US20220363022A1 - Composite rail tie apparatus and method - Google Patents
Composite rail tie apparatus and method Download PDFInfo
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- US20220363022A1 US20220363022A1 US17/827,579 US202217827579A US2022363022A1 US 20220363022 A1 US20220363022 A1 US 20220363022A1 US 202217827579 A US202217827579 A US 202217827579A US 2022363022 A1 US2022363022 A1 US 2022363022A1
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- Prior art keywords
- fill
- tie
- shell
- rail
- fastener
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Images
Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B29—WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
- B29C—SHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
- B29C70/00—Shaping composites, i.e. plastics material comprising reinforcements, fillers or preformed parts, e.g. inserts
- B29C70/04—Shaping composites, i.e. plastics material comprising reinforcements, fillers or preformed parts, e.g. inserts comprising reinforcements only, e.g. self-reinforcing plastics
- B29C70/28—Shaping operations therefor
- B29C70/40—Shaping or impregnating by compression not applied
- B29C70/50—Shaping or impregnating by compression not applied for producing articles of indefinite length, e.g. prepregs, sheet moulding compounds [SMC] or cross moulding compounds [XMC]
- B29C70/52—Pultrusion, i.e. forming and compressing by continuously pulling through a die
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B29—WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
- B29C—SHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
- B29C70/00—Shaping composites, i.e. plastics material comprising reinforcements, fillers or preformed parts, e.g. inserts
- B29C70/68—Shaping composites, i.e. plastics material comprising reinforcements, fillers or preformed parts, e.g. inserts by incorporating or moulding on preformed parts, e.g. inserts or layers, e.g. foam blocks
- B29C70/74—Moulding material on a relatively small portion of the preformed part, e.g. outsert moulding
- B29C70/745—Filling cavities in the preformed part
-
- E—FIXED CONSTRUCTIONS
- E01—CONSTRUCTION OF ROADS, RAILWAYS, OR BRIDGES
- E01B—PERMANENT WAY; PERMANENT-WAY TOOLS; MACHINES FOR MAKING RAILWAYS OF ALL KINDS
- E01B3/00—Transverse or longitudinal sleepers; Other means resting directly on the ballastway for supporting rails
- E01B3/46—Transverse or longitudinal sleepers; Other means resting directly on the ballastway for supporting rails made from different materials
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16B—DEVICES FOR FASTENING OR SECURING CONSTRUCTIONAL ELEMENTS OR MACHINE PARTS TOGETHER, e.g. NAILS, BOLTS, CIRCLIPS, CLAMPS, CLIPS OR WEDGES; JOINTS OR JOINTING
- F16B7/00—Connections of rods or tubes, e.g. of non-circular section, mutually, including resilient connections
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B29—WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
- B29C—SHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
- B29C70/00—Shaping composites, i.e. plastics material comprising reinforcements, fillers or preformed parts, e.g. inserts
- B29C70/04—Shaping composites, i.e. plastics material comprising reinforcements, fillers or preformed parts, e.g. inserts comprising reinforcements only, e.g. self-reinforcing plastics
- B29C70/28—Shaping operations therefor
- B29C70/54—Component parts, details or accessories; Auxiliary operations, e.g. feeding or storage of prepregs or SMC after impregnation or during ageing
- B29C70/545—Perforating, cutting or machining during or after moulding
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B29—WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
- B29L—INDEXING SCHEME ASSOCIATED WITH SUBCLASS B29C, RELATING TO PARTICULAR ARTICLES
- B29L2031/00—Other particular articles
- B29L2031/06—Rods, e.g. connecting rods, rails, stakes
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B29—WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
- B29L—INDEXING SCHEME ASSOCIATED WITH SUBCLASS B29C, RELATING TO PARTICULAR ARTICLES
- B29L2031/00—Other particular articles
- B29L2031/10—Building elements, e.g. bricks, blocks, tiles, panels, posts, beams
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16B—DEVICES FOR FASTENING OR SECURING CONSTRUCTIONAL ELEMENTS OR MACHINE PARTS TOGETHER, e.g. NAILS, BOLTS, CIRCLIPS, CLAMPS, CLIPS OR WEDGES; JOINTS OR JOINTING
- F16B15/00—Nails; Staples
- F16B15/06—Nails; Staples with barbs, e.g. for metal parts; Drive screws
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16B—DEVICES FOR FASTENING OR SECURING CONSTRUCTIONAL ELEMENTS OR MACHINE PARTS TOGETHER, e.g. NAILS, BOLTS, CIRCLIPS, CLAMPS, CLIPS OR WEDGES; JOINTS OR JOINTING
- F16B37/00—Nuts or like thread-engaging members
- F16B37/005—Nuts or like thread-engaging members into which threads are cut during screwing
Definitions
- This invention relates to railroad crossties and, more particularly, to novel systems and methods for construction thereof from composite structural materials.
- Rail ties sometimes called rail ties or simply ties, have traditionally been constructed of wood.
- Wood provides a structural platform sitting on top of road ballast, rock of specified size distribution.
- the crosstie provides sufficient “flotation” (load pressure distribution) to support the substantial weight of the axles of a railroad train passing over the top thereof.
- Each rail is secured near one end of each crosstie in order to provide support for a train.
- rail ties have been cut from or formed of various wood products, including hardwoods such as oak, as well as softer woods such as pine or spruce.
- rail ties have been treated with creosote, a thick, oily liquid that is highly viscous and is typically soaked into the rail ties as an insecticide or pesticide to prevent or resist rotting of the wood.
- the spikes that have secured plates to the ties may eventually begin to loosen. As wood weathers, splits, shrinks, and the like, the spikes may loosen. Accordingly, the base plate underneath each rail, on top of a tie, as well as the securement plates that attach over the top of the base of the rail, may work loose and fail to provide adequate securement.
- Recycled crumb rubber is made up of the ground up rubber material from tires, usually absent the fibrous cord materials, such as nylon and rayon, or other polymer cords, and substantially devoid of any of the metals that previously formed the bead and the radial bands of seal reinforced tires.
- a method and apparatus including a process method, equipment, and product for making and using railroad ties formed by pultrusion or other molding processes as fiber-reinforced, polymeric, composite materials.
- the processes and devices may produce an outer shell formed of fiber-reinforced polymer engineered to have the proper strength, stiffness, modulus of elasticity, modulus of rupture, and other mechanical properties necessary to serve as a rail tie.
- a fill material may be selected from concrete, lightweight concrete, expanded polymer, expanded elastomer (elastomeric polymer), or the like. Any fill may, in turn, include an “inner fill” or “bulking agent” such as air, glass beads (hollow spheres), polymer bubbles or spheres, to bulk it up while reducing cost and density or total weight. These may include also sawdust, recycled wood, recycled wooden rail ties, or the like
- the axial cross-section of a tie may be designed to provide the proper mechanical properties to support a railroad rail passing over a tie. These include supporting the load, resisting chafing, securing the rail to the tie, resisting deflection, resisting buckling, retaining a spike or other fastener, and resisting weather, wear, and the other environmental exposure expected for a rail tie.
