container 10 adjacent the fill port opening 14. Since the nose portion 30 is made of a malleable material, continuing to torque the set screw portion 32 deforms the nose portion 30 to mate with that surface adjacent the fill port opening 14, as shown in
If testing shows that the first seal has good integrity, then a weld plug 60 is placed over the distal end 24 of the boss 16 and welded in place to provide a second seal, redundant to the first seal. Because the port plug 26 is entirely within the passage 20 through the boss 16, the weld plug 60 and the boss 16 form a hermetically-sealed chamber over both the port plug 26 and the fill port opening 14. So even if the port plug seal fails, the container 10 will remain sealed by the weld plug 60 and the weld holding it in place. The weld plug 60 typically is made of steel, such as the same steel as the pressure container 10. An exemplary weld plug is approximately 0.060 inches (about 1.5 mm) thick. The weld can be formed with an orbital TIG welder, for example. Such welders are commonly available, generally are small, portable, simple to use, and relatively inexpensive. More importantly, they yield consistent-quality welds with simple operation. Consequently, orbital welders can be used in the field and do not require the precise conditions of a factory environment to form the weld seal. Other types of welding devices can be used to weld the weld plug 60 to the boss 16, however, including laser and electron-beam welders.
As shown in
A sequence of operation of a sealing method provided in accordance with the present invention is shown in
As shown in
Although only one type of weld plug 60 has been shown so far, additional designs also are contemplated within the scope of the present invention.
In
Instead of an axial weld, the weld plug may be provided with a radial weld, as was the case with the embodiments previously shown in
The weld plug designs shown in
Thus the present invention provides a redundant seal for a high pressure gas container 10. First a port plug 26 seats and then deforms a nose 30 portion adjacent a surface surrounding a fill port opening 14 to establish a first seal. The set screw portion 32 both advances the nose portion 30 against the opening 14 and holds the deformed nose 30 in place. A weld plug 60 then caps or covers the port plug 26 and the passage 20 through the boss 16 and is welded in place to provide a second seal for any gas that might escape past the port plug 26.
In addition, the present invention allows the first sealing elements, the port plug 26 and particularly the nose portion 30, to be reworked or replaced if the first seal is tested and fails the test, before the weld plug 60 is added to form the second seal. An exemplary seal assembly provided by the invention has been found to seal over 40,000 psig (about 276,000 kPa) prior to burst. The resulting seal assembly 12 is robust to mishandling, the first seal is protected from environmental conditions and contamination, and the first and second seals can be formed with inexpensive tools that can be used outside a factory setting, in the field. For example, in an air-conditioning maintenance and repair situation, as well as for supplying gas for a missile. Such an exemplary seal assembly is expected to have an approximately 14 year life, at least, with no more than 200 psig (about 1,400 kPa) leak over that 14 year period.
In summary, the present invention provides a redundant sealing system includes a seal assembly 12 for a pressurized container 10, where the container 10 has a fill port opening 14 and a boss 16 extending from a surface of the container 10. The boss 16 has a passage 20 aligned with the opening 14, and the passage 20 has a threaded portion 22. The seal assembly 12 includes a port plug 26 having a nose portion 30 with a surface shaped to mate with the fill port opening 14 in the container 10 and a set screw portion 32 with external threads for engaging the threaded portion 22 of the passage 20 through the boss 16 to press the nose portion 30 into the fill port opening 14 to form a first seal. The seal assembly 12 further includes a weld plug 60 sized to close the distal end of the passage 20 through the boss 16, the weld plug 60 is welded to the boss 16 to form a second seal.
Consequently, the present invention provides a system and method with one or more of the features set forth in the following clauses.
A. A seal assembly 12 for a pressurized container 10, the container 10 having a fill port opening 14 and a boss 16 extending from a surface of the container 10, the boss 16 having a passage 20 aligned with the opening 14, the passage 20 having a threaded portion 22, the seal assembly 12 comprising a port plug 26 having a nose portion 30 with a surface shaped to mate with the fill port opening 14 in the container 10 and a set screw portion 32 with external threads for engaging the threaded portion 22 of the passage 20 through the boss 16 to press the nose portion 30 into the fill port opening 14 to form a seal.
B. A seal assembly 12 as set forth in clause A or any other clause that depends from clause A, where the nose portion 30 is a malleable metal.
C. A seal assembly 12 as set forth in clause B or any other clause that depends from clause B, where the nose portion 30 is brass.
D. A seal assembly 12 as set forth in clause A or any other clause that depends from clause A, where the nose portion 30 has a cone-like shape with a proximal end that is smaller than the opening 14 and a distal end that is larger than the opening 14.
