High performance, thin metal lined, composite overwrapped pressure vessel

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to composite overwrapped pressure vessels (COPV's) and their method of manufacture. More specifically, the present invention relates to high-performance COPV's including liners made of metals which exhibit high moduli of elasticity and high ductility, such as titanium alloys.

2. General Background

The basic technology for composite overwrapped pressure vessels with metal liners dates back to the late 60's and early 70's.

High-performance fibers offer very high strength-to-weight ratios and are ideal for making lightweight pressure vessels. However, composite laminates fabricated with these fibers have relatively high permeability and cannot contain high pressure liquids or gasses or low pressure gasses for extended periods of time. Therefore, composite pressure vessels must have a liner to prevent leakage. The tank efficiency, as measured by its pressure multiplied by its volume divided by its weight (PV/W), increases as the liner weight decreases. For low pressure and/or liquid containment, elastomeric or polymeric liners are used—these liners are strictly non-structural. For high pressure or gas containment, metal liners are typically used. Metal liners may be structural or non-structural.

For lightweight, high-pressure gas containment, there are basically two primary technologies (a) graphite/epoxy composite with a yielding aluminum liner, and (b) Kevlar/epoxy with load-sharing liners (typically stainless steel, titanium alloy, or inconel). The aluminum-lined, graphite/epoxy tank is the most prevalent technology, but it has limitations. First, the liner yields on each pressure cycle because the strain capability of the fibers is much higher than the elastic capability of the liner. This limits cycle life to around 100 cycles (depending on the specific design) and means that the liner is basically non-structural—it adds weight and a permeation barrier but very little load-carrying capability. PV/W (burst pressure of the tank in p.s.i. times volume in cubic inches, divided by weight in pounds) for these tanks is typically about 1.0×10

6

in. These liners are typically spun from sheet metal or machined from forgings. The spun tanks typically have welded fittings at the ends of the tanks where the forged tanks typically are made in two halves and welded at the center.

The second type of tank makes use of a liner which has a higher elastic range and remains elastic during operating pressure cycles.

FIG. 1

shows a comparison of liners which undergo plastic deformation each cycle (copper and aluminum) as compared to an elastic liner (titanium). This means the tank has the potential to be more efficient; however, because of the density of these materials and the thicknesses required for processing, the efficiency of these tanks is also about 1.0×10

6

in. These load-sharing lined tanks typically have much higher cycle life, but are also typically are much more expensive than aluminum-lined tanks because of the materials and manufacturing processes required, e.g. machining thick, expensive titanium forgings.

SUMMARY OF THE PRESENT INVENTION

The present invention is a COPV with a high PV/W (preferably at least 1.05 million inches, more preferably at least 1.25 million inches, and even more preferably at least 1.45 million inches, more preferably at least 1.80 million inches, and most preferably at least 2.00 million inches). The present invention is able to achieve such a high PV/W in part because it uses a liner made of a high-strength metal which has a low modulus of elasticity and good ductility. The preferred metals are titanium alloys. More preferably, the metal is from the group consisting of titanium alloyed with Al, Cb, Cr, Fe, Mo, Si, Sn, Ta, V, and/or Zr. The most preferred material to use for the metal liner of the tank of the present invention is Ti-6Al-4V.

The apparatus of the present invention is a composite overwrapped pressure vessel, comprising a liner made of a metal having a tensile yield strength in p.s.i. divided by tensile modulus of elasticity in p.s.i. (F

TY

/E) of preferably at least 0.6% and having a ductility of preferably at least 5%, the liner including first and second dome portions and a cylinder portion, and a composite overwrap applied over the liner, wherein the vessel has a PV/W of at least 1.25 million inches. The metal is preferably a titanium alloy from the group consisting of: Ti-6Al-2Sn-4Zr-2Mo, Ti-5Al-2.5Sn, Ti-5Al-2.5Sn ELI, Ti-6Al-2Cb-1Ta-0.8Mo, Ti-8Al-1Mo-1V, Ti-11Sn-5Zr-2Al-1Mo, Ti-6Al-4V, Ti-6Al-4V ELI, Ti-6V-2Sn, Ti-3Al-2.5V, Ti-6Al-2Sn-4Zr-6Mo, Ti-6Al-2Sn-2Zr-2Mo-2Cr-0.25Si, Ti-5Al-2Sn-2Zr-4Mo-4Cr, Ti-13V-11Cr-3Al, Ti-3Al-8V-6Cr-4Mo4Zr, Ti-15V-3Al-3Cr-3Sn, and Ti-10V-2Fe-3Al. The term “ELI” stands for “extra low interstitial”.

More preferably, the metal has a F

TY

/E of at least 0.7%, even more preferably at least 0.8%, even more preferably at least 0.9%, and most preferably at least 1.0%.

The ductility is more preferably at least 10%, even more preferably at least 15%, even more preferably at least 20%, even more preferably at least 25%, and most preferably at least 30%.

While other types of welds might work, the welding steps used to make the liner are preferably done with an autologous fusion process. More preferably, the welding process is electron beam welding, and most preferably, pulsed electron beam welding.

There is preferably an adhesive between the liner and the overwrap, and the adhesive is preferably a film adhesive. Preferably, the COPV includes a protective coating over the overwrap.

Preferably, the liner of the COPV of the present invention has a ratio of thickness in inches over diameter in inches of about 1.7×10

−3

. Preferably, the liner of the COPV has a thickness of not more than 0.050″, more preferably, not more than 0.040″, and most preferably not more than 0.025″. The ratio of the length of the cylinder to the diameter of the cylinder is preferably at least 1.00, more preferably at least 1.25, and more preferably greater than 1.25.

The overwrap can comprise a graphite/epoxy composite.

The present invention also comprises a method of manufacturing a composite overwrapped pressure vessel. The method preferably comprises the following steps:

(a) using spin forming, making a liner having first and second dome portions and a cylindrical portion made of a metal having a F

TY

/E of at least 0.6% and a ductility of at least 5%;

(b) forming first and second bosses made of the metal, the first boss being connected to the first dome portion and the second boss being connected to the second dome portion; and

(c) applying a composite overwrap over the liner, applying filaments of the overwrap onto the liner.

Welding steps are preferably done with an electron beam weld process.

It is an object of the present invention to produce a COPV which, when used in spacecraft, launch vehicles, or aircraft, effects significant savings as compared to current COPV's.

It is an object of the present invention to produce a COPV with a high PV/W.

It is also an object of the present invention to produce a COPV with a liner made of a metal having a high F

TY

/E and a high ductility.

It is another object of the present invention to provide a method of producing a COPV with a high PV/W.