- the fiber reinforcement may typically be glass, but may be formed of another polymer. However, glass is typically a cost effective solution to fiber reinforcement, having comparatively lower costs and comparatively higher strength and stiffness than other candidate fibers. Meanwhile, the fiber reinforcement may be configured as continuous filament mats (e.g., non-woven) or a woven mat or layup of multiple directions of fibers accessing each of the principal stress directions of zero degrees, 90 degrees, and positive and negative 45 degrees with respect to zero.
- a pultrusion system may provide guides to assist in directing fiber reinforcement rovings as strands, CFM mats, or oriented fiber fabrics such as quadraxial non-crimp fabric, into a molding system that embeds the fiber reinforcement into a polymer matrix and the polymer matrix may be a thermoplastic, but may be well suited to various thermoset, including epoxies, polyesters, and so forth.
- Post processing may include curing, cooling, heating, and the like.
- a pultrusion system will rely on rollers to grip the solidified, cured product and dry it continuously from the pultrusion system.
- Ties may be cut to length after manufacture as a continuous beam, typically at a length of about 102 inches in accordance with conventional railroad tie sizing. Meanwhile, the lateral and transverse dimensions are typically nine inches and seven inches, respectively, where lateral is a horizontal direction orthogonal to the axial length of a tie, and the transvers direction is the vertical, orthogonal direction with respect to the horizontal, axial direction of the tie in service.
- fastener systems may be of configurations, sizes, types, and materials best adapted to the fill material in the tie.
- Fill materials may be drilled, piloted, or otherwise provided with an aperture sized to receive a fastener.
- Apertures may be formed to provide an interference between the outer dimensions thereof, and may be of any suitable shape, although a round hole is easiest to drill by rotary motion.
- fasteners may be driven such as spikes, wherein frictional forces secure the fastener within the fill of a tie.
- fasteners may be threaded, barbed, or otherwise designed to provide pullout strength and securement of a rail to the tie.
- an aperture drilled in the fill, and necessarily passing through the outer shell of a tie may be made oversized such that no interference exists with a fastener, in order to be later back filled with a suitable material for bonding and binding to the fill, in order to provide adequate purchase (grip, holding power) of a fastener with respect to the fill.
- a comparatively lighter density of fill may be used, with a comparatively higher density of backfill into an aperture or cavity formed near (e.g. surrounding) a fastener penetrated into the tie, and particularly into the fill thereof after having passed through the shell.
- apertures may include recesses, relief, countersinks, and so forth.
- Lag systems may be included wherein a compression sleeve is fitted into an aperture in the tie, after which a threaded fastener, such as a lag screw is threaded into the lag sleeve, thus swelling the lag sleeve and forcing it into a compression fit within the fill.
- Fasteners may include self tapping screws, bolts, lag screws, rivets, blind rivets, meaning fastener having a main shank that is segmented along axial lines and perforated through its length. A passage along a center axis receives a swage driven into the fastener after the fastener is in place for use.
- the fastener is inserted by whatever mechanism desired, whether hammered, driven axially, threaded in, or the like after which a swage element is driven down the central passage.
- the swage separates out the multiple segments of the shank, spreading them apart and rendering the fastener effectively a rivet in practice.
- This particular mechanism is particularly appropriate for a composite tie in accordance with the invention, because it then allows the fiber reinforced polymeric shell to act as part of the mechanism of securement against pullout or relaxation of load.
- a spreadable, rivet-like fastener may be driven, placed without resistance, or threaded into an aperture before being swaged out.
- Analyses of various designs, materials, fill densities, and so forth have been conducted and indicate a rail tie system in accordance with the invention as described hereinbelow appears to have the suitable mechanical properties for satisfactory service as a railroad tie.
- FIG. 1 is a perspective view of one embodiment of a rail system partially cut away, implementing a tie in accordance with the invention
- FIG. 2 is a perspective view of one end of a tie in accordance with the invention, also illustrating end cross-sectional views of certain alternative embodiments of the tie;
- FIG. 3 is a perspective view of one embodiment of a continuous fiber mat (CFM) for reinforcing a composite construction for a tie in accordance with the invention
- FIG. 4 is a perspective view of one embodiment of a stack-up of various oriented fibers being assembled into a quadraxial non-crimp-fabric (NCF) having four different fiber orientations directed to principal stress directions;
- NCF quadraxial non-crimp-fabric
- FIG. 5 is a perspective view of one embodiment of a pultrusion system for manufacturing rail ties in accordance with the invention.
- FIG. 6 is a side elevation, cut away, cross-sectional view of a portion of one embodiment of a tie in accordance with the invention, illustrating securement of a rail thereto on a supporting plate anchored by fasteners in apertures within the ties;
- FIG. 7 is a perspective view, partially cut away, of a segment of a tie in accordance with the invention, having an aperture therein for receiving various shapes of fasteners having a variety of cross-sections, and varying amounts of interference;
- FIG. 8 is a side elevation, cross-sectional view, partially cut away, illustrating two different apertures for receiving fasteners into the tie in accordance with the invention
- FIG. 9 is a side elevation, cross-sectional view of one alternative embodiment of an aperture for receiving a fastener into the tie in accordance with the invention.