E. A seal assembly 12 as set forth in clause A or any other clause that depends from clause A, where the set screw portion 32 has a drive means at a distal end for engaging the set screw portion 32 and advancing or retracting the set screw portion 32 in the passage 20 relative to the boss 16.
F. A seal assembly 12 as set forth in clause A or any other clause that depends from clause A, where the seal is a first seal and further comprising a weld plug 60 sized to close the distal end of the passage 20 through the boss 16, the weld plug 60 being welded to the boss 16 to form a second seal.
G. A seal assembly 12 as set forth in clause F or any other clause that depends from clause F, where the container 10 and the weld plug 60 are steel.
H. A seal assembly 12 as set forth in clause F or any other clause that depends from clause F, where the weld is one of an axial weld or a radial weld or a combination of the two.
I. A seal assembly 12 as set forth in clause A or any other clause that depends from clause A, where the boss 16 is generally tubular.
J. A seal assembly 12 as set forth in clause A or any other clause that depends from clause A, where the boss 16 has a circular cross-section.
K. A pressurized gas container 10, comprising a fill port opening 14 and a boss 16 extending from a surface of the container 10, the boss 16 having a passage 20 aligned with the opening 14, the passage 20 having a threaded portion 22; and a seal assembly 12 as set forth in clause A or any other clause that depends from clause A, for sealing the opening 14 and the passage 20.
L. A method of charging a container 10 with gas and then sealing the container 10 to provide an extended shelf life, comprising the following steps:
-
- (a) providing a container 10 having a fill port opening 14 therein and a boss 16 extending from a surface of the container 10 adjacent the opening 14, the boss 16 having a passage 20 aligned with the opening 14 in the container 10, the passage 20 being at least partially threaded with internal threads, a port plug 26 that includes a nose portion 30 for closing the fill port opening 14 in the container 10 and a set screw portion 32 with external threads for engaging the threaded portion of the boss 16;
- (b) inserting the port plug 26 in the passage 20 with the nose portion 30 closer to the opening 14 than the set screw portion 32;
- (c) charging the container 10 with a pressurized gas via the passage 20;
- (d) torquing the threaded port plug 26 to advance the port plug 26 in the passage 20 until the nose portion 30 engages the surface of the container 10 adjacent the opening 14 to create a first seal;
- (e) installing a weld plug 60 into an outer end of the boss 16 to close the passage 20 through the boss 16; and
- (f) welding the weld plug 60 to the boss 16 to create a second seal.
M. A method as set forth in clause L or any other clause depending from clause L, where the torquing step includes deforming the nose portion 30 to mate with a surface of the container 10 adjacent the opening 14.
N. A method as set forth in clause L or any other clause that depends from clause L, where the welding step includes forming at least one of a radial weld or an axial weld or a combination of the two.
O. A method as set forth in clause L or any other clause that depends from clause L, where the charging step occurs before the inserting step.
P. A method as set forth in clause L or any other clause that depends from clause L, where the installing step and the welding step are the last two steps, and the installing step occurs before the welding step.
Q. A method as set forth in clause L or any other clause that depends from clause L, comprising the step of testing the integrity of the first seal before the step of installing the weld plug 60.
R. A method as set forth in clause Q or any other clause that depends from clause Q, where if the testing step shows that the first seal is inadequate, removing and replacing the port plug 26 and then repeating the testing step until an adequate seal is obtained.
S. A gas container 10 with a seal assembly 12, the container 10 having a fill port opening 14 therein and a boss 16 extending from a surface of the container 10 adjacent the opening 14, the boss 16 having a passage 20 aligned with the opening 14 in the container 10, the passage 20 being at least partially threaded with internal threads; means for sealing 26 the opening 14 in the container 10, adjacent the opening 14 at a proximal end of the passage 20 through the boss 16; and means for sealing 60 the passage 20 through the boss 16, adjacent a distal end of the passage 20 through the boss 16.
T. A container 10 and seal assembly 12 as set forth in clause S or any other clause that depends from clause S, where the opening-sealing means includes a port plug 26 having a nose portion 30 with a surface shaped to mate with the fill port opening 20 in the container 10 and a set screw portion 32 with external threads for engaging the threaded portion 22 of the passage 20 through the boss 16 to press the nose portion 30 into the fill port opening 14 to form a seal, and the passage-sealing means includes a weld plug 60 sized to close the distal end of the passage 20, the weld plug 60 being welded to the boss 16 to form a second seal.
