Since the 1990's heavy vehicles have been taking advantage of compressed natural gas (CNG) engines. However, light vehicles, such as passenger cars, still have yet to achieve widespread adoption. Both private and public players began to identify technological hurdles to CNG passenger vehicle growth. Industry realized that if certain storage issues could be solved natural gas offered incredible untapped opportunity. However, current CNG storage solutions, both for integrated vehicles and converted vehicles, are still bulky and expensive cylinder based systems. For the integrated systems, various sized cylindrical tanks are integrated into the vehicle chassis design. For the converted vehicles, a big tank is placed in the trunk, eliminating storage or spare tires.
Various embodiments of the invention are disclosed in the following detailed description and the accompanying drawings.
The invention can be implemented in numerous ways, including as a process; an apparatus; a system; a composition of matter; a computer program product embodied on a computer readable storage medium; and/or a processor, such as a processor configured to execute instructions stored on and/or provided by a memory coupled to the processor. In this specification, these implementations, or any other form that the invention may take, may be referred to as techniques. In general, the order of the steps of disclosed processes may be altered within the scope of the invention. Unless stated otherwise, a component such as a processor or a memory described as being configured to perform a task may be implemented as a general component that is temporarily configured to perform the task at a given time or a specific component that is manufactured to perform the task. As used herein, the term ‘processor’ refers to one or more devices, circuits, and/or processing cores configured to process data, such as computer program instructions.
A detailed description of one or more embodiments of the invention is provided below along with accompanying figures that illustrate the principles of the invention. The invention is described in connection with such embodiments, but the invention is not limited to any embodiment. The scope of the invention is limited only by the claims and the invention encompasses numerous alternatives, modifications and equivalents. Numerous specific details are set forth in the following description in order to provide a thorough understanding of the invention. These details are provided for the purpose of example and the invention may be practiced according to the claims without some or all of these specific details. For the purpose of clarity, technical material that is known in the technical fields related to the invention has not been described in detail so that the invention is not unnecessarily obscured.
A system for storing natural gas is disclosed. The system comprises a plurality of straight sections of tube. The plurality of straight sections of tube are dense packed. The plurality of straight sections of tube are configured to fill a designated volume.
In 1890 Giuseppe Peano discovered a class of curves that fill 2-dimensional space, a result which Hilbert extended to 3-dimensional cubes. It can be shown that such a curve can densely fill any 2- or 3-dimensional (2D or 3D) shape. Based on these insights, an Intestine Storage Concept is disclosed, a compressed gas storage tank modeled after the human intestine, an example of a high density curve efficiently filling an irregular volume.
A key insight here is that in the design of a cylindrical tank the ratio of the tank mass to the contained gas mass is not dependent on tank geometry. The mass of the material used, and thus the bulk material cost is constant for a given pressure and material yield stress. With no penalty paid (in material cost or packing density) for moving to small diameter tubes, the ability is gained to fit the tank in to any 3D shape desired—for example embedded in the chassis of the vehicle. In the following, several options for creating a compressed natural gas (CNG) tank with small diameter tubing are disclosed. Also, how to pack that tubing into desirable geometries for use in the automotive industry is disclosed. Important design considerations are discussed: material stress, diffusion through the tank, and possible tank failure due to creep, fatigue, or thermal conditions.
It can be shown that it is possible to fill arbitrary shapes with small tubes without a loss in mass, here we discuss possible ways to pack these tubes. Because it is likely difficult, from a manufacturing stand point, to use actual Hilbert curves as a packing scheme alternative packing geometries are examined, and it is considered how well they fit into space (conformability factor). The conformability of a tank design (that is, the ratio of gas volume contained in the tank to the volume of the smallest bounding box of the tank) is a function of tube geometry, and packing geometry. To calculate conformability factor exactly, a precise definition of the packing scheme considered is needed, including bends.
In various embodiments, the tank has an inlet coupler at one end, the tank has multiple inlet couplers, the tank has an inlet coupler after a taper from the one or more straight sections of tube, the tank has an inlet coupler coupled to a reduced section of tube, or any other appropriate manner for coupling to the tank for access.