- FIG. 10 is side elevation, cross-sectional view of an alternative embodiment of an aperture in a portion of a rail tie in accordance with the invention, this having more of a pilot hole configuration, with comparatively greater interference;
- FIG. 11 is a side elevation, cross-sectional view of another alternative embodiment of an aperture in a portion of a rail tie in accordance with the invention, for receiving a threaded fastener, and having a counter sunk opening;
- FIG. 12 is a perspective view of one embodiment of a fastener, a spike lacking threads and having a rectangular cross section;
- FIG. 13 is a side elevation, cross-sectional view of an alternative embodiment of a fastener having a self tapping point, followed by a threaded shank or shaft thereabove, and driven by a head shaped to receive an internal wrench as a drive tool for installing the fastener;
- FIG. 14 is a side elevation, cross-sectional view of an alternative embodiment of a fastener illustrating two types of shanks, one barbed, and the other not, with a central channel within the fastener for receiving a spreader that operates as a wedge or swage element dividing the shank into multiple segments and spreading them away from one another in order to provide a riveting type of securement process in a tie in accordance with the invention;
- FIG. 15 is a side elevation, cross-sectional view thereof in a deployed configuration
- FIG. 16 is a side elevation, cross-sectional view of an alternative embodiment of a fastener, in accordance with the invention, providing threads on the shank, between the head and a point thereof, and including a swage element or spreader to spread the diameter of the threaded shank into multiple segments that may then spread apart and secure the fastener within a tie;
- FIG. 17 is a side elevation view of an alternative embodiment of a fastener having threads on a shank and driven by a head, such as a hexagonal head adapted to fit the shape of a wrench;
- FIG. 18 is a perspective view of one embodiment of a portion of a tie evaluated with a top plate to determine the functional properties thereof in service;
- FIG. 19 is an end cross-sectional view of the tie thereof in an embodiment having sharper corners on the lower surface thereof, to increase the section modulus at the bottom extremum of the cross-section;
- FIG. 20 is a table illustrating the stiffness properties of the shell portion of the tie as analyzed
- FIG. 21 is a table illustrating the strength properties of the shell
- FIG. 22 is a table illustrating the stiffness and strength properties of the expanded polyurethane or polyurethane resin (PUR) foam at various densities;
- FIG. 23 is a side elevation view of the tie segment, surmounted by the compression plate and a rail, illustrated in cross-sectional view, as loaded for the evaluation;
- FIG. 24 is a perspective view of the grid or mesh of finite elements used in analyzing the performance of the rail tie
- FIG. 25 is a perspective view of a distribution of vertical displacements thereof in the tie under compression loading
- FIG. 26 is a chart showing curves of the elastic deformations thereof under a 100,000 pound force compressive load on a tie in accordance with the invention as a function of various constitutions of reinforcing fibers;
- FIG. 27 is a chart illustrating various minimum values of shell thickness and polyurethane resin densities used in analysis to meet the compression, modulus of elasticity (MOE), and modulus of rupture (MOR) wherein the shell thickness-to-fill density region above the curves corresponds to safe tie designs according to the established criteria, and shell thicknesses or fill densities lower than the curves are considered unsafe;
- MOE modulus of elasticity
- MOR modulus of rupture
- FIG. 28 is a chart illustrating values of modulus of elasticity as a function of fill density
- FIG. 29 is a chart illustrating values of modulus of rupture as a function of the fill density.
- FIG. 30 is a chart illustrating the weight of a single rail tie, having a length of 102 inches, charted against the fill density along the horizontal axis, wherein each curve represents a different reinforcing fiber configuration.
- FIG. 31 is a cut-apart, perspective view of an alternative embodiment of a composite rail tie having no bottom wall, and thereby an open cross section for the shell containing the fill;
- FIG. 32 is a perspective, cut-away view thereof illustrating additional cross sectional views of optional cross sections that may be fabricated in accordance with the invention.
- FIG. 33 is a schematic block diagram of a process for creating a composite, protruded rail tie, having a conventional, used, rail tie as a core or principal filler inside thereof;
- FIG. 34 is a schematic block diagram of a core preparation process that may be part of the process of FIG. 33 , or may precede it;
- FIG. 35 is a process flow diagram illustrating various cross sectional views of a core and a composite rail tie in accordance with the invention.
- FIG. 36 is a series of cross sectional views of alternative embodiments of a composite rail tie filled with a portion of a conventional wooden tie as a core, which may take on any of the cross sections and use any of the fill materials around the core that have been discussed herein.
- a system 10 in accordance with the invention may implement a composite construction for a rail tie 100 .
- a tie 100 may be of a conventional size in order to meet replacement needs (retro fit) in systems already using conventional ties.
- Conventional ties are typically cut from wood, treated to extend their service life. Typical height from a railroad bed of a ballast rock is about seven inches. Meanwhile, the typical width of a tie is nine inches. Meanwhile, the conventional length of 102 inches is consistent with the width between rails that was established supposedly by the width of a chariot on the roads of ancient Rome. Thus, the tie 100 may have these traditional dimensions.
- a tie 100 may be formed of a shell 102 formed of a composite structural material.
- the composite material of the shell 102 may be a polymeric matrix of resin such as a polyester resin, epoxy resin, or other thermoset resin.
- a thermoset resin will be cured by any of several means, including heat. However, the addition of heat after cure will not result in liquefaction of the resin. That is, thermoset resins cure. They may require heat to induce the cure, and may be exothermic (giving off heat, rejecting heat) in the process of curing. Thereafter, they will typically maintain a solid state, even to the point of being completely carbonized in a furnace.
- the polymer may be a thermoplastic.
- Thermoplastics differ from thermosets in that a thermoplastic may be reheated to become liquefied again.
- One benefit to thermosets over thermoplastics is that thermosets are less vulnerable in service to excessive environmental temperatures.
- the shell 102 is typically filled with a fill material 104 or fill 104 formed of a very different constituent, which may also be a composite.
- the fill 104 may be concrete.
- Such concrete materials may be substantially similar to those used for concrete structures in various civil engineering projects. Walls, buildings, sidewalks, and the like use a combination of aggregate, sand, and Portland cement rendered active by the addition of water and mixing.
- various types of concrete may include greater or lesser amounts of sand, greater or lesser amounts of aggregate, greater or lesser amounts of cement, greater or lesser amounts of other additives, and greater or lesser amounts of water and curing agents.
- the fill 104 may be concrete having an engineered fraction of expanded polystyrene. It has been found that particles of expanded polymers, such as polystyrene, will reduce the weight of concrete. It also provides additional toughness against fracture. Point loads, sharp impacts, and the like will often fracture conventional concrete. The addition of other polymeric fillers that introduce not only a polymer but additional entrapped air in the expanded polymer have been found to provide additional toughness and resistance to fracture. Moreover, the addition an expanded polymer, such as expanded polystyrene may permit, or perhaps more clearly enable, the engineered control of density of the overall fill 104 when installed. This enables creation of ties 100 of substantially any desired mass or weight.
- recycled crumb rubber has been found to have many properties suitable for application to structural support.
- a binding resin may be mixed with recycled crumb rubber (RCR) as a fill 104 inside the shell 102 of a tie 100 in accordance with the invention.
- the fill 104 may be an expanded polyurethane resin (PUR).
- PUR polyurethane resin
- Polyurethane may be manufactured in a multiplicity of grades, providing various degrees of hardness, various degrees of flexibility, various degrees of density, and so forth. Meanwhile, PUR may be configured in a variety of elasticity and strengths.
- elasticity of a material is meant the elastic modulus. That is, the elastic modulus defines the behavior of materials that abide by Hooke's law.
- Hooke's law is the law of spring constants. It basically states in mathematical form that a force is equal to the spring constant of a material multiplied by the deflection (movement, distortion, bending, etc.) of the spring material. The force acts opposite to the direction opposite to the deflection.
- a spring in compression provides a force in the opposite direction from the compression, proportional to the deflection. That constant of proportionality is often referred to as “k” or the spring constant.