As used herein, including in the claims, PV/W stands for tank burst pressure in p.s.i. times volume of the tank in cubic inches, divided by the weight of the tank in pounds. PV/W is expressed in inches.

BRIEF DESCRIPTION OF THE DRAWINGS

For a further understanding of the nature and objects of the present invention, reference should be had to the following detailed description taken in conjunction with the accompanying drawings, in which like parts are given like reference numerals, and wherein:

FIGS. 1A

,

1

B, and

1

C show[s] a comparison of liners which undergo plastic deformation each cycle (copper-plated liner—FIG.

1

A—and aluminum liner—

FIG. 1B

) as compared to an elastic liner (titanium-6AL-4V liner—FIG.

1

C); in

FIGS. 1A

,

1

B, and

1

C, “STS” indicates stress. “PR” indicates proof, “STN” indicates strain, and “SI” indicates sizing; the plastic strain during MEOP cycles is indicated to be 0.7% for the copper plated liner and 0.3% for the aluminum liner;

FIG. 2

is a perspective, partially cut-away view of the COPV of a first embodiment of the present invention;

FIGS. 3

a

through

3

k

are a schematic representation of the fabrication flow of the COPV of the present invention;

FIG. 4

is a graph showing the effect of heat treatment on ductility of the dome; more specifically, it shows the effect of the Heat Treat Temperature (“HTT”) on dome metal on elongation (“E”), where “STN” represents strain, “SMS” represents strain at maximum stress, and “N” represents no heat treatment;

FIG. 5

is a graph comparing the elongation of TIG and EB welds, in which “STN” represents strain, “E” represents elongation, “SMS” represents strain at maximum stress, “EB/AW” represents electron beam as welded, “TIG/AW” represents TIG as welded, and “PB” represents previous baseline;

FIG. 6

is a graph showing data on oxygen surface contamination resulting from inadequate processing, normalized to 0.16% nominal, in which “DS” represents depth from surface;

FIG. 7

is a graph showing tensile strength (“TS”) of the filament-wound overwrap as a function of temperature (“T”);

FIG. 8

is a graph showing weight savings of the tank of the present invention over competitive tank technologies, in which “WS” represents weight savings, “AlL” represents aluminum lined. “SSL” represents SS lined, “LPTi T” represents low pressure titanium tank, “Ti L” represents Ti lined, “HPTi T” represents high pressure titanium tank, and “TT” represents type of tank;

FIG. 9

is a graph showing potential launch cost savings when using the COPV technology of the present invention, based on a 5000 psi pressure vessel, in which “CS” represents cost savings, “Al COPV” represents aluminum-lined COPV, “SL” represents steel-lined, “TV” represents tank volume (in cubic inches);

FIG. 10

is a graph showing potential launch cost savings when using the COPV technology of the present invention instead of low-pressure titanium tanks, in which “PCS” represents potential cost savings with the new technology and “TiTW” represents all titanium tank weight (in pounds);

FIG. 11

is a rear end view of the liner of the COPV of the present invention;

FIG. 12

is a side end view of the liner of the COPV of the present invention;

FIG. 13

is a cut-away side view of the liner of the COPV of the present invention;

FIG. 14

is a front view of the liner of the COPV of the present invention; and

FIG. 15

is a cut-away side view of the liner of the COPV of the preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The following table lists the part numbers and part descriptions as used herein and in the drawings attached hereto. The preferred materials, if any, follow in parentheses.

Part

Num-

ber

Description

10

COPV of the first embodiment of the present invention

20

liner (titanium-alloy)

20M

maximum thickness of domes 21, 23

21

spun-formed dome (Ti-6Al-4V)

22

liner cylinder (Ti-6Al-4V)

23

spun-formed dome (Ti-6Al-4V)

24

machined boss (Ti-6M-4V)

25

machined tube (Ti-6Al-4V)

26

machined boss (Ti-6Al-4V)

27

fitting used to test tank

28

holes in boss 24

29

holes in boss 26

30

EB welds

31

preferred region for boss/dome weld

40

adhesive (AF-191)

50

filament-wound graphite-epoxy overwrap (T-1000/EPON 862-

Curing Agent W)

51

graphite windings of filament-wound graphite-epoxy overwrap 50

60

epoxy coating (EPON 862-Curing Agent W)

120

liner (titanium-alloy)

120M

maximum thickness of domes 121, 123

121

spun-formed dome (Ti-6Al-4V)

123

spun-formed dome (Ti-6Al-4V)

124

machined boss (Ti-6Al-4V)

126

machined boss (Ti-6Al-4V)

130

interface of cylindrical part of domes 21, 23, 121, 123 and non-

cylindrical part thereof

The COPV of the first embodiment of the present invention, COPV

10

, is shown in FIG.

2

. COPV

10

includes a liner

20

, a composite overwrap

50

, an adhesive

40

bonding liner

20

to overwrap

50

, and a protective epoxy coating

60

over the overwrap. The liner

20

includes preferably spun-formed domes

21

and

23

connected by a cylinder

22

. The thickness of the liner is at a minimum at cylinder

22

and where domes

21

and

23

meet cylinder

22

and for some distance thereafter (see FIG.

13

). The maximum thickness

20

M of domes

21

,

23

is adjacent their outer ends. This increased thickness helps to prevent premature rupture in this constrained area of the liner

20

. Bosses

24

and

26

are attached to domes

23

and

21

, respectively. Bosses

24

and

26

serve to provide a mechanism for structural attachment. Tube

25

is attached to boss

24

to provide a port for pressurization and de-pressurization. The tube fitting

27

serves to provide a mechanism for attachment to hydrostatic and pneumatic test equipment. It is typically removed after the vessel

10

is successfully tested. Holes

28

and

29

are either threaded or fitted with inserts to allow for structural attachment to tank

20

. EB (electron beam) welds are designated at

30

in

FIGS. 2

,

12

, and

13

. Filament windings

51

of filament-wound graphite-epoxy overwrap

50

are run from dome

21

to dome

23

and concentrically around cylinder

22

. The preferred area for attaching the bosses to the domes are indicated at

31

in FIG.

2

.

One key feature of the present invention is the method of manufacturing of the liner. The approach used is novel in the industry and offers significantly improved performance and decreased cost. The key features of the preferred liner fabrication process are listed below.

