The disclosure generally relates to systems and methods for storing high-pressure gas, and more particularly, to burst discs for systems storing high-pressure gas.
Gas storage at high pressure may require a non-resealable mechanism to release the gas and prevent rupture of the gas storage unit in the event of overpressurization. Overpressurization can be caused by changes in surrounding temperature or an overfill of the gas storage unit. For example, a nearby fire may change the surrounding temperature proximate the gas storage unit. Without a gas release mechanism in such a situation, the gas storage unit may rupture and cause significant damage to the surroundings or harm to nearby people.
Moving seals and valves have been used to direct the flow of released gas in the event of overpressurization and to guide the flow to flow paths of adequate size for timely discharge of the pressure. However, these moving seals and valves contain moving parts that increase the risk of failure or system fault. What is needed is a new system to allow released gas to flow out a flow path.
In an embodiment of the present disclosure, a gas storage system is provided. The gas storage system comprising a vessel configured for gas storage under a pressure and having a port; a first flow path in pneumatic communication with the port; a first burst disc disposed in the first flow path such that the gas flow in the first flow path is prevented by the first burst disc, and the first burst disc configured to permit gas flow at a first burst pressure; a second flow path in pneumatic communication with the first flow path, downstream from the first burst disc; and a second burst disc disposed in the second flow path such that gas flow in the second flow path is prevented by the second burst disc, the second burst disc configured to permit gas flow at a second burst pressure, which is less than the first burst pressure.
In another embodiment of the present disclosure, a regulator for a gas storage system is provided. The regulator comprising a first flow path configured to be in pneumatic communication with a port of a vessel; a first burst disc disposed in the first flow path such that the gas flow in the first flow path is prevented by the first burst disc, and the first burst disc configured to permit gas flow at a first burst pressure; a second flow path in pneumatic communication with the first flow path, downstream from the first burst disc; and a second burst disc disposed in the second flow path such that gas flow in the second flow path is prevented by the second burst disc, the second burst disc configured to permit gas flow at a second burst pressure.
In another embodiment of the present disclosure, a method for providing a gas is disclosed. The method comprising providing a gas flow through a first burst disc along a first flow path, wherein a pressure for the gas flow is at a first value and a second burst disc along a second flow path connected to the first flow path remains intact; increasing the pressure to a second value higher than the first value; and bursting the second burst disc when the pressure is at the second value.
In another embodiment of the present disclosure, a method for overpressure gas release is provided. The method comprises storing a gas in a gas storage unit connected to a first burst disc and a second burst disc downstream of the first burst disc, wherein a pressure for the gas is at a first value and the first burst disc and the second burst disc remain intact; causing the pressure to increase to a second value higher than the first value; bursting the first burst disc when the pressure is at the second value; and bursting the second burst disc after the first burst disc when the pressure is at the second value.
For a fuller understanding of the nature and objects of the disclosure, reference should be made to the following detailed description taken in conjunction with the accompanying drawings, in which:
A burst disc, also known as a rupture disc or a burst diaphragm, is a non-resealable pressure relief device, configured to prevent gas flow through a channel when intact, and to permit gas flow when ruptured (for example, through operator action or due to overpressure). Burst discs provide quick response to changes in temperature or pressure. In one example, the response may be within milliseconds. Burst discs are reliable, resistant to leaks, and low cost. Burst discs may be used, for example, in applications where high pressure gas is stored and the system is non-refillable or non-reusable.
The system 10 comprises a regulator 20 having a first flow path 22 in pneumatic communication with the port 14 of the vessel 12. The first flow path 22 may be configured to direct a release of gas from the vessel 12 to a breathing mask or system. A first burst disc 24 is disposed in the first flow path 22 and configured to seal the gas flow path 22 such that no gas flow is possible when the first burst disc 24 is intact. The first burst disc 24 has a first burst pressure at which the disc 24 will rupture. The first burst pressure may be configured to be some pressure greater than a maximum pressure of the vessel 12. For example, the first burst pressure may be 1.5 times, 1.75 times, or 2 times the maximum rated pressure of the vessel 12. In other embodiments, the first burst pressure is greater than the operating pressure of the system 10. For example, if the system 10 is designed to operate by providing breathing gas to an air passenger at an operating pressure, the first burst disc 24 can be configured to burst at a first burst pressure which is greater than the operating pressure.