For straight cylindrical tubes, far away from the ends, the stress along the length remains constant. The magnitude of this stress depends on the radius and wall thickness of the straight lengths. Stress concentrations may also develop at tube ends, bends, or fittings.
Polymers or metals can be extruded into tubes that can be bent and packed into dense geometries. In order to develop an understanding of the load bearing capabilities of these tubes, a single length of cylindrical tubing without considering the end conditions is examined. For geometries where t/r≦1/20 we can use thin-wall theory to calculate the principal stresses in a cylindrical vessel. The stress is as follows:
For hoop stress it is assumed that the stress in the material is only due to the pressure inside the tank. The hoop stress acts circumferentially around the cylinder. Since this force is twice the longitudinal stress, it sets the required thickness of the tank at a given pressure and material yield stress.
with: Yield Stress (σy), Pressure (P), Inner Radius (r), Wall Thickness (t), Factor of Safety (fs)
The axial stress can be written as:
If we divide the hoop stress by the axial stress we get:
Again using a thin wall assumption: r≅R, we can say:
which dictates that the hoop stress is about twice that of the axial stress.
The tank mass is a function of tank pressure, volume and material properties. Therefore, tank mass and bulk material cost are not a function of tube radius. The equation for tank mass, for a single cross section straight cylindrical tube is:
Another important metric for CNG vehicles is overall tank energy density. For a fixed internal volume, energy density is determined from tank mass, where higher strength materials will drive down mass, and increase energy density.
High strength fibers such as Carbon and ultrahigh molecular weight polyethylene (UHMWPE) have greater strength-weight ratios than metals, making them attractive materials for CNG applications. By winding or weaving a fiber around a pressure vessel, the very strong fibers significantly increase the burst pressure of a vessel. Dry fiber reinforced vessels are made by weaving, braiding, or winding high strength fibers around a pressure vessel.
By optimally orienting the fibers, it is possible to balance the hoop and longitudinal stress evenly. The ideal angle to achieve this is called the hose angle. This angle makes sure that material strengths are being used the most effectively, which is valuable when the strength-weight ratio is driving design decisions.
In some embodiments, a fiber reinforced composites are more durable than dry fiber reinforcement because the matrix encases and protects the fibers. Carbon, the strongest commercially available fiber to date, is unfeasible in a dry application because the fibers are too fragile. The drawback of fiber reinforced composites is an increased manufacturing cost associated with laying the fibers up in a matrix.
To confirm that adding bends does not compromise the strength of the structure, the stresses in a pressurized bend needed to be determined. A torus, or section of a bend, can be geometrically represented as a circular cross-section of radius ro revolved around a fixed axis distance Ro from the center of the circle. The hoop stress in a section of the torus can be determined by applying conservation of momentum to two connected cross-sections of tube. This results in a general equation for pressure vessels that has a constant that needs to be determined. By examining the torus at the centerline where r=Ro and α=π/2, the constant can be found:
So, the equation for hoop stress in a torus is:
where α is the tangential angle of the circular cross section, c is substituted for
and r is the distance that the point is from the axis of rotation. Alternatively:
r=Ro+ro cos α
or:
using the fact that αs=−1/ro for a circle, and substituting in for r:
which simplifies to the equation of longitudinal stress in a straight cylinder
These equations show that longitudinal stress remains unchanged, that hoop stress increases minimally (e.g., 20% with a bend radius of 3.5 tube radii), and that the bend stress can be kept below the failure point of the tube by reducing the radius of the tubes at the bend.
For joining one tube into another calculating the braze area becomes more difficult. The path length of the miter can be calculated as:
The integral finds the path length around a quarter miter and r is the radius of the mitered tube (smaller tube), while a=R/r the ratio of radii of the large tube to the small. The obvious analogy with π shows us that the ‘circumference’ of the miter is given as:
C=ν(a)d
where
and d is the diameter of the small tube. Using ν(a), the braze area can be calculated as Ab=2 ν(a)rol, where ro is the smaller tube outer radius and l is the length of the interface (which will be the wall thickness of the larger end tube). Now we can write the braze length can be written as:
as R>>r, ν→π and R≧r the circular braze is the worst case scenario.