The preferred liner approach is to 1) spin form domes

21

and

23

(see

FIG. 3

a

), 2) machine bosses (end fittings)

24

,

26

(

FIG. 3

b

), 3) electron-beam weld tube

25

and domes

21

,

23

to bosses

26

,

24

and inspect (

FIG. 3

c

); 4) form and electron beam weld cylinder

22

(

FIG. 3

d

), and 5) weld the domes

21

,

23

to the cylinder

22

(

FIG. 3

e

). Each key operation had to be optimized for use in an overwrapped pressure vessel application, because the strain levels in the metal are well above yield, which non-composite overwrapped metal tanks are not designed to withstand. Several key points are discussed briefly below.

1. Spun Formed Domes—Spun titanium domes have not previously been used in composite overwrapped pressure vessels (although there is some history in using them in all titanium tanks). The use of spin forming significantly reduces cost and lead time over the prior art—primarily forging. To achieve the desired performance in an overwrapped tank application, special processing steps, namely spinning temperature, machining practices (i.e., machining after the heat treatment to remove all oxygen-enriched material from the domes), and heat treating, were implemented; the steps are above and beyond what is typical for titanium dome spinning for non-composite overwrapped tanks.

2. Formed and Welded Cylinder—Formed and welded cylinders have not previously been used in composite overwrapped pressure vessels (although there is some history in using them in all titanium tanks). Similarly to the domes, an optimum process had to be developed for the overwrapped pressure vessel application. The standard TIG weld process was abandoned for a pulsed electron beam weld process.

3. Assembly Welding—A liner fabricated with an assembly method of welding domes to cylinders has not been used for composite overwrapped pressure vessels. Electron beam welding was used in these operations also due to the high ductility and minimal distortion required of the weld in this application.

Several additional factors are key to the success of the vessel and are somewhat innovative in their own right, but are probably considered dependent claims to the primary innovation, i.e. the liner fabrication approach. Some of these are listed below

1. Bonding the liner to the overwrap. This should be done to achieve proper vessel performance. The approach of using a high performance film adhesive has been used before on metal lined pressure vessels, but is not prevalent and the present inventors are not aware of prior use with titanium. In fact, some metal lined pressure vessel manufacturers make sure the liner is not bonded to the composite overwrap.

2. The basic vessel design. In particular, the dome shape and thickness contour are important parameters to vessel performance. Also the configuration of the overwrap in the regions around end fittings and at the dome/cylinder interface is important. The present design is optimized; however the basic design approach is not foreign to the industry.

3. The materials and manufacturing process for the composite overwrap. The selection of materials and the composite manufacturing process are important components to the success of tank

10

. The particular combination of fiber and resin may not have been used before, and the fabrication process of the present invention has some techniques (e.g., using filament winding and incrementally increasing the internal pressure of the liner

20

) which make it work better.

4. The thickness of the liner. The 0.025″ titanium liner

20

of the first embodiment of the COPV

10

of the present invention is significantly thinner than other titanium liners used previously, and thinner than typical aluminum liners. The thinner the liner, the higher the performance of the tank.

With the present invention, to make domes

21

,

23

, one preferably takes a plate, machines it down, then spins it over a male mandrel while heating and pressing down with a roller. Cylinder

22

is preferably made by rolling out of sheet metal.

The pressure vessel technology developed herein represents a significant advantage over the current state of the art.

The construction of the tank

10

of the first embodiment of the present invention is shown in FIG.

2

. Tank

10

includes a thin titanium liner

20

with a filament-wound graphite-epoxy overwrap

50

as shown in FIG.

2

. The chief attribute of the tank

10

is that the thin titanium liner

20

combined with the high-performance overwrap

50

yield a tank

10

which is of minimum weight. The ability to use the thin liner

20

depends on a good adhesive bond between the liner

20

and the overwrap

50

to prevent the titanium liner

20

from buckling due to the compressive stresses induced into the liner

20

after the first pressurization cycle. Previously, titanium liners were thicker, and did not require a bond between the liner and overwrap.

The primary innovative feature of the titanium liner

20

besides its minimum thickness is its method of fabrication. The method developed met two competing goals (a) low cost and short lead time and (b) high performance.

The performance demands for the titanium in overwrapped pressure vessels are much greater than in a typical titanium application. This is because the liner is yielded biaxially (i.e., the liner

20

stretches in two directions, as is typical in liners of high-performance COPVs when first pressurized with internal pressure) in the first pressurization cycle, after which it becomes prestressed (in compression) and performs elastically in subsequent operating cycles (see FIG.

1

). During the course of the development of the technology, several failures were encountered due to manufacturing techniques that were not capable of fabricating a liner with the proper characteristics. Extensive development efforts were required to develop processes which could meet the performance requirements of this liner.

A discussion of the key components and assemblies involved in the subject invention follows. A schematic of the fabrication flow is shown in FIG.

3

.

For dome fabrication, a spin-forming process was selected. Spin forming offered a low cost, readily available option for dome fabrication as compared to conventional forging technologies. Although spin forming in not a new process, the use of spin forming to form domes for overwrapped tanks is innovative, as well as is the complete dome-fabrication process. Initial attempts to use industry-standard spun-dome processing (developed for all metal tanks) proved inadequate for this application. The key steps to fabricating a dome are spin forming the dome, heat treating it, and machining it.

In spin forming the domes

21

,

23

, from the preferred alloy, Ti-6Al-4V, the spin forming temperature was a key parameter in the successful development. The domes

21

,

23

are spun at a temperature of between about 800° F. and about 1600° F., and preferably at a temperature of approximately 1400° F. Sufficient thickness is maintained to allow (a) uniform metal temperature, and (b) removal of all oxygen-enriched material.

The spun domes

21

,

23

are put through an anneal cycle which recrystallized the grain structure of the domes

21

,

23

. The domes

21

,

23

are annealed by heating them to a temperature of between about 1300° F. and about 1700° F. (and preferably 1675° F.—see

FIG. 4

) for about 30-120 minutes, then cooling the domes

21

,

23

to ambient temperature at a rate of not more than about 200° F. per minute. Most preferably, the domes

21

,

23

are annealed per MIL-H-81200 at 1675° F. for one hour, then furnace cooled to 1400° F., then held for one hour and air cooled, or slower. For the preferred alloy, this anneal cycle is critical to remove the residual work hardening in the domes and significantly improves the ductility and fracture toughness of the liner. The effect of heat treatment on ductility of the dome is shown in FIG.

4

.

After this heat treatment, the dome

21

,

23

is machined to its final configuration. Machining is sufficient to insure that all oxygen-enriched material (from either spin forming or heat treatment) is removed.

The bosses, or end fittings,

24

,

26

of the liner

20

are machined from Ti-6Al4V plate or bar stock.