- the elastic modulus is related to stress and strain. That is, the elastic modulus is also characterized in a material as the stress (force per unit area) applied to a material, divided by the strain (deflection in length per unit length) undergone by the material being loaded (having a force applied).
- the shell 102 is composed of walls 106 .
- a trailing letter following a reference numeral indicates a specific instance of a particular item identified by the reference numeral.
- it is proper to speak of a wall 106 generally, of a shell 102 .
- we may identify specific walls such as the upper wall 106 a or top wall 106 a , the bottom wall 106 b , or either of the side walls 106 c.
- the upper wall 106 a (or any wall 106 ) may be coated with a coating 108 .
- the bottom wall 106 b may be coated with the same coating 108 or another.
- the upper wall 106 a may be coated with one material 108 a , having one set of properties while the lower wall 106 b is coated with a different coating 108 b of different properties.
- the entire exterior or outer surface of the shell 102 may be coated with a coating material 108 selected for universal use on any and all sides.
- the reinforcing material within the polymeric resin that forms the shell 102 is typically glass. It may be some other polymer, or a mixture of materials. However, the cost and performance of glass fiber make glass fiber an excellent candidate as a reinforcing material in a matrix of polymeric resin forming the shell 102 of each tie 100 .
- the coating 108 may provide mechanical damping, mechanical deflection, and stress relief, as well as protection against chafing.
- a coating 108 may provide protection of the glass fibers and resin in the shell 102 from sharp objects, wear, chipping, impacts, and the like to which they may be susceptible.
- the coating 108 may also provide protection against ultra violet or other electromagnetic radiation (e.g., sunlight and its constituent parts), weather (rain, freezing, dust, etc.) chemical attack, or the like.
- the coating 108 may have different properties to meet different requirements.
- a significant performance concern for rail ties 100 is lateral ballast resistance.
- the lateral resistance parameter is important to the ability of railroad tracks to maintain their alignment over time and traffic.
- a polymer and its reinforcing material forming the shell 102 may tend to have a comparatively lower coefficient of friction than, for example, a rubber or elastomeric polymer material
- the ability to resist lateral motion may be improved by the addition of the layer 108 b of a coating 108 on the lower wall 106 b.
- protection against chafing by the rock within the road bed (ballast) supporting a rail tie 100 may reduce impact, distribute loads, prevent point loads, and otherwise maintain the integrity of the shell 102 under the force of compression represented by a train passing over the tie 100 , and “grinding it into” the road bed.
- a coating 108 a on the upper wall 106 a may prevent chafing by a rail assembly 110
- the coating 108 b may provide protection against the chafing of rock. It may provide increased resistance to lateral movement of the rail 112 , which is longitudinal movement of the tie 100 , with respect to the ground and the road bed.
- the rail assembly 110 includes a rail 112 crossing a sequence of ties 100 .
- Each rail 112 is typically supported by a plate 114 that distributes the load of the rail 112 across a broader surface area of the shell 102 of the tie 100 than would be covered by the rail 112 itself.
- a keeper 116 securing the rail 112 to the tie 100 .
- a rail assembly 110 including a plate 114 , a keeper 116 on each side of a rail 112 , and the rail itself crossing that tie 100 .
- fasteners 120 have been spikes 120 driven through apertures in the keeper 116 and plate 114 .
- a portion of the keeper 116 extends over the bottom of the rail 112 in order to secure it in place.
- the keeper 116 registers the rail 112 along the length or longitudinal direction of the tie 100 .
- the keeper 116 holds the rail 112 down in contact with the plate 114 , keeping both the plate 114 and rail 112 snugged down against the tie 100 .
- top surface 122 and bottom surface 124 of the tie 100 are illustrated with a coating 108 .
- the coating 108 is not required.
- the resin selected to form the shell 102 may have a degree of flexibility that dispenses with the benefits or some of the benefits of a coating 108 .
- the top surface 122 may be referred to as the top surface of the tie 100 , as completed with the coating 108 , or absent such.
- the bottom surface 124 may be the surface of the shell 102 , or may be the ultimate surface of the tie 100 after the shell 102 has received a coating 108 .
- the rail 110 is constituted by an upper flange 125 that actually carries the wheel of a rail vehicle (e.g., locomotive, car, etc.) while a lower flange 126 provides a base 126 on the tie 100 .
- a web 127 connects the upper flange 125 to the lower flange 126 .
- the bending loads on the entire rail 112 render the “I” shape of the rail 112 an effective beam.
- the I-beam construction provides for the maximum stiffness at the minimum weight required to support the load.
- section modulus (used here as the term is used in engineering) is the mechanical property of a material that reflects the effect in bending. It reflects the location of the material away from the “neutral axis” near the midway line, as the maximum compression is imposed at one “outermost fiber” while the maximum tension is imposed on the opposite “outermost fiber.” “Outermost” is at the points most distant from the neutral axis.
- a rail car wheel presents a load in compression against the upper flange 125 , putting it into local compression. Meanwhile, the lower flange 126 is placed in tension in response to the tendency of the rail 112 to bend between supporting points, such as adjacent ties 100 .
- section modulus an engineering term defining the exact relationship between the cross-sectional shape and the stiffness of that shape
- section modulus an engineering term defining the exact relationship between the cross-sectional shape and the stiffness of that shape
- the lower corners 130 a , 130 b may actually be sharper corners, or more filled in. This will provide more material in tension, and thus stiffen the tie 100 by increasing the section modulus.
- the section modulus is proportional to a power of the distance from the neutral axis to the outermost fiber.
- the overall stiffness is greatly improved by putting a comparatively small proportion of the overall cross-sectional area farther away from the neutral axis, and especially at or near the outmost fiber.
- the upper corners 128 and lower corners 130 need not have the same radius, nor contain the same amount of material.
- FIG. 2 while referring generally to FIGS. 1 through 36 , various cross-sections provide different benefits in a tie 100 in accordance with the invention.
- the tie 100 is shown with a radius at each corner 128 , 130 .
- the tie 100 a is rounded on all corners 128 , 130 , as is the tie 100 e and the tie 100 f .
- the ties 100 b , 100 c , 100 d have a comparatively sharp lower corner 130 on each side with the radiused corners 128 a , 128 b on top.
- the ties 100 a , 100 b are “bare” so to speak, having no coating 108 .
- the tie 100 c is fully coated about its outer surface 122 while the tie 100 d has a coating layer 108 a on the top and a coating layer 108 b on the bottom.
- the tie 100 e has a coating 108 a on top with a coating layer 108 b on the bottom, whereas the tie 100 f is fully coated about its outer surface 122 .