Although the invention has been shown and described with respect to a certain illustrated embodiments, equivalent alterations and modifications will occur to others skilled in the art upon reading and understanding the specification and the annexed drawings. In particular regard to the various functions performed by the above described integers (components, assemblies, devices, compositions, etc.), the terms (including a reference to a “means”) used to describe such integers are intended to correspond, unless otherwise indicated, to any integer which performs the specified function (i.e., that is functionally equivalent), even though not structurally equivalent to the disclosed structure which performs the function in the illustrated embodiments of the invention.
Claims
1. A seal assembly for a pressurized container, the container having a fill port opening and a boss extending from a surface of the container, the boss having a passage aligned with the opening, the passage having a threaded portion, the seal assembly comprising a port plug having a nose portion with a surface shaped to mate with the fill port opening in the container and a set screw portion with external threads for engaging the threaded portion of the passage through the boss to press the nose portion into the fill port opening to form a seal.
2. A seal assembly as set forth in claim 1, where the nose portion is a malleable material.
3. A seal assembly as set forth in claim 2, where the nose portion is brass.
4. A seal assembly as set forth in claim 1, where the nose portion has a cone-like shape with a proximal end that is smaller than the opening and a distal end that is larger than the opening.
5. A seal assembly as set forth in claim 1, where the set screw portion has a drive means at a distal end for engaging the set screw portion and advancing or retracting the set screw portion in the passage relative to the boss.
6. A seal assembly as set forth in claim 1, where the seal is a first seal and further comprising a weld plug sized to close the distal end of the passage through the boss, the weld plug being welded to the boss to form a second seal.
7. A seal assembly as set forth in claim 6, where the container and the weld plug are steel.
8. A seal assembly as set forth in claim 6, where the weld is one of an axial weld and a radial weld or a combination of the two.
9. A seal assembly as set forth in claim 1, where the boss is generally tubular.
10. A seal assembly as set forth in claim 1, where the boss has a circular cross-section.
11. A pressurized container, comprising a fill port opening and a boss extending from a surface of the container, the boss having a passage aligned with the opening, the passage having a threaded portion; and a seal assembly as set forth in claim 1 for sealing the opening and the passage.
12. A method of charging a container with gas or liquid and then sealing the container, comprising the following steps:
- (a) providing a container having an opening therein and a boss extending from a surface of the container adjacent the opening, the boss having a passage aligned with the opening in the container, the passage being at least partially threaded with internal threads, a port plug that includes a nose portion for closing the fill port opening in the container and a set screw portion with external threads for engaging the threaded portion of the boss;
- (b) inserting the port plug in the passage with the nose portion closer to the opening than the set screw portion;
- (c) charging the container with a pressurized gas or liquid via the passage;
- (d) torquing the threaded port plug to advance the port plug in the passage until the nose portion engages the surface of the container adjacent the opening to create a first seal;
- (e) installing a weld plug into an outer end of the boss to close the passage through the boss; and
- (f) welding the weld plug to the boss to create a second seal.
13. A method as set forth in claim 12, where the torquing step includes deforming the nose portion to mate with a surface of the container adjacent the opening.
14. A method as set forth in claim 12, where the welding step includes forming at least one of a radial weld or an axial weld or a combination of the two.
15. A method as set forth in claim 12, where the charging step occurs before the inserting step.
16. A method as set forth in claim 12, where the installing step and the welding step are the last two steps, and the installing step occurs before the welding step.
17. A method as set forth in claim 12, comprising the step of testing the integrity of the first seal before the step of installing the weld plug.
18. A method as set forth in claim 17, where if the testing step shows that the first seal is inadequate, removing and replacing the port plug and then repeating the testing step until an adequate seal is obtained.
19. A gas container with a seal assembly, the container having an opening therein and a boss extending from a surface of the container adjacent the opening, the boss having a passage aligned with the opening in the container, the passage being at least partially threaded with internal threads; means for sealing the opening in the container, adjacent the opening at a proximal end of the passage through the boss; and means for sealing the passage through the boss, adjacent a distal end of the passage through the boss.
20. A container and seal assembly as set forth in claim 19, where the opening-sealing means includes a port plug having a nose portion with a surface shaped to mate with the fill port opening in the container and a set screw portion with external threads for engaging the threaded portion of the passage through the boss to press the nose portion into the fill port opening to form a seal, and the passage-sealing means includes a weld plug sized to close the distal end of the passage, the weld plug being welded to the boss to form a second seal.
Type: Application
Filed: Nov 4, 2011
Publication Date: May 9, 2013
Applicant: RAYTHEON COMPANY (Waltham, MA)
Inventors: Paul M. Lyons (Tucson, AZ), Christopher E. Pentland (Vail, AZ)
Application Number: 13/289,400
International Classification: B65D 51/16 (20060101); B65B 1/04 (20060101);