Cylinder

22

is fabricated by rolling and electron-beam welding a pre-cut sheet of Ti-6Al-4V. Because of the thin sheet used, special pulsed electron-beam (EB) weld schedules were developed to produce consistent welds (i.e., a pulsed EB welding technique, well known to those skilled in this art, was used—specifically, the welds were made per AMS 2680 except that the internal maximum pore diameter did not exceed 0.2 times the thickness). The early cylinders were fabricated using a Tungsten Inert Gas (TIG) welding technique, which even after numerous refinements was not capable of consistently performing in this application. Therefore, TIG welds were abandoned in favor of the EB welds because of the superior ductile performance of the EB welds (FIG.

5

).

The liner is assembled by EB welding. First the bosses

24

,

26

are welded to the domes

21

,

23

. The bosses

24

,

26

are first welded to the domes

21

,

23

, then the boss/dome assemblies are welded to the cylinder

22

. Again, special pulsed EB weld schedules were developed for the dome-to-cylinder welds. Due to the high ductility of the EB welds

30

, a post-weld high-temperature stress-relieve operation is not required. This is critical because even the best high-temperature vacuum stress-relieve operations produce a very thin layer of oxygen contamination (

FIG. 6

) which has been shown to crack under high strains (early tanks which were vacuum stress relieved exhibited cracks, some of which penetrated through the liner).

The adhesive and surface-preparation technique are essential to the success of this design concept. Once the liner

20

is complete, the surface is cleaned and abraded using a multi-step process to insure a good bond between the liner

20

and the composite overwrap

50

. This process includes (

FIG. 3

f

) (a) an alkaline clean, (b) an abrasive clean with abrasive pads and methyl-ethyl ketone (MEK), (c) solvent wipe with MEK, (d) an abrasive clean with abrasive pads and demineralized (DM) water, (e) a final DM water rinse and (f) “water break free” verification. Once the liner

20

is dry, the high-performance film adhesive

40

, AF-191 manufactured by 3M, is applied (

FIG. 3

g

). This surface preparation process in conjunction with the AF-191 adhesive

40

has been shown to produce very good bonds between titanium and graphite epoxy.

The liner

20

is then filament wound (

FIGS. 3

h

and

3

i

) with T-1000GB graphite fiber (manufactured by Toray), and an EPON 862 epoxy resin/Curing Agent W mixture (manufactured by Shell Chemical Company). This combination has been shown to deliver outstanding tensile strength over a wide temperature range (FIG.

7

). During the winding process, the developed process maintains proper tension on the graphite fiber and the proper ratio of fiber to resin as the material is applied to the tank. Techniques have also been developed for incremental pressurization of the liner

20

to prevent collapse of the liner

20

from the external pressure exerted by the filament-wound overwrap

50

(as discussed in the next paragraph).

The composite overwrap

50

consists of a high strength fiber (glass, carbon/graphite, aramid, etc.) and a polymeric resin system (polyester, epoxy, cyanate ester, etc.). Preferably, the fiber has a specific strength (tensile strength in p.s.i. over density in pounds per cubic inch) of greater than 7.5×10

6

inches, more preferably greater than 1.0×10

6

inches, and most preferably greater than 1.3×10

6

inches. The composite overwrap

50

is applied in layers using a technique called filament winding, whereby the liner

20

is rotated about its longitudinal axis and a pay-out eye moving up and down the longitudinal axis of the liner

20

dispenses the fiber (which has been coated with liquid resin by being passed through a resin bath) onto the liner. The layers are typically either wound circumferential on the cylindrical portion of the tank (hoop plies) or wound from end to end across the domes

21

,

23

in a helical or planar fashion (planar or helical plies). During the winding process, the internal pressure of the liner

20

is incrementally increased to offset the forces applied to the liner

20

by the application of the overwrap

50

. Once all the plies are applied to the liner, the tank

10

is cured. The curing process may take place at room temperature or at elevated temperatures, depending on the resin system selected and the end-use environments for the tank

10

.

The tank overwrap can advantageously be cured as follows. (1) At an average rate of 1+/−0.5 degrees F. per minute, the part is raised to 160+/−10 degrees F. and held for 20-25 minutes. (2) Excess resin is removed after the 160 degree F. hold. The part temperature may drop as much as 20 degrees F. during resin removal. (3) At a rate of 1-10 degrees F. per minute, the temperature of the part is raised back to 160+/−10 degrees F. (4) At an average rate of 1+/−0.5 degrees F. per minute, the temperature of the part is raised to 200+/−10 degrees F. Excess resin is removed from the part surface. (5) At an average rate of 1+/−0.5 degrees F. per minute, the temperature of the part is raised to 250+/−10 degrees F. and held for 50-70 minutes. (6) At an average rate of 1 to 4 degrees F., the part or reference panel temperature (a reference panel may be used to determine temperature to prevent damage to the part by thermocouples) is raised to 350+/−10 degrees F. and held for 105-135 minutes. (7) At a rate not exceeding 5 degrees F. per minute, the part is cooled to below 150 degrees F.

A protective coating

60

can optionally be added after curing (see

FIG. 3

j

).

COPV

10

is then internal cleaned for final acceptance, packaged, and shipped (

FIG. 3

k

).

There are many variations of the winding process which may be employed. One such variation makes use of a “prepreg”, which is fiber impregnated with resin and partially cured into a ribbon or band, in place of fiber impregnated with liquid resin. Another variation is to use more sophisticated equipment which physically places the fiber or prepreg band into place using computer-aided machinery—this process is generally referred to as “fiber placement” or “tape placement”.

A test article was designed and fabricated to demonstrate the technology. For this activity, a new satellite program and Mil Std. 1522A requirements were selected because they (a) were typical for spacecraft applications for overwrapped tanks, and (b) the new satellite program was a potential application of the technology.

The primary goal of this program was to develop a tank design which met all requirements with sufficient margins, repeatable processing, and high quality materials.

The primary design drivers of this tank were the burst pressure and weight requirements. Structurally, the tank designed to meet burst pressure requirements was adequate for all other load cases (e.g. maximum expected operating pressure (MEOP)+vibration loads, MEOP+thermal, etc.). Other design considerations included: (a) cycle life; (b) the high-temperature environment (approximately 300° F.) encountered because of the proximity of the tank to a spacecraft engine, (c) mechanical interface requirements (as referenced in SCD 20032541, Rev. A); (d) vacuum outgassing requirements; (e) chemical resistance to hydrazine.