- the coating 108 a may provide for protection against weathering from sun, rain, or chemical environments, as well as providing for resistance to chafing, stress concentrations (stress risers), or the like from loading by the plate 114 against the tie 100 .
- each of the layers 108 b or the portion 108 b of the coating 108 about a tie 100 provides protection against stress concentrations, chafing, weathering, and other factors.
- a suitable thickness of a coating 108 b with the engineered properties of toughness, spring constant or elastic modulus, durometer value of hardness, texture variation along the surface thereof, and the like may be engineered to promote stress distribution of loads of underlying ballast rock against the bottom surface 124 .
- the material properties of the coating 108 b should be engineered to provide a coefficient of friction against the underlying ballast rock of the railroad bed to provide for lateral support of the railway, meaning resistance to axial motion by the tie 100 in its axial direction, which is laterally orthogonal to the travel direction of the rails 112 of a railroad system.
- the fiber reinforced composite that constitutes the shell 102 may include one or more mats or the like.
- a fiber reinforcement 131 or mat 131 may be constituted by a continuous filament mat 132 (CFM 132 ).
- This type of a mat 132 is manufactured by spinning out a continuous filament 133 (or actually many filaments 133 ) that are permitted, actually encouraged, to lie flat on a manufacturing surface. Typically, these many filaments run continuously, thus forming the continuous filament or filaments 133 of the mat 132 .
- the various filaments 133 are included into a mat of stable dimensions.
- the mat 132 thus becomes a non-woven fabric of sorts.
- the mat 132 has a thickness that may be selected in manufacturing to be of any desired amount.
- the dimensions of such a mat 132 may also be selected for length and width according to the desired shape into which it will be molded.
- the filaments 133 overlap one another, cross one another, and otherwise provide a random layout of fibers extending without break.
- the mat 132 must be folded, deflected, formed, and so forth while maintaining its integrity, in order to form a particular shape.
- Such geometries as cylinders, rectangular tubing, and the like, may thus be formed by overlapping the edges of the mat 132 .
- the mat 132 may be a continuous mat fed from a roll, into a molding system in order to form a fiber reinforced composite material of a particular shape.
- a reinforcement mat 131 may be configured as a quadraxial layup in which the principal axes of zero degrees, 90 degrees, 45 degrees, and ⁇ 45 degrees are all laid up in a single mat 131 , constituting the quadraxial non-crimp fabric 140 or fabric mat 140 .
- Longitudinal fibers 134 may be alternated with diagonal fibers 135 at 45 degrees, and followed by other orthogonal fibers 136 in a lateral direction. Thus, the longitudinal fibers 134 lie at 90 degrees with respect to the lateral fibers 136 and vice versa.
- diagonal fibers 135 at 45 degrees are juxtaposed to other diagonal fibers 137 at ⁇ 45 degrees.
- the diagonal fibers 135 , 137 are juxtaposed at 90 degrees to one another.
- stitching 138 of a suitable fiber and suitable size may bind the various layers 134 , 135 , 136 , 137 together in the quadraxial non-crimp fabric (NCF) 140 .
- a pultrusion process may occur in a pultrusion apparatus 142 .
- rovings 141 of any particular form may be constituted by fibers, such as bundles of fiberglass.
- a roving 141 is typically not woven, but rather simply constituted by an untied bundle of fibers all progressing in approximately the same direction. Some amount of twist may exist, but it is not maintained by a tight twisting such as in a rope, nor necessarily any other ties between fibers.
- a roving 141 of fiber may be in any form.
- the roving 141 may actually be a mat 131 .
- the roving 141 may be a layup of multiple mats 131 , constituted by both CFM mats 132 and NCF mats 140 .
- the thicknesses of the mats 132 , 140 may be of any suitable size.
- a layer of the fabric mat 140 may be on each side or each surface of a non woven, CFM mat 132 .
- Rovings 141 may be controlled and directed by guides 143 to orient the rovings 141 to pass into a molding system 144 .
- the molding system 144 is a pultrusion system 142 that draws the rovings 141 or the roving 141 into the die, while pumps and presses drive the polymer matrix into the same die.
- the fiber reinforcement mats 132 , 140 pass through the molding system 144 , they are completely soaked through with the resin matrix selected and exposed to curing conditions, such as the addition of heat.
- the pultrusion system 142 may include a post processing system 146 for one or several purposes.
- a post processing system 146 may include curing heat, cooling air or cooling liquids, cooled extension of the die cross-section, or the like.
- the post processing system 146 must discharge to a pulling system 148 a blank 150 or a tie blank 150 .
- the blank 150 is a tie 100 of substantially infinite length. That is, the system 142 may operate continuously.
- the pulling system 148 may include two, three, or four rollers 152 that grip the blank 150 between them. Rotating on or with shafts 154 , driven by motors, not shown, the rollers 152 grip against the surfaces of the blank 150 , drawing it out of the molding system 144 .
- Tremendous forces may be involved on the orders of hundreds or thousands of pounds. High pressures (tens of thousands of Psi), high velocities, large pull forces (e.g., tons), and the like may occur.
- drawing the rovings 141 is actually done by virtue of the continuous fibers of the mats 132 , 140 .
- the system 142 is started up by drawing the rovings 141 completely through the system 152 with no resin. Thus, they may more easily fit through the die, and be grasped by suitable machinery or by hand downstream from the pulling system 148 .
- the rovings 141 can be initially drawn, resin can be added through the molding process and the molding system 144 . Eventually, after cure and sufficient cooling to maintain proper strength, the blank 150 may exit the molding system 144 .
- the post processing system 146 acting on the blank 150 as a solid that can then be manipulated mechanically by the pulling system 148 , may provide a continuous production of the cross-section established by the dies in the molding system 144 .
- a station for cutting the blanks 150 to a standard length will be necessary, because the pultrusion process of the system 142 , as illustrated, is a continuous process, not a batch process.
- a tie 100 is illustrated in cross-section, taken axially with respect to the rail, and in a transverse plane of the tie 100 , parallel to the longitudinal direction of the tie, but also looking orthogonally thereto across the lateral width of the tie 100 .
- the tie 100 may have any suitable height, illustrated by the illustrated break in the continuity of the fill 104 .
- the fill 104 may be injected into the inner cavity 156 of the tie 100 .
- the inner cavity 156 becomes the fill region 104 after completion.
- the fill 104 may be concrete, lightweight concrete containing particles of an expanded polymer, special compounds of rubber, other elastomers, recycled crumb rubber bonded together by binders, expanded foams (expanded polymers) such as polyurethane resin (PUR), or the like.
- expanded polymers expanded polymers
- PUR polyurethane resin
- the rail 112 is seated on top of a plate 114 , which plate 114 sits on the top of the surface 122 of the tie 100 .
- the keeper 116 grips the bottom flange 126 of the rail 112 .