The system 10 may comprise a striker (deliberate gas release device 16) configured to pierce the first burst disc 24 upon action by an operator or an actuator. In the embodiment depicted in
The regulator 20 comprises a second flow path 26 in pneumatic communication with the first flow path 22 and downstream from the first burst disc 24 (i.e., on the opposite side of the first burst disc 24 from the vessel 12). A second burst disc 28 is disposed in the second flow path 26 such that gas flow is prevented through the second flow path 26 when the disc 28 is intact.
Flow through the third flow path 40 may be restricted because the third flow path 40 may have dimensions that are configured to provide a lower flow rate than that of the second flow path 26. In other embodiments, the third flow path 40 has a further pressure regulator or other device to limit the operating pressure of the system 10. This restriction of the operating pressure may be designed for the particular application for which the system 10 is used. However, in an emergency, such as, for example, a rupture of the first burst disc 24 due to an overpressure of the vessel 12, the third flow path 40 may have inadequate flow capacity to enable gas release or may have insufficient volume to ensure safe gas release. The third flow path 40 may have a discharge location or other drawbacks that makes it undesirable for gas release in an emergency.
In such an event, where the gas is released as a result of the first burst disc 24 rupturing due to an overpressure in the vessel 12, the high gas pressure will rupture the second burst disc 28 and the gas is vented through the second flow path 26. The diameter or other dimensions of the second flow path 26 may be configured to enable venting within a certain period of time or meet other specifications. For example, at a given test pressure, such as 100 psia, the second flow path 26 may need to enable flow at a minimum rate which is a function of the size of the vessel 12. The requirements for venting through the second flow path 26 may be set by, for example, trade groups or governmental organizations.
The first flow path 22 and second flow path 26 may be pipes, conduits, channels formed into the regulator 20, etc. The first flow path 22 and second flow path 26 may be angled or may contain other parts or components. Thus, the actual flow geometry can vary as will be apparent to those skilled in the art in light of the present disclosure. A connection between the first flow path 22 and second flow path 26 may be perpendicular or at other angles.
A first burst disc 24 is positioned in the first flow path 22. This first burst disc 24 is exposed to the gas stored in the gas storage unit 12. The first burst disc 24 has a first burst pressure at which it will burst or otherwise rupture or break. In some embodiments, the first burst disc 24 may be part of an assembly. Such an assembly may be integral to the seal or cap of the gas storage unit 12 or may be integral to the gas storage unit 12 itself.
A second burst disc 28 is positioned in the second flow path 26. This second burst disc 28 is downstream of the first burst disc 24 with respect to gas flow from the vessel 12. The second burst disc 28 has a second burst pressure at which it will burst or otherwise rupture or break that is lower than the first burst pressure. Thus, the second burst disc 28 will burst at a lower pressure than the first burst disc 24. The second burst disc 28 may be unpressurized until gas in the gas storage unit 12 is released through or into the first flow path 22 (and, where present, the third flow path 40). The second burst disc 28 is designed to hold integrity when exposed to normal operating pressures, such as when gas is flowing through the first flow path 22 after it is released from the gas storage unit 12. In some embodiments, the second burst disc 28 may be part of an assembly. This assembly may be part of the second flow path 26.