The fundamental design concept, a thin metal liner with a high-performance graphite/epoxy overwrap, was selected early in development trade studies. Graphite/epoxy, due to its high strength-to-weight ratio, was required for the overwrap to meet the weight requirements. Initially, three liner systems were considered, aluminum—the current state of the art, electroplated copper—a developmental technology with limited success in preliminary development with the potential for very low weight, and titanium alloy. The titanium alloy was selected over aluminum because it offered higher reliability and lower weight. The titanium was selected over electroplated copper because of the high design/fabrication risk associated with the copper lined tank development.

The basic design was defined by using netting analysis which provided the minimum quantity of both hoop (circumferential) and helical (end-to-end) plies for the overwrap and also defined the basic dome geometry. The basic details of the boss design and dome thickness profile were defined based on sound engineering principles. The overwrap configuration, specifically the termination of the hoop plies at the dome/cylinder interface, and the method of terminating helical plies in the boss region, were defined by a combination of sound engineering practice and conducting developmental testing of tanks under the Lockheed Martin IR&D program. The final details of the design were optimized using finite element analysis methods. Numerous parametric analyses were performed to arrive at the final configuration.

The basic tank

10

construction is shown in FIG.

2

. The overwrap

50

is a filament-wound Toray T-1000GB graphite fiber and a Shell EPON 826/Curing Agent W epoxy resin system. The fiber was selected based on its extremely high strength-to-weight ratio. The resin system (for both winding and coating) was selected because it has (a) processing characteristics (viscosity, pot life, etc.) which are very suitable for filament winding, (b) high elongation (good translation of fiber properties), (c) good high-temperature performance (glass transition temperature is above 320° F.), (d) low condensable volatiles, and (e) good chemical resistance. The adhesive

40

, 3M AF-191 brand film adhesive, was selected because it has (a) outstanding adhesion to both graphite epoxy and titanium, (b) high peel and shear strengths, (c) good high temperature performance up to 350° F., and (d) low condensable volatiles.

The titanium alloy, Ti-6Al-4V, was selected because of its high elastic capability. Unlike aluminum or copper, titanium alloy can remain elastic during operating cycles as shown in FIG.

1

. This significantly increases cycle life and allows the use of standard linear elastic fracture mechanics to predict flaw growth and tank life.

All required validation testing for the technology program was successful. A brief description of all validation tests is listed below.

The test article configuration is as discussed above.

The tank was pressurized to 4830, −0, +30 psi., the volume was determined, the pressure was increased to 6030, −0, +30 psi. and held for 5 minutes for proof test, the tank pressure was decreased to 4830, −0, +30 psi. and the volume and dimensional growth measurements were recorded. The volume of the tank was 5086 in.

3

, above the 4985±15 in.

3

requirement; which was not a technical concern. The permanent set was −0.02% (below the 0.2% maximum required) and the dimensional growth was acceptable.

To leak test the tank

10

, it was placed in a vacuum bag attached to a helium leak detector. The bagged tank

10

was placed in an altitude chamber, and the chamber pressure was brought below one torr. The tank

10

was pressurized with helium to 4830, −0, +30 psi. After the tank pressure had been stabilized for 30 minutes, the leak rate was measured. The leak rate was 3.0×10

−8

scc/sec, within the 1.0×10

−6

scc/sec requirement.

Sine and random vibration testing were performed on a tank pressurized to 4,800 p.s.i. with helium according to the vibration levels shown below in Tables 1 and 2.

TABLE 1

Tank Sinusoidal Sweep Vibration Schedule

Axis

Frequency Range (Hz)

Acceleration Level (G's)

X-Axis

4-17

0.5″ D.A.

17-65

7.0

70-100

3.0

Y and Z Axes

2-20

0.5″ D.A.

20-80

10.0

85-100

4.0

MEOP cycling was conducted by pressurizing tank

10

to 4830 psi minimum a total of 50 times. This meets the MIL-STD-1522A minimum requirement of 50 cycles since 4 times the maximum number of operating cycles is less than 50 (actual is 4×10=40). Forty-two of those cycles were done consecutively, and the other 8 were accomplished as follows: (a) two during leak checks (one after proof and one prior to burst), (b) three during vibration testing (the tank was pressurized and de-pressurized for each axis of vibration testing, (c) one during thermal cycling, (d) one during de-tanking, and (e) one during final volumetric check. There was no indication of tank failure as a result of the MEOP cycles.

Proof cycling was conducted by cycling tank

10

to 6030 psi. six times. One cycle as accomplished during the initial proof test, and 5 additional cycles were done consecutively. There was no indication of tank failure as a result of the proof cycles.

Thermal cycling was conducted by pressurizing tank

10

with helium to 4080 psi this pressure was chosen so the tank would not exceed MEOP at maximum temperature) and placing it in a computer-controlled temperature chamber. The chamber was cycled 10 times from −29° F. to +178° F., holding at each temperature extreme for 2 hours. The overall test objectives were met and the test was successful.

A de-tanking test was also performed. The purpose of the de-tanking test was to verify the tank could withstand the external heat encountered during service while the tank is being de-pressurized. Because of the difficulty in simulating the exact tank surroundings, accurately monitoring and controlling a heat source based on heat flux, and not being able to simulate the effects of a no-gravity environment, the tank test was devised to monitor and control tank temperature, as predicted by analysis, rather than perform an exact simulation. A margin of 18° F. was added to the maximum temperature for test purposes to account for any inaccuracies in the analysis.

The test was a three-stage blow down of the tank where the mass flow out of the tank was regulated at 0.001 lbm/sec and the temperature of the tank was raised using heater pads bonded to the appropriate areas of the tank. There were two 50-minute de-pressurization cycles and one 22-minute cycle. Between cycles, initial tank and chamber temperatures were restored. The tank temperatures were maintained to within a few degrees of the predictions (with final maximum temperatures always meeting or exceeding predictions) and the mass flow rate was easily maintained between 0.0009 and 0.0011 lbm/sec. At the end of the final 22-minute de-pressurization cycle, the tank pressure was 750 psi, the maximum tank temperature in the center of the heated section was 275.6° F., and the minimum temperature on the tank cylinder directly opposite the heated part of the tank was 67.3° F. At this point the heaters were turned off and the tank was allowed to continue to de-pressurize at 0.001 lbm/sec to 400 psi., at which time the maximum tank temperature was 147.8° F. The tank was subsequently completely de-pressurized, at which time the maximum temperature was 94.1° F.

The de-tanking test was successful and there was no detectable damage to the tank.

To conduct a leak check, the tank was placed in a vacuum bag attached to a helium leak detector. The bagged tank was placed in an altitude chamber and the chamber pressure was brought below one torr. The tank was pressurized with helium to 4830, −0, +30 psi. After the tank pressure had been stabilized for 30 minutes, the leak rate was measured. The leak rate was 1.4×10

−7

scc/sec, within the 1.0×10

−6

scc/sec requirement.