- the keeper 116 is secured to the tie 100 by a fastener 120 .
- the fastener 120 may have a point 158 at the distal end of a shaft 160 or shank 160 of the fastener 120 .
- the head 162 may be sized to support hammering or other driving of the fastener 120 into the fill 104 inside the tie 100 .
- an aperture 164 in the tie 100 is sized to receive the shank 160 of the fastener 120 with a certain amount of interference.
- the aperture 164 need not be provided in the fill 104 .
- a fastener 120 such as a lag screw or a common railroad spike 120 may be driven into the fill 104 , which provides resistance, grip, and securement of the shank 160 therein.
- a pilot hole 164 or aperture 164 may be sized to provide an interference fit in which the shank 160 compresses away from itself the fill material 104 .
- the fastener 120 may be made of a similar material, such as steel, reinforced polymer, or the like as the keeper 116 . Accordingly, it would not be proper for the fastener 120 to be responsible to pierce by its point 158 the keeper 116 material. Rather, an aperture 166 in the keeper 116 may be fabricated therein or drilled after fabrication in order to provide easy access. Meanwhile, it is advisable that the aperture 164 at least pass through the shell 102 (the top wall 106 a ) in order to not fracture the material thereof. In the illustrated embodiment, an aperture 167 in the plate 114 is aligned and consistent with the size of the fastener 120 , and the size of the aperture 166 , and the keeper 116 .
- the aperture 164 may have an upper region 165 or an aperture 165 that provides complete clearance with no interference for the shank 160 of the fastener 120 .
- the upper aperture 165 will typically be larger than the aperture 164 within the fill 104 in order to provide clearance for the shank 160 to pass through the upper wall 106 a , quite freely, while providing interference substantial enough to secure the shank 160 within the fill 104 .
- the shank 160 may be threaded. Likewise, the shank 160 may be split and a swaging element 200 (See FIGS. 14 through 16 ) driven through the center of the head 120 and the shank 160 in order to separate the shank 160 into segments 204 that deflect and swell by the presence of the swaging element 200 to increase their “purchase” or grip and holding ability within the fill 104 . As mentioned hereinabove, the aperture 164 may cease with the upper region 165 , requiring that the point 158 and shank 160 penetrate the fill 104 without the assistance of a pilot hole 164 or other interference aperture 164 .
- the support forces of the ballast 168 must support and counteract, in accordance with Newton's laws of physics, the load imposed by a train wheel rolling on the rail 112 supported by the upper wall 106 a .
- a coating 108 b on the lower wall 106 b may be designed to provide more grip by the individual rocks 169 that form the ballast 168 of the railroad bed.
- the coating 108 b may be comparatively softer than the coating 108 a .
- a material that may deform or mold over time, but not respond quickly, may encourage the rocks 169 against the bottom surface 124 to embed into the coating 108 b , thus increasing the effective friction coefficient to a value greater than would otherwise exist between the smooth surfaces of such materials.
- a coefficient of friction operates according to the equation that a force of friction is equal to a coefficient of friction (usually the Greek letter Mu) multiplied by the normal force (force perpendicular) urging the two surfaces of the two materials together. Friction may provide a certain amount of resistance to the sliding in the axial direction of the tie 100 , and thus in the lateral direction of the railroad, by the tie 100 .
- ballast 168 As the ballast 168 settles over time, one may expect the tie 100 to settle into the ballast 168 , also assisting in lateral resistance to motion by the railroad.
- the ballast 168 according to studies on the subject, becomes more resistant to lateral displacement of ties 100 , where lateral is with respect to the railroad direction. Resistance to motion along an end-wise direction for the longitudinal dimension of the tie 100 improves with consolidation of the individual rocks 169 together in the ballast 168 . This suggests that the resistance of the individual rocks 169 to individual motion of one another may have increased. This may also indicate that a tie 100 has settled somewhat deeper into the ballast 168 , thus providing some support for lateral loads on the railroad rails 112 .
- the individual rocks 169 may have engaged more completely the bottom surface 124 of the tie 100 . This may be a matter of individual rocks 169 cutting in or orienting to engage various depressions or concavities that may exist in the bottom surface 124 . Thus, resistance is offered by a combination of friction, direct mechanical engagement by the rocks 169 of the bottom surface 124 , and its various topography, as well as mechanical resistance by the consolidation of individual rocks 169 into the ballast 168 at either end 118 a , 118 b of the tie 100 .
- the fill 104 within a tie 100 is illustrated in a perspective view, and having an aperture 164 prepared therein.
- the aperture 164 may be drilled to extend through the shell 102 and into the fill 104 .
- various types of fasteners 120 may be installed to engage the inner surface of the aperture 164 . Engagement typically may be facilitated by an interference between the outermost dimensions of the fastener 120 and a compressed portion of the fill 104 immediately surrounding the aperture 164 .
- various embodiments are illustrated for the engagement of the fasteners 120 by the apertures 164 .
- a fastener 120 may be configured to have a round shape, threaded shape, barbs, segments that may be divided away from one another along axial cuts or separations, and so forth.
- a fastener 120 may have a head 162 that is configured to receive a driver, such as a hex wrench, a bolt-like head 162 to receive an adjustable wrench or other hexagonal wrench fitting around the exterior thereof, or the like.
- a driver such as a hex wrench, a bolt-like head 162 to receive an adjustable wrench or other hexagonal wrench fitting around the exterior thereof, or the like.
- the profile image of a fastener 120 illustrated includes a point 158 in order to engage the aperture 164 , and possibly cut into the fill material 104 .
- the shank 160 is illustrated generically, and may be threaded, barbed, flat or smooth sided, textured, or otherwise designed to engage the fill 104 surrounding the aperture 164 .
- the head 162 has a top 172 into which a fitting for a wrench is formed into the head 162 .
- the edge 174 of the head 162 may be shaped to fit another type of wrench that engages the exterior surface of the edge 174 .
- An example of this would be a conventional hex head commonly used with end wrenches, socket wrenches, adjustable end wrenches, and so forth.
- square heads have been ubiquitous for centuries.
- the effect of driving the shank 160 of a fastener 120 into an aperture 164 or simply directly into the fill material 104 is to grip the shank 160 in the aperture 164 or the material 104 such that the shoulder 176 of the fastener 120 maintains a compressive force against the keeper 116 . Meanwhile, the keeper 116 maintains in compression the bottom flange 126 of the rail 112 against the plate 114 .
- the function of a fastener 120 is to hold the lower flange 126 of the rail 112 in compression toward the tie 100 .
- this compressive force exerted by the shoulder 176 against the keeper 116 , and of the keeper 116 against the bottom flange 126 is to capture the plate 114 under the bottom flange 126 of the rail 112 , thus maintaining the rail assembly 110 secure against motion in substantially all degrees of freedom (e.g., rail longitudinal direction, rail lateral direction, rail transverse/vertical direction, and any bending or rolling about any of those directions as axes).