While illustrated as approximately flat, the first burst disc 24 and second burst disc 28 may be domed, curved, or other shapes. A dome shape may help ensure bursting at a particular pressure and the peak of the dome may be pointed in either direction with respect to gas flow. The first burst disc 24 and second burst disc 28 may burst inward or outward with respect to gas flow. The first burst disc 24 or second burst disc 28 may be deliberately damaged in a manner such that it is weakened when burst pressure falls below the pressure in the gas storage unit 12 The first burst disc 24 and second burst disc 28 may fragment upon bursting or may remain attached upon bursting.
In the event of overpressurization in the gas storage unit 12, the first burst disc 24 will burst and then the second burst disc 28 will burst. Thus, the first burst disc 24 and second burst disc 28 are said to “cascade.” Flow through the third flow path 40 may be insufficient to enable venting of the gas storage unit 12 during overpressurization or to prevent the second burst disc 28 from bursting. Thus, the gas may also be vented through the second flow path 26 past the second burst disc 28 after the first burst disc 24 and the second burst disc 28 both burst.
The gas storage system 10 is configured to have a maximum fill pressure (typically measured at a specific temperature) and a rated burst pressure. The rated burst pressure may be set by safety guidelines, such as 1.5 times greater than the maximum fill pressure in one example. The pressure at which the second burst disc 28 will burst may be between the maximum fill pressure and the burst pressure or the lower end of the range at which the first burst disc 24 will burst. The second burst disc 28 may burst below the rated burst pressure. This relationship ensures that if the first burst disc 24 has burst, that the second burst disc 28 also will burst in an overpressurization or other emergency situation. The first burst disc 24 may burst either below or above the rated burst pressure.
The burst pressure ranges for the first burst disc 24 and second burst disc 28 are selected based on the potential application for the gas storage unit 12. A group or lot of the first burst discs 24 and second burst discs 28 may be designed to burst in a particular range rather than at a particular value due to manufacturing tolerances.
While described with respect to pressure, the burst pressure for the first burst disc 24 and second burst disc 28 may be based on temperature because some materials used for the fabrication of the first burst disc 24 or second burst disc 28 may weaken at higher temperatures. The exact pressure or temperature at which the first burst disc 24 and second burst disc 28 will burst may vary based on the application in which the gas storage unit 12 is being used or design specifications.
In one particular example using oxygen, the maximum fill temperature for the gas storage unit 12 is approximately 3000 psig at 70° F. The rated burst pressure for the gas storage unit 12 is 1.5 times the maximum fill pressure, which is 4500 psi. The first burst disc 24 may have a lower burst limit at 4150 psig and an upper burst limit at 4725 psig, of which both pressures are at 70° F. The nominal burst pressure for the first burst disc 24 is 4500 psig. The second burst disc 28 may have a lower burst limit at 3900 psig and an upper burst limit at 4100 psig, of which both pressures are at 70° F.
The upper burst limit for the first burst disc 24 may exceed the maximum fill pressure for the gas storage unit 12. There may be an acceptable tolerance for this upper burst limit beyond the maximum fill pressure. The relationship between the first burst disc 24 and the rated burst pressure may vary with the application in which the gas storage unit 12 is being used. A nominal burst pressure for the first burst disc 24 may be the maximum fill pressure for the gas storage unit 12 in an example. There may be some manufacturing tolerance above or below this nominal burst pressure for the first burst disc 24. For example, approximately 105% of the maximum fill pressure may be allowable on the upper end and approximately 90% of the burst pressure may be allowable on the lower end. The exact tolerances may vary.
The first burst disc 24 and second burst disc 28 may be disposable or may be configured to have a single use. Each may be fabricated of metal, though other materials may be used. The first burst disc 24 and second burst disc 28 may have varying dimensions based on the material, application, maximum fill pressure of the gas storage unit 12, or the gas contained in the gas storage unit 12. In one example, the first burst disc 24 and second burst disc 28 are less than 0.125″ in thickness, though other dimensions are possible. The metal used for the first burst disc 24 and second burst disc 28 may be selected to comply with safety regulations or may be selected in light of the gas being stored in the gas storage unit 12. For example, if oxygen is stored in the gas storage unit 12 then oxygen-safe metals such as brass or nickel alloys like Monel or Inconel may be used. Of course, other metals known to those skilled in the art also may be used depending on the application or gas being stored in the gas storage unit 12.