Unlike liquid fuels, gas fuels can diffuse through nonporous, seamless materials. Excessive diffusion is a concern because lost fuel leads to lost money, shorter range, and explosive gas mixtures. Additionally, diffusion linearly increases with both increasing surface area and decreasing wall thicknesses. The disclosed highly conformable design can achieve acceptable levels of natural gas permeation with both polymer-matrix composites and metal walls. This analysis is based on the solution-diffusion model for permeation through non-glassy polymers. The model assumes two different modes of transportation. The first, adsorption, is linearly approximated by Henry's law of solubility. This model describes the process of the permeate dissolving into and subsequently out of the membrane. The second is diffusion, which is treated as Fickian diffusion. This model approximates the transport of the gas through the membrane directly. The combination of these two modes can be linearly described by a diffusive gas permeability coefficient, which is the product of the solubility coefficient and the diffusion coefficient. This model only holds true when the polymers are below their glass-transition temperature with little or no pores. Given the small range of operating temperatures, Permeability is assumed to be independent of temperature. It is also assumed that permeability is independent of concentration and pressure, both are common assumptions. The equation for approximating this process is:
where Q is the volume flow (m3=sec) through the membrane, Δp is the difference of the gases partial pressure between the feed and permeate side of the membrane, t is the thickness of the membrane, A is the surface area and P is the diffusive gas permeability coefficient
P=D*S
Here D is the diffusion coefficient, and S is the solubility coefficient. Permeability values are often expressed in a wide range of units (barrer, cm3(STP)/(cm*s*mmHg), mL(STP)*mm/(m2*day*atm), etc.). In some embodiments, SI units are used for P (m3(STP)*m/(m2*s*Pa).
For the sake of simplifying the model, convection on the permeate side of the membrane is assumed to be zero. This gives the assumption that the mass fraction of methane on the permeate side is approximately 1, causing the model to be dominated by pressure. This is a reasonable assumption because the partial-pressure differential across the pressure vessel is very large. In a real system, even on the bottom of a fast-moving car, permeation rates will only be slightly higher than in this simplified system. Beginning by examining cylindrical tubes with no bends the surface area A is calculated from the tank's volume (V), inner radius (ri), and wall thickness (t):
Yielding the equation:
Three metrics can be used to determine if diffusion through the tank walls is a limiting factor: human safety, environmental impact, and perceived comfort. Methane is explosive when it is present in atmospheric concentrations between 5% and 15%. It is unsafe to be in a space with a methane concentration of more than 1%. If the worst air change rate case for a sedan cabin of 3.5 m3 is used (1 changeover/hour); and it is assumed that every bit of gas that escapes the tank goes directly into the car cabin, it can be calculated if a design is acceptable.
Permeation also needs to be considered. the ANSI/CSA NGV2-2007 16.12 Permeation Test requires that the steady state permeation for the tank be no more than 0.25 cc hour per liter water capacity of the container. ISO 11439:2000 has the same requirement. Further, the global warming potential of the diffused Methane should be considered in relation to the global warming potential of the Carbon Dioxide emitted from internal combustion vehicles. According to the EPA (as of 1997), the average passenger car consumes 550 gallons of gasoline, and emits 4,500 kg of CO2 each year. Methane has 25 times the global warming potential of CO2. The disclosed Methane gas intestine will need to emit less than 180 kg of methane/year. Design choices can make it so that greenhouse gas emissions due to diffusion from the small radius tank will be much less than the greenhouse gas emissions from an internal combustion engine.