- the fasteners 120 a through 120 f are simply alternative embodiments for the engagement by the fasteners 120 with the aperture 164 , fill 104 , or both.
- the fastener 120 a is illustrated in cross-section with the shank 160 as it would appear embedded in the fill 104 immediately surrounding it without any pre formed aperture 164 .
- a spike 120 a having a rectangular cross-section may be driven by force applied to a head 162 in order to drive the shank 160 into the fill material 104 without a pre-drilled aperture 164 .
- the fastener 120 b is similar to the fastener 120 a , having the same type of shank 160 , but having a certain degree of relief provided by an aperture 164 b that is nearly a pilot hole 164 b . That is, the interference between the shank 160 and the aperture 164 b is substantial.
- the shank 160 does not have to drive its own penetration into the fill 104 , because the pilot provides a certain amount of relief. Nevertheless, substantial interference, and therefore substantial pressure on the shank 160 by the surrounding fill 104 may tend to hold the fastener 120 b securely in the fill 104 .
- the fastener 120 c provides less interference between the shank 160 and a substantially larger aperture 164 b .
- the shank 160 must drive, cut, or otherwise displace the amount of fill 104 existing between the profile of the aperture 164 b , and the profile of the shank 160 .
- the fastener 120 d is illustrated with an aperture 164 d that actually has interference near the corners of the shank 160 , and clearance between the flat sides of the shank 160 and the circumference of the aperture 164 d.
- the outermost diameter of the shank 160 is larger than a drilled, circular aperture 164 e .
- This may be a driven shank 160 that is simply driven like a spike 120 .
- the shank 160 may be threaded, helical threaded, barbed, separable, or otherwise designed to engage the fill 104 surrounding the initial aperture 164 e .
- the fill material 104 and the aperture 164 in each will eventually conform to the outer surface of each of the respective shanks 160 .
- the illustrated interference is the interference that would exist before the shank 160 is driven into the aperture 164 or the surrounding fill material 104 .
- the interference largely or entirely disappears, as the shank 160 forces the material 104 to move out of the path of the shank 160 .
- the spring force or the elastic force of the fill material 104 provides a frictional, shear, or other engagement of the outer surface of the shank 160 by the material 104 .
- the fastener 120 f illustrates a comparatively small aperture 164 f operating substantially as a pilot, with the shank 160 f driving into the pilot aperture 164 f , with threads 170 engaging by either displacing, cutting, or otherwise penetrating outward radially into the fill material 104 .
- the threads 170 or flutes 170 may compress the fill 104 , or cut into it as the shank 160 drives down into the fill material 104 , piloted by the comparatively smaller aperture 164 f.
- a rail tie 100 may have a distance or length of the tie 100 extending outwardly beyond the rails mounted thereon. That is, historically, ballast 168 supports a tie 100 , and the tie 100 then supports two rails 112 or more running across or laterally across the ties 100 . Thus, the ties 100 may extend substantially beyond the rails 112 in order to provide a spreading of the load represented by the rails 112 against the ties 100 . Thus, fasteners 120 may exist on each side of each rail 112 toward each end 118 a , 118 b of a tie 100 .
- FIG. 8 is illustrated one embodiment of an aperture 164 g and an aperture 164 h .
- the aperture 164 g has not yet received a fastener 120 .
- the aperture 164 h has received a fastener 120 securing a keeper 116 and underlying plate 114 to the tie 100 .
- the apertures 164 g , 164 h represent alternative embodiments.
- an upper aperture 165 represents additional space in which a fastener 120 may pass through the shell 102 without any substantial interference.
- the mechanical properties of the shell 102 are sufficiently stiff, hard, strong, brittle, and so forth, that the upper aperture 165 is not designed to stretch or displace to accommodate the fastener 120 .
- a fastener 120 may be inserted through the upper aperture 165 without substantial resistance, after which interference will exist between a fastener 120 and the main aperture 164 g , as described hereinabove.
- the upper aperture 165 may have a bottom surface that may be tapered, flat, or dictated by the artifacts of whatever type of tool is used to form it.
- the aperture 164 h is a mere pilot hole 164 h providing nearly total interference between the fill material 104 and the inserted fastener 120 .
- the fastener 120 in the aperture 164 h is illustrated also with an upper aperture 165 terminating in a taper.
- shank 160 of that fastener 120 may be of any type, including rectangular, circular, or other shape in cross-section, such as a star, triangle, or any other suitable shape.
- shank 160 may also include threads, flutes, barbs, straight sides, textured sides, or the like in order to facilitate engagement by the shank 160 of the material 104 or fill 104 surrounding it.
- fasteners 120 are illustrated with their various shanks 160 .
- Various configurations of apertures 164 , and upper apertures 165 are illustrated.
- a fastener 120 may be passed through an upper aperture 165 formed in the shell 102 , and possibly, not necessarily, extending some distance into the fill 104 .
- the fastener 120 engages with threads 170 or other artifacts (features, shapes) on the shank 160 , the outer walls 179 of the respective apertures 164 .
- the upper aperture 165 is substantially circular in cross-section, thus forming a right circular cylinder, but terminates with a taper such as may result from the point of a drill bit. Meanwhile, the upper aperture 165 of FIG. 10 provides a flat shoulder or milled bottom surface of the upper aperture 165 . Meanwhile, the upper aperture 165 of FIG. 11 illustrates a countersink. Any of the apertures 164 providing any degree of interference with a shank 160 of a fastener 120 may use any appropriate upper aperture 164 deemed appropriate to accommodate the shank 160 , a head 162 , or the like.
- the threads 170 may be very comparatively short pitched, that is, the threads 170 are close together as a conventional screw. In other embodiments, the pitch may be extremely long including a single rotation or revolution or less of one thread 170 between the head 162 and the point 158 . Thus, as a twist nail, each of the helical threads 170 may simply curve or rotate some minimum number of turns or a fraction of a turn in order to support driving thereof into the aperture 164 .
- various embodiments of fasteners 120 may engage the apertures 164 in the ties 100 in accordance with the invention.
- a spike of FIG. 12 may be driven by placing the point 158 into the upper aperture 165 of any particular tie 100 and driven by pounding the head 162 .
- the axial movement of the shank 160 causes engagement of the outer surface 179 or outer wall 179 of the aperture 164 by the surfaces 178 .
- edge 174 of a driven spike 120 of FIG. 12 need only have sufficient thickness to provide a stable shoulder 176 for securing the keeper 116 to the tie 100 .
- a hammer or other driver may simply provide an impact load on the top 172 or upper surface 172 of the head 162 , singly or repeatedly, in order to drive the point 158 and shank 160 deeply into the fill 104 .