Regarding volumetric expansion, the tank was pressurized to 4830, −0, +30 psi. and the tank volume was measured. The tank volume was 5112 in.

3

at the end of the qualification as opposed to 5086 in.

3

during the initial measurement. This does indicate some minor tank growth during the qualification program, however, this is not a major concern. It should be noted that although efforts were made to eliminate air from the system, small amounts of trapped air (e.g. from air bubbles suspended in pressurization media, bubbles clinging to tank inner surface, or air trapped in the tank of pressurization system) may have contributed the perceived variance in volume.

Burst Test and Failure Mode Discussion

The tank was pressurized to 7230 psi., held for 15 seconds, then pressurized to failure, which occurred at 9339 psi.

The exact mode of failure cannot be determined because, despite efforts to suspend the tank with elastic cords to prevent secondary damage, there was significant secondary damage to the tank which masked the exact failure initiation site.

The failure scenario, as constructed from examination of the failed article and video tape, occurs as follows.

(1) There was a failure in the dome region of the tank on the end with the pressure inlet. This is evidenced by a visual indication of water in the video. The impulse of this failure instantly sheared the bolts holding the tank to the plates attached to the elastic cords. (It is known that the bolts were sheared because the plate to which the tank was attached at the failure initiation end did not move with the tank and the scar from the impact of the opposite boss opposite on the other mounting plate to which it was attached is not concentric to the bolt pattern.)

(2) The tank was propelled into the wall opposite the failure location which imploded the dome opposite the failure and exploded the dome where the failure initiated.

(3) The entire boss and upper portion of the dome from the failure initiation end of the tank (to a diameter of approximately 8″) was separated from the tank after the tank impacted the wall. Also there was extensive fiber and liner damage in both domes.

Although there is no way to be certain exactly what happened, it is likely that the failure initiated in the liner dome at a radius of approximately 4″ from the longitudinal centerline. Stress analysis shows this is the region where there is extensive yielding of the liner and that the strains at burst pressure are over 4.4% in the meridional direction and 1.4% in the hoop direction, which are sufficient to fail the metal. In a previous development test of an identical tank which achieved a similar pressure (9368 psi) and did not fail catastrophically (it failed by fiber failure in outer hoop plies only—the remainder of the overwrap and liner remained intact), there was visible indication of extreme yielding in this region.

The initial failure probably released a propulsive jet of water which failed the bolts holding the tank in the elastic-cord-supported fixture and propelled the tank into the wall, thereby creating the extensive secondary damage.

Although failure above 9000 psi. is considered a burst, previous development tanks of essentially identical overwrap configuration (same exact configuration of the six helical plies but had two fewer hoop plies, 16 as opposed to the current 18), but with different liner designs leaked at above 6800 psi. In one of these tanks, the liner had a different design in the boss and dome region and failed at 6870 psi. with a large crack in the dome (at approximately 7.5″ diameter from longitudinal axis), which only leaked—this was a pneumatic test with nitrogen. In another test of the present liner design with a different longitudinal cylinder weld, a tank leaked at above 6800 psi by cracking along the entire length longitudinal cylinder weld, (this weld was a TIG weld which was used only in development and abandoned prior to fabrication of flight or final technology validation tanks). This demonstrates that the tank overwrap design is sufficient to produce leak before burst failures in liner failures below 6800 psi, which encompasses MEOP (4800 psi) and Proof pressure (6000 psi).

Extensions of Innovation

The technology discussed herein could be extended to a tanks of a variety of sizes, shapes, and pressure requirements. In addition, other metals, such as other titanium alloys, Inconel, or Stainless steel could be used as the liner material with similar results. Similarly, other fibers, resins, and adhesives may be used with similar results.

Advantages Over Prior Practices

This technology offers cost-effective performance enhancement to a number of applications where weight is critical. Some of the specific advantages are significantly lower weight, short lead time, high cyclic life potential, and cost-effective performance enhancement. These advantages are discussed in detail below.

The typical weight reduction is about 20% over competitive aluminum-lined tanks and 40% over comparable steel-lined tanks or titanium-lined tanks, 40% over low-pressure titanium tanks, and 60% over high-pressure titanium tanks as shown in FIG.

8

. The key tank attributes which allow weight reduction are the high-strength/low-density fiber and the high-strength, thin titanium-alloy liner. The use of titanium alloy offers additional benefits over aluminum in that it is much stronger and stiffer per unit weight; this is a particular advantage in the polar boss regions of the dome where the liner is required to withstand high structural loads. Reduced tank weight offers many potential advantages to satellite/spacecraft applications, including:

a) Ability to deliver a larger payload. Satellite propulsion busses and launch vehicles can deliver a finite mass to the proper orbit. Reduction of the mass of the tanks allows more mass for the electronics or other components of the spacecraft.

(b) Increased life on orbit. Satellites must expend propellant in some type of thrust-producing engine to maintain a proper orbit. Satellite life is limited by the amount of propellant which the spacecraft can deliver to orbit. Reducing tank weight can increase the amount of propellant taken to orbit, and therefore increase the life of the satellite.

(c) Reduced launch costs. As the mass of the spacecraft increases, so does the size and cost of the launch vehicle required to launch the spacecraft. Reduction in tank weight can mean the difference in launching with one class of launch vehicle versus another, which can mean dramatic differences in launch costs. In addition, some launches are priced on a per-pound basis, so every pound can save $5000 to $15,000 or more.

FIGS. 9 and 10

show potential launch cost savings associated with implementation of the subject technology into both high-pressure COPVs and low-pressure titanium-tank applications.

Typical lead time for tank

10

, from start to finish is about 4 to 6 months, as compared to a tank with a forged titanium liner which would be typically 12 to 18 months.

Because the liner

20

remains elastic during operating cycles, the technology has capability for much higher cyclic life than an aluminum-lined tank. The high cyclic life capability offers the potential to use this technology in applications where much heavier tanks are currently used.

When compared to aluminum-lined tanks, tank

10

offers a cost-effective alternative in that although acquisition costs may be higher, the total cost, once launch savings are factored in, is lower.

When compared to other titanium-lined or steel-lined technologies, the COPV

10

of the present invention offers cost savings in both acquisition costs and launch costs.