The first burst disc 24 and second burst disc 28 may weaken when exposed to heat. However, the relationship of the burst pressure range for the first burst disc 24 being above that of the second burst disc 28 may not change with any weakening. This may be caused by the use of similar materials or similar dimensions in the first burst disc 24 and second burst disc 28. Other designs may prevent changes to this relationship upon exposure to heat. For example, one of the first burst disc 24 and the second burst disc 28 may be scored. In one example, the first burst disc 24 is scored in an X-shape. Other designs are possible.
Some embodiments of the gas storage system 10 also includes a deliberate release device 16. This deliberate release device 16 is configured to deliberately puncture or otherwise form a hole in the first burst disc 24. In one instance, the deliberate release device 16 may be known as a striker, though other devices that do not puncture the first burst disc 24 are possible. While illustrated as an arrow in
Puncturing or forming a hole in the first burst disc 24 will release the gas stored in the gas storage unit 12. This may be done on demand. In the event of a puncture or hole formation during normal operation, the second burst disc 28 will maintain integrity. However, in the event of overpressurization after the puncture or hole formation, the second burst disc 28 will burst.
The hole formed in the first burst disc 24 by the deliberate release device 16 may be circular or other shapes. The first burst disc 24 may be scored or may contain perforations to enable a desired gas flow through the first burst disc 24 in the event of a puncture or other hole formation. This scoring may enable the first burst disc 24 to “petal.” Of course, the second burst disc 28 also may be scored or contain perforations. The first burst disc 24 may be configured to enable a desired gas flow rate through a hole or puncture if the deliberate release device 16 is disposed through or proximate the first burst disc 24.
The gas storage system 10 may be used for multiple applications that may require an emergency flow path or vent. For example, the gas storage system 10 may be used with an oxygen tank in an aerospace system, an argon tank used in a welding system, an air tank for diving applications, an oxygen tank in a medical system, or with single-use gas canisters used for manufacturing. Thus, the gas storage unit 12 may contain exotic or even toxic species used in, for example, semiconductor manufacturing. For toxic or other species, the second flow path 26 may be connected to various industrial hygiene systems to prevent damage to people, facilities, or the environment upon venting.
Use of burst discs simplifies the design of the seal for the gas storage system 10 while still meeting pertinent gas standards. Burst discs avoid the use of dynamic seals or 3-2 valves. This reduces complexity and part count, which increases reliability.
With reference to
The regulator 20 has a second flow path 26 in pneumatic communication with the first flow path 22. The second flow path 26 is downstream from the first burst disc 24 with respect to gas flow when the regulator is connected to a vessel. A second burst disc 28 is disposed in the second flow path 26. In this way, gas flow through the second flow path 26 is prevented by the second burst disc 28 when the disc 28 is intact. The second burst disc 28 is configured to permit gas flow at a second burst pressure. The second burst pressure may be less than the first burst pressure.
The present disclosure may be embodied as a method 100 for providing a gas (see, for example,
In other embodiments, a method 200 for overpressure gas release is provided (see, for example,
Although the present disclosure has been described with respect to one or more particular embodiments, it will be understood that other embodiments of the present disclosure may be made without departing from the spirit and scope of the present disclosure. Hence, the present disclosure is deemed limited only by the appended claims and the reasonable interpretation thereof.
This application claims priority to U.S. Provisional Application No. 61/893,478, filed on Oct. 21, 2013, the disclosure of which is incorporated herein by reference.
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Number | Date | Country | |
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20150107684 A1 | Apr 2015 | US |
Number | Date | Country | |
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61893478 | Oct 2013 | US |