Although Methane is an odorless gas, Methane suppliers often add other chemicals to Methane such as hydrogen sulfide to make the gas smell noticeable. There is a concern that diffused methane will smell before health concerns become a risk. If consumers can smell the gas, they will be distrustful of the technology, limiting its market viability. This threshold will need to be examined based on common aromatic gases that are added to methane. The effects of adding fiber reinforcement to polymers is not entirely understood. It is generally understood that wet layup FRPs have between 2 and 10 times the permeability of a pure polymer barrier. This effect increases as more layers are added to the composite. One explanation is that the wet layup process with fibers introduces voids that expedite diffusion. If this is the case, then vacuum layups or other layup techniques could reduce voids, reducing permeation. A factor of ten increase in permeability could rule out FRPs as a design option.
In some embodiments, a design goal is a variable radius cylinder which starts out with a large radius r0 and shrinks to a small radius r1<r0. The mean curvatures at the ends are 1=r0 and 1=r1. When the radius starts to shrink, the curvature in the axial direction changes from zero to positive, increasing the mean curvature. Since the amount of bending force is roughly proportional to mean curvature, higher mean curvature means a higher pressure can be resisted.
Unfortunately, eventually the taper must become concave in the axial direction in order to meet up with the smaller cylinder, causing a decrease in the mean curvature which must be countered by a smaller radius. This raises the question of the fastest possible taper that stays within a given mean curvature bound.
Let z be the distance along the axial direction, r=r(z) the variable radius and define:
E=1+R2z
The mean curvature is given by
The mean curvature of the large cylinder is 1/2r0, so the space of curves satisfying H≧1/2r0 needs to be understood. Extremal curves where equality holds are therefore solutions to
This equation appears impossible to solve analytically, but is easy to treat numerically. One solution option is a convex shape such as a partial spherical cap. Another solution option is to use single constant mean curvature curve with mean curvature larger than 1/2r0, chosen such that the ratio between the minimum and maximum radii is r0/r1. There are likely further options, so further criteria are needed to pick out the best one.
Examining the extreme cases of objects with no curvature in one direction establishes that having a constant mean curvature does not guarantee that stress is maintained as constant. Instead, a pair of coupled equations generated from examining differential, axi-symmetrical elements can be used to create curves of continuously varying stress when revolved and pressurized. Performing a transformation from cylindrical coordinates to cartesian coordinates yields equations below in [0053], obtaining a first and second piola-kirchhoff stress in relation to the cauchy stress tensor in the ‘undeformed’ material.
P=J∇F
−T
S=JF
−1
σF
−T
F=∇p
p=[r(s)cos(θ),r(s)sin(ƒ),z(s)]
J=det F
In the equations above, p is the curve parameterized by s (the length travelled along the curve), and J is the Jacobian. Since the Jacobian is 1,
P=F S
The fact that the first piola-kirchhoff tensor represents the cylindrical stresses on a cartesian plane can be used to apply the divergence theorem in cylindrical coordinates to get the equation:
Where c is the ratio internal pressure/wall thickness, and n is the normal vector
n=[cos(α)cos(θ),cos(α)sin(θ),−sin(α)cos(θ)]
This gives us the system of equations:
which can be simplified by evaluating the system at θ=0
This system of differential equations can be simplified by canceling the Ssss terms to yield the relationship:
which defines the relationship between axial and hoop stress for any axi-symmetric pressure vessel. Another equation for Sss can be derived from applying conservation of momentum to a differential element of varying radius:
2πr1 cos(α1)σ|s1−2πr0 cos(α0)σ|s0−2πc∫s0s1r(s)sin(α(s))ds=0
Substituting sin(α(s))ds=dr and evaluating the integral, the following relationship is found:
rS
ss cos(α)−cr2/2=const
Since any physical pressure vessel must eventually have a radius of zero to close the volume, the constant must always be equal to zero. Therefore, the following relationship is derived for axial stress:
Therefore, a closed form solution for Saa as well:
The hose angle for any geometry is then.
The above equation demonstrates that a line which is constrained to have αs=0 at the junction with a cylinder will have a continuously varying braid angle without any discontinuities. Any curve which has a continuously varying curvature (e.g., with no discontinuity in the change of curvature), tangential angle, and radius and satisfies α(0)=0, αs(0)=0, α(end)=0, and αs(end)=0 when revolved around the axis of symmetry, will allow for the construction of a taper with continuously varying braid angle.