The technology of the present invention is a breakthrough in weight and cost efficiency for COPVS. The technology, utilizing a thin titanium liner, (utilizing spinning technology, off-the-shelf materials, and electron-beam welding) combined with a high-performance graphite/epoxy overwrap, offers the following advantages:

1. At least a 20% weight savings over traditional aluminum-lined vessels with comparable lead time and availability.

2. Cost-effective performance enhancement over aluminum-lined vessels for launch vehicle/spacecraft applications. For example, for a typical 4800 psi., 5000 in.

3

vessel, the acquisition cost of the vessel would be about $30,000 higher than a comparable aluminum-lined COPV, but the launch cost savings would be $50,000 to $90,000, producing an overall savings of $20,000 to $60,000 per launch. Alternatively, the weight savings could be translated into increased payload capability, e.g. increased transponders for communications satellites. This increases the revenue potential of the satellite by increasing capacity to transfer information and data.

3. Approximately 40 to 45% weight savings over comparable technologies for multi-use tanks, such as those used on the Space Shuttle. If implemented on Space Station, the number of launches required could be reduced or the capability increased.

4. Approximately 30 to 50% cost savings and a 50% or greater reduction in lead time over prior technologies (e.g. forged/machined liners). These features are critical in the very competitive commercial satellite market.

COPV

10

can be, for example, 16 inches in diameter by 32 inches long to 24 inches in diameter to 102 inches long. It is believed that it would be practical to make the diameter up to, for example, 36 inches, with a length of 36 to 120 inches. The ratio of liner length to tank diameter (around 0.75-1.0, more preferably around 1.0-1.4, and most preferably around 1.4-2.0+) would probably be fairly constant, regardless of the size, as would the ratio of liner thickness (in inches) to liner diameter (also in inches) (preferably not more than about 1.7×10

−3

, more preferably not more than about 1.5×10

−3

, even more preferably not more than about 1.3×10

−3

, and most preferably not more than about 8.5×10

−4

,). The thickness of the overwrap

50

will depend upon the desired pressure. The maximum thickness of domes

21

and

23

can be, for example, about twelve times the minimum thickness of domes

21

and

23

(to prevent failure near the outer ends of the domes

21

and

23

, the thickness of domes

21

and

23

needs to be increased near the outer ends, as shown in FIG.

13

).

Exemplary dimensions for the COPV

10

of the present invention are as follows:

diameter of cylinder

22

and inner ends of domes

21

and

23

: 16.0 inches;

length of cylinder

22

: 19.9 inches;

length of domes

21

and

23

: 6.3 inches;

length of COPV

10

(from outer end of boss

24

to outer end of boss

26

): 32.3 inches;

thickness of cylinder

22

and domes

21

and

23

adjacent the inner ends of domes

21

and

23

: 0.025 inch;

maximum thickness of domes

21

and

23

: 0.300 inch;

average thickness of overwrap

50

: 0.25 inch;

minimum thickness of overwrap

50

: 0. 10 inch;

maximum thickness of overwrap

50

: 0.60 inch;

the hoop plies can advantageously be wound at 8 tows per 0.58+/−0.010 inches tow spacing;

the helical plies can advantageously be wound at 8 tows per 0.55+/−0.010 inches tow spacing;

with these exemplary dimensions, the plies can terminate as shown in Table 3;

weight of liner

20

: 10 pounds;

burst pressure of COPV

10

: about 9,300 p.s.i.;

volume of COPV

10

: 5,000 cubic inches;

weight of COPV

10

: 32 pounds;

PV/W for COPV

10

: 1.45 million inches (for a comparable COPV made with an aluminum liner, it is 1.0 million inches);

F

TY

/E of liner

20

: 0.8%;

ductility of liner

20

: 10%.

Domes

21

,

23

can, for example, vary in thickness from about 0.300 inch near the inlet opening to 0.025 inch where it is welded to the cylinder (in such a case, the cylinder is preferably 0.025 inch thick as well). Domes

21

,

23

should be thicker near the inlet opening to prevent premature rupture.

The composite overwrap can, for example, consist of 24 plies applied as shown in Table 3 (ply

1

being applied first and ply

24

being applied last). Each ply is composed of a number of individual fibers aligned at an angle indicated in Table 3.

TABLE 3

Ply

Angle

Location (In Inches) of Termination of Ply at Each

(In Degrees)

End

with Respect

to Longitudi-

nal Axis

of Cylinder

24

88-92

1.000 + .00, −.20 towards the center from a reference

line spaced .300 + .20 − .00 towards the center from

the interface (indicated at 130 in

FIG. 15

) of the

cylindrical portion and the elliptical portion of the

dome

23

88-92

.750 + .00, −.20 towards the center from a reference

line spaced .300 + .20 − .00 towards the center from

the interface (indicated at 130 in

FIG. 15

) of the

cylindrical portion and the elliptical portion of the

dome.