This taper is created by establishing the necessary boundary conditions and generating a curve that matches either the hoop or axial stress of the larger cylinder according to the coupled ordinary differential equations (ODEs) below. That curve is then revolved around a central axis and subsequently braided over to create a composite without any discontinuities in braid angle.
In some embodiments, a taper to a reduced radius section of a tube has a continuously varying curvature. In some embodiments, the continuously varying curvature enables the targeting of an optimized braid angle for the overbraid. For example, the optimized braid angle helps maintain the desired shape of the tube (and the braid) under pressure after being bent into desired shape from a straight shape (e.g., the braid does not later move or deform significantly). In some embodiments, this enables a dry braid to be used. In some embodiments, a taper targets optimization of the internal volume of the bend without exceeding a stress maximum of the bend.
Working with a braiding machine will allow building prototypes of both a snake design and a spiral. The spiral design requires tapering of the braid, and bending the braid before laying it in a mold and curing it. Below a braid is described that reduces diameter and maintains hose angle. The hose angle is defined here to be the fiber angle that equalizes hoop and axial stress. A prototype of a square spiral can be achieved using a triaxial braid with helical third axis.
With full control over the mandrel feed rate (ν) and carrier angular velocity (w) it is possible to create a tapered braid that maintains stress equilibrium in the fibers over the taper. This builds on the definition of the hose (or ideal) angle established above. A definition of hose angle is developed for tapered braids. In a braided pressure vessel, the axial force and hoop force should be in equilibrium. This is achieved by adjusting the braid angle (θb) such that the portion of hoop force and axial force in the braid fibers is equally carried by the tension in the fiber. Since the hoop force is a function of cone radius, angle, and curvature we expect that the braid angle will be as well. In a traditional, cylindrical, pressure vessel this angle takes on a single value (arctan √{square root over (2)}) and is called the ‘hose’ angle (the braid angle of a braided fire hose). To find the ‘hose’ angle for a cone we assume square cross-section braid fibers with thickness t. The axial stress balance for the fibers is given by:
T sin θh=σaxial tan θh
The hoop stress balance for the fibers is:
T cos θh=σhoop
dividing and solving for θh we get:
Braiders will be able to use this equation to dynamically set machine parameters and keep that braid angle ideal throughout the braiding process. Although it is likely that braiders will use this relationship to determine the parameters for their specific machine, a general way is developed here to translate between ideal braid angle and angular velocity of carriers (ω), and take-up speed (ν). A basic equation for braid angle would be:
θb=arctan(ωR/ν)
Solve for ω/ν to get a relationship between braid radius and the ratio of carrier angular velocity to take-up speed.
Given a function R(z), that is the shape of the mandrel along the z axis, an equation is obtained for the takeup speed at a fixed carrier frequency as a function of mandrel position.
The cover fraction (cf) is the fraction of the surface area of a composite braid that is covered by fiber. In pressure vessels, having a cover factor that is too small will result in excessive radial shear stresses acting on the diamond shaped interstices in between the fibers of a biaxial weave. Those interstices are triangular in a tri-axial weave. When the shear forces exceed the shear strength of the matrix, the structure fails as the interstices ‘blow out.’ A geometric function of the minimum acceptable cover factor is defined assuming ideal braid angle and isotropic matrix. The blow-out force on a unit diamond (the space defined by the area between the middle of the yarn for four interlacing fibers) is equal to the area in between the fibers which is defined as:
Where A is the area between the fibers, θ is the braid angle, R is the radius of the tube, n is the number of carriers, and w is the width of the carriers. This force is applied in shear across the diamond. Due to scaling laws (surface area vs. edge length), the largest shear stress will be experienced at the boundary of the interstitial diamond. The perimeter of the area is defined by the fiber geometry as:
Since stress is the ratio between force and area:
Where P is the pressure inside the vessel, and t is the thickness of the epoxy
Including the geometric definition of coverage factor:
or
ωn=4πR cos θ(1−√{square root over (1−cp)})
and using the equation for the optimal winding angle for the section of a cylindrical pressure vessel that is at a constricted radius relative to the widest section of tube:
Where Ro is the maximum radius of the pressure vessel, and a is the angle of the taper. The function of a minimum acceptable cover factor at a given radius reduction and the ideal braid angle is given by:
As long as the above inequality is true, within a factor of safety for τyield, the material will not fail by having a blowout. The actual cover factor for the tapered braid can be calculated as above. It is assumed that the number of carriers (n) and the yarn width (ω) are constant over the braid. At the largest radius (Ro) the cover factor is Co and the braid angle is θo. It is convenient to define two constants:
where
B=nω/(4π)
The cover factor is then
In some embodiments, the taper is braided using the ‘hose’ angle, θh, and the ideal taper is:
Once the nominal radius is chosen, and the reduced radius (as well as values for the number of carriers and yard width), the inequality governing the risk of blowout is as follows:
In some embodiments, a braided fiber based tank is constructed by over braiding a polymer liner. For example, the polymer liner is created as a single long tube with reduced sections that will bend when the tank is folded into shape. In some embodiments, a plurality of straight sections of tube comprise a single long tube with reduced radius sections. In some embodiments, the reduced radius sections comprise bent sections (e.g., where the reduction has considered the desired bending, wall thickness, spacing of the larger tubes, to make the desired packing without deformation of the bend section or mechanical failure when bending). In some embodiments, this liner can be formed as a single unit blow molded from a single die or with a set of discrete length dies. In some embodiments, the plurality of straight sections of tube comprise multiple long tubes with reduced radius sections that are joined together (e.g., sealed together). In some embodiments, the liner sections can be molded separately and connected with a smaller diameter tubes and sealed into a larger assembly as shown in
All metal, type I, tanks are the lowest cost option for CNG storage. Metals manufacturing has a longer and more developed history than that of composites. Inexpensive and efficient methods for forging and forming metal geometries are common, readily accessible, and sufficiently vetted for safety and long term viability.
In some embodiments, the type I tank is a fully brazed-T-pulled designed. The fully brazed tank uses straight lengths of tube with tapered (swaged) ends. The ends are brazed onto a ball pulled tube in a bulk brazing process. Layers could be hexagonally packed and connected again using a ball pulled tube.
In some embodiments, the type I tank includes swaged straight tubes that are brazed onto U joints. Similar to the above design the joints will be easier to braze or weld. In some embodiments, it is possible to swage straight lengths of tube at the ends, tapering and increasing wall thickness enough to allow internal or external national pipe threads (NPT). Once threads are made hydraulic hose or small diameter thick walled tubing can be used to connect to the ends.
In some embodiments, it is possible to swage or otherwise form a tube so that the center of the tube has a reduced diameter. With special tooling a mandrel bender could be used to bend this tube into a snake. The snake would be a single layer of a larger, hexagonally packed. In some embodiments, it is possible to swage straight lengths of tube at the ends, tapering and increasing wall thickness enough to allow internal or external NPT threads. Once threads are made hydraulic hose or small diameter thick walled tubing can be used to connect to the ends.
In some embodiments, it is possible to swage or otherwise form a tube so that the center of the tube has a reduced diameter. With special tooling a mandrel bender could be used to bend this tube into a snake. The snake would be a single layer of a larger, hexagonally packed.
In some embodiments, in order to utilize current bending technology with minimum custom tooling a single diameter tube could be bent into a spiral. Spirals can stack hexagonally to allow for better packing density. One disadvantage of the spiral tank is that to achieve maximum packing density, the turns of the spiral need to be touching, which does not leave enough room for many tube-bending dies. By making one layer of a tank out of two (or more) spirals that have 1 diameter spacing between the turns and interlacing them at a 180 degree offset, you can achieve similar packing density to a tight spiral with relaxed manufacturing constraints.