22

88-92

.500 + .00, −.20 towards the center from a reference

line spaced .300 + .20 − .00 towards the center from

the interface (indicated at 130 in

FIG. 15

) of the

cylindrical portion and the elliptical portion of the

dome

21

88-92

.250 + .00, −.20 towards the center from a reference

line spaced .300 + .20 − .00 towards the center from

the interface (indicated at 130 in

FIG. 15

) of the

cylindrical portion and the elliptical portion of the

dome

20

11-19

adjacent the bosses, along a circle of radius 2.80

inches, centered on the longitudinal axis of the liner

88-92

.500 + .00, − .20 towards the center from a reference

line spaced .300 + .20 − .00 towards the center from

the interface (indicated at 130 in

FIG. 15

) of the

cylindrical portion and the elliptical portion of the

dome

18

88-92

.250 + .00, − .20 towards the center from a reference

line spaced .300 + .20 − .00 towards the center from

the interface (indicated at 130 in

FIG. 15

) of the

cylindrical portion and the elliptical portion of the

dome

17

88-92

.250 + .00, −.20 towards the center from a reference

line spaced .300 + .20 − .00 towards the center from

the interface (indicated at 130 in

FIG. 15

) of the

cylindrical portion and the elliptical portion of the

dome

16

10-17

adjacent the bosses, along a circle of radius 2.20

inches, centered on the longitudinal axis of the liner

15

88-92

.300 + .20 − .00 towards the center from the interface

(indicated at 130 in

FIG. 15

) of the cylindrical

portion and the elliptical portion of the dome

14

88-92

.250 + .00, −.20 towards the center from a reference

line spaced .300 + .20 − .00 towards the center from

the interface (indicated at 130 in

FIG. 15

) of the

cylindrical portion and the elliptical portion of the

dome

11

88-92

.300 + .20 − .00 towards the center from the interface

(indicated at 130 in

FIG. 15

) of the cylindrical

portion and the elliptical portion of the dome

12

10-17

adjacent the bosses, along a circle of radius 2.20

inches, centered on the longitudinal axis of the liner

10

88-92

.250 + .00, − .20 towards the center from a reference

line spaced .300 + .20 − .00 towards the center from

the interface (indicated at 130 in

FIG. 15

) of the

cylindrical portion and the elliptical portion of the

dome

10

88-92

.300 + .20 − .00 towards the center from the interface

(indicated at 130 in

FIG. 15

) of the cylindrical

portion and the elliptical portion of the dome

9

8-13

adjacent the bosses, along a circle of radius 1.80

inches, centered on the longitudinal axis of the liner

8

88-92

.250 + .00, −.20 towards the center from a reference

line spaced .300 + .20 − .00 towards the center from

the interface (indicated at 130 in

FIG. 15

) of the

cylindrical portion and the elliptical portion of the

dome

7

88-92

the interface (indicated at 130 in

FIG. 15

) of the

cylindrical portion and the elliptical portion of the

dome

6

88-92

.300 + .20 − .00 towards the center from the interface

(indicated at 130 in

FIG. 15

) of the cylindrical

portion and the elliptical portion of the dome

5

7-12

adjacent the bosses, along a circle of radius 1.80

inches, centered on the longitudinal axis of the liner

4

88-92

the interface (indicated at 130 in

FIG. 15

) of the

cylindrical portion and the elliptical portion of the

dome

3

88-92

.300 + .20 − .00 towards the center frorn the interface

(indicated at 130 in

FIG. 15

) of the cylindrical

portion and the elliptical portion of the dome

2

88-92

the interface (indicated at 130 in

FIG. 15

) of the

cylindrical portion and the elliptical portion of the

dome

1

6-10

adjacent the bosses, along a circle of radius 1.80

inches, centered on the longitudinal axis of the liner

The typical length of cylinder

22

is 1.25 times its diameter. Typically, the cylinder

22

encloses 75% of the volume, but has only 25% of the weight—thus, to improve PV/W, one can make the cylinder

22

longer.

The composite overwrap takes most of the load. The portion of domes

21

,

23

near the inlet opening is thicker to take most of the load. When a titanium alloy is used for the liner

20

, the COPV

10

of the present invention has a longer cycle life than comparable aluminum-lined tanks (see FIG.

1

).

The present invention can be used as pressurant tanks for satellites and spacecraft and as fuel and oxidizer tanks for satellites and spacecraft.

Vehicles/spacecraft applications which require tanks which could directly use this technology include: (1) various satellites (pressurant, fuel and oxidizer), (2) Space Station (life support and station reboost), (3) Space Shuttle (Life support, orbital maneuvering), (4) Re-useable Launch Vehicle (life support, primary/secondary fuel/oxidizer tank pressurization, secondary fuel and oxidizer), (5) Hybrid Rockets (oxidizer tank pressurization), (6) Space Station/Shuttle Extra-Vehicle Activity—Pressurized gas proposed as propulsion media for most applications (manned and unmanned).

FIG. 15

shows the preferred embodiment of the liner of the present invention, liner

120

. Liner

120

is similar to liner

20

, except for the location of the welds connecting the bosses to the domes. Liner

120

can advantageously be substituted for liner

20

in the COPV

10

of the present invention.

Liner

120

can be produced at a cost of about 30% less than the cost of liner

20

, without adversely affecting performance of the liner. The reason for this is that a machining and inspection step between spinning and annealing of the domes is eliminated and the location of the weld between the dome and the boss is changed.

The machining and inspection step which is eliminated was initially planned into the program to determine if there was any cracking of the spun domes before they were annealed and final machined. After processing of many domes, there has never been any indications of cracking at this step, so it is eliminated in the construction of liner

120

.

As can be seen by reviewing FIG.

13

and

FIG. 15

, the welds between dome

21

and boss

26

and between dome

23

and boss

24

have a plane parallel to the plane of the welds between these domes

21

and

23

and cylinder

22

, while the welds between dome

121

and boss

126

and between dome

123

and boss

124

are cylindrical and are parallel to cylinder

22

(i.e. the interface between the boss and the dome at the weld is cylindrical), Movement of the weld location is beneficial because it allows the thickness of the starting plate from which the domes are machined to be reduced from about 0.90″ (

20

M in

FIGS. 13 and 15

) to about 0.375″ (

120

M in

FIG. 15

) when a tank having the exemplary dimensions is made. Also, a lot of pre-machining of the domes is eliminated. The weld locations between boss

124

and dome

123

and between boss

126

and dome

121

of liner

120

remains elastic, even at burst pressures; these weld locations are at approximately the same strain level as the welds of liner

20

between the bosses and the domes.

Though the liners

20

and

120

have been described as being made with three major separate components (domes

21

,

23

and cylinder

30

or domes

121

,

123

, and cylinder

30

), they could be made by spin forming a single major component or by spin forming two major components, each containing a dome portion and half (or some portion) of a cylinder portion.

Because many varying and different embodiments may be made within the scope of the inventive concept herein taught, and because many modifications may be made in the embodiments herein detailed in accordance with the descriptive requirement of the law, it is to be understood that the details herein are to be interpreted as illustrative and not in a limiting sense.

Number	Name	Date	Kind
2809762	Cardona	Oct 1957	A
3131725	Chyle	May 1964	A
3137405	Gorcey	Jun 1964	A
3184092	George	May 1965	A
3207352	Reinhart, Jr.	Sep 1965	A
3240644	Wolff	Mar 1966	A
3321347	Price et al.	May 1967	A
3504820	Barthel	Apr 1970	A
3815773	Duvall et al.	Jun 1974	A
3843010	Morse et al.	Oct 1974	A
3969812	Beck	Jul 1976	A
4053081	Minke	Oct 1977	A
4225051	Faudou et al.	Sep 1980	A
4369894	Grover et al.	Jan 1983	A
4835975	Windecker	Jun 1989	A
5228585	Lutgen et al.	Jul 1993	A
5284996	Vickers	Feb 1994	A
5287988	Murray	Feb 1994	A
5341638	Van Name et al.	Aug 1994	A
5385262	Coquet et al.	Jan 1995	A
5385263	Kirk et al.	Jan 1995	A
5822838	Seal et al.	Oct 1998	A

	Number	Date	Country
Parent	08/595371	Feb 1996	US
Child	08/681147		US

High performance, thin metal lined, composite overwrapped pressure vessel

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

CROSS-REFERENCE TO RELATED APPLICATIONS

US Referenced Citations (22)

Continuation in Parts (1)