In some embodiments, in order to achieve sufficient energy density for light vehicle applications, the tank must weigh <100 kg. To achieve this, high yield strength steels or aluminums are used. Because of complexities with joining aluminum alloys in some embodiments steel is selected. In some embodiments, brazing options are eliminated because of the inconsistency introduced from that number of brazed joints, as well as the difficulty in fixturing the assembly for batch brazing. A similar argument holds against mechanical fittings. In some embodiments, a bent snake is selected because of the lack of fittings or joins, but forming the reduced sections is challenging.
In some embodiments, a bent square spiral is a good design because of the convenience of having only quarter bends with relatively large bend radius. In various embodiments, bent square spirals are used for a tank where the bent square spirals comprise one of the following: a single long tube square spiral closely packed, a single sparse square spiral, a double-sparse square spiral, or any other appropriate spiral.
In some embodiments, hexagonally packed fiber tube systems are used for tanks. A traditional carbon fiber structure can be made from straight carbon fiber reinforced polymer (CFRP) tubes with glued in end-caps. These end-caps might consist of “U” bends that join two adjacent tubes together. The straight tubes are pultruded in a continuous process, and the end caps made in a batch molding process. The wall thickness of the end of the pultruded tube is given a slight taper, which is matched by a slight taper in the end-cap. These elbows can be either composite or metal hydraulic hose.
In some embodiments, instead of depending on bond strength to hold the end-caps in place, it is possible to use external CFRP bands or through rods that run parallel to the pultruded tubes and take the full axial load, holding the end-caps in against the internal pressure. For this case, the pultruded tube need have circumferential fibers, and so can have a thinner wall thickness, the axial fiber requirement being shifted to the external bands or through rods.
In some embodiments, stacked spiral composite structures can be made by wet pultruding the carbon fiber weave over an ethylene vinyl alcohol (EVOH) liner and laying it into a two part spiral mold with a breather cloth. The EVOH liner is pressurized, and a vacuum is pulled over the mold to drive out any air, off-gas, and excess resin. The spiral tank layers is stacked and connected using a carbon spine that runs along the outer edge of the tank.
In some embodiments, a modular design of a long carbon fiber (CF) tube is laid into a square spiral. For example, a tube diameter is between 0.6″-2″, and a bounding box is about 3′×3′. The spiral tanks are stacked hexagonally to form larger volumes.
In some embodiments, the densest packing with the most flexibility is to stack tubes hexagonally and simply connect the ends.
In some embodiments, using a continuous internal liner as a mandrel, the entire tank is braided in a single process. The shape of the tank is ‘programmed’ into the liner such that reduced sections is bent into elbows after braiding.
In various embodiments, the tank is used to store other gases than natural gas and conform to a volume—for example, air, oxygen, carbon dioxide, nitrogen, or any other appropriate gas.
Although the foregoing embodiments have been described in some detail for purposes of clarity of understanding, the invention is not limited to the details provided. There are many alternative ways of implementing the invention. The disclosed embodiments are illustrative and not restrictive.
This application is a continuation of, and claims priority to, U.S. Non-Provisional patent application Ser. No. 14/624,370, entitled COILED NATURAL GAS STORAGE SYSTEM AND METHOD and filed Feb. 17, 2015, which is a continuation of, and claims priority to, U.S. Non-Provisional patent application Ser. No. 13/887,201, entitled CONFORMING NATURAL GAS STORAGE and filed May 3, 2013, which claims priority to U.S. Provisional Patent Application No. 61/642,388, entitled CONFORMING ENERGY STORAGE and filed May 3, 2012, and to U.S. Provisional Patent Application No. 61/766,394, entitled NATURAL GAS INTESTINE PACKED STORAGE TANK and filed Feb. 19, 2013, each of which is incorporated herein by reference for all purposes.
This invention was made with Government support under DE-AR0000255 awarded by the US DOE. The Government has certain rights in this invention.
Number | Date | Country | |
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61642388 | May 2012 | US | |
61766394 | Feb 2013 | US |
Number | Date | Country | |
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Parent | 14624370 | Feb 2015 | US |
Child | 15232355 | US | |
Parent | 13887201 | May 2013 | US |
Child | 14624370 | US |