- FIG. 13 on a threaded fastener 120 the threads 170 are shown in cross-section.
- the hidden lines illustrate threads 170 on the back side of the fastener 120 .
- a head 162 shows one embodiment of a hexagonal recess 190 for receiving a male hex wrench.
- the point 158 is augmented by a tap 180 in order to render the fastener 120 a self-tapping device 120 .
- the tap 180 may include a drilling edge 182 or drill edge 182 that cuts as it passes into the fill 104 .
- a thread cutter 184 is formed by the relief 186 or relief region 186 cut into the distal end of the fastener 120 .
- 90 degrees of arc may be removed from near the point 158 of the fastener 120 . Leaving sharp edges on threads 170 , renders them cutters 184 .
- This self-tapping mechanism may assure that the shank 160 cuts into the fill 104 , rather than simply pushing or displacing it outward, to engage the threads 170 .
- each thread 170 may be thought of as the outermost point or extent of the diameter of the shank 160 .
- the broken lines illustrate the hidden crest 188 of the threads as they pass around the back surface of the fastener 120 illustrated in cross-section here.
- a fastener 120 may act as a something of a rivet.
- the shank 160 may include a surface 178 that is smooth, illustrated on the left side of the embodiment.
- Barbs 194 are illustrated on the right side thereof.
- the barbs 194 may be individual elements that extend or project away from the surface 178 . Alternatively, they may pass completely and continuously around the circumference of the shank 160 . They may appear like threads, completely circumnavigating the shank 160 , but not progressing helically. Barbs 194 do not progress with rotation of the fastener 120 . They progress by driving of the fastener 120 and shank 160 into the tie 100 .
- the fastener 120 is provided with a channel 196 down its center.
- the shank 160 is divided into at least two, and preferably three or even four segments about its circumference.
- the channel 196 may be formed as a slot passing straight through from side to side in one, two, or more directions.
- the channel 196 may be cut at 120 degree angles about the circumference of the shank 160 , in order to render the shank 160 a rivet when the segments are separated.
- the effect of the fastener 120 in service is to be driven by pounding, rotation, or both into an aperture 164 in a tie 100 .
- a shaft 198 formed as part of a swage 200 or spreader 200 may be driven into the channel 196 after the shank 160 is fully engaged and fully penetrated into the tie 100 .
- the swage 200 may be placed into the channel 196 after the shank 160 has been driven into the tie 100 , or before.
- the head 162 may be rotated to thread the shank 160 into the aperture 164 .
- the swage 200 may be placed in the channel 196 after the head 162 has already been pounded to drive the shank 160 into the tie 100 .
- the head 202 of the swage 200 is hammered or otherwise driven in order to force the shaft 198 down the channel 196 with an interference fit.
- the interference causes the shaft 198 to spread the channel 196 , thus opening up segmented portions 204 a , 204 b (segments 204 ) into which the shank 160 is already divided (e.g., 2, 3, 4, etc.).
- the constriction 206 or shoulder 206 may be placed at an appropriate location along the length of the shank 160 to engage by interference the shaft 198 .
- the result is swaging the segments 204 outward in an expansion 208 or expansion direction 208 also asserting a force 208 and motion 208 on the segments.
- a peculiar benefit of the fastener 120 is that spreading 208 the segments 204 compresses the fill 204 between the segments 204 and the shell 102 .
- the shell 102 now may assist more directly to retain the fastener 120 , and thus provide a more affirmative engagement and securement of the keeper 116 and support plate 114 along with the rail 112 supported thereby.
- the amount of interference between the shaft 198 of the swage 200 and the channel 196 may be selected, and may vary at any specific rate.
- the shank 198 may have a degree of taper.
- the shape of the channel may also have some degree of taper providing a greater or lesser expansion 208 of the segments 204 and a higher or lower initiation of the spreading 208 thereof along the length of the shank 160 .
- yet another alternative embodiment of a fastener 120 may rely on a head 162 adapted to the use of a driver, wrench, hammer, impact device, or the like.
- the device may likewise have threads 170 and segments 204 a , 204 b representing either two, three, four, or the like segments 204 divided by a channel 196 into which is received a swage 200 .
- the channel 196 near the head 162 is sufficiently wide to receive the head 202 of the swage 200 , while the shaft 198 thereof penetrates gradually into the channel 198 , thus spreading apart the segments 204 from one another.
- threads 170 are illustrated schematically and in broken lines inasmuch as they would be on the opposite side from the viewer of this cross-sectional view of a fastener 120 .
- a side elevation view of the fastener 120 illustrates an alternative embodiment of a head 162 having flats 210 or surfaces 210 shaped to receive a wrench thereon.
- threads 170 or flutes 170 around the shank 160 render it a screw, lag screw, bolt, or the like.
- Any fastener 120 may have a shank 160 designed according to any of the embodiments illustrated herein, and a head 162 appropriate thereto for engaging the tooling or tool that will drive the fastener 120 into the fill 104 of a tie 100 .
- the use of a pilot aperture 164 or other interference-based aperture 164 may assure securement of the shank 160 in the fill 104 .
- the chemistry of the fill 104 or the structure may also be altered.
- an oversized aperture 164 may be drilled or otherwise formed through the shell 102 and into the fill 104 . Thereafter, a stiffer, stronger, or otherwise modified material may be infused into the aperture 164 . This provides better distribution of forces into the fill 104 , and better support against pull-out by the fastener 120 .
- the aperture 164 may be drilled well over size and filled with a suitable holding material, which serves as a modified filler 104 . Thereafter, a second aperture 164 is drilled for receiving and holding the shank 160 of any particular embodiment of a fastener 120 .
- a tie 100 comprising a shell 102 containing fill 104 within the cavity 103 thereof was arranged with a plate 114 thereupon.
- FIG. 19 a cross-sectional view of the tie 100 is illustrated.
- the height was about seven inches and the width was nine inches.
- Various radii for the corners 128 were posited. It was found that in order to support a conventional plate 114 , the radius of 0.625 inches (two centimeters) was necessary in order to provide full support beneath the plate 114 on the upper wall 106 a of the shell 102 .
- section modulus an engineering term used here in as per the engineering definition thereof
- section modulus relating the cross-sectional area to the stiffness thereof
- the values 212 a , 214 a , 216 a represent values corresponding to various constructions of the mat 131 or reinforcement 131 used in a shell 102 in accordance with the invention.
- the values 212 represent values corresponding to continuous fiber mat 132 .
- the values 214 refer to the layered quadraxial non-crimp fabric mat 140 .
- Each of these values 212 , 214 , 216 corresponds to a particular variable 220 .
- the variable 220 a is the unidirectional modulus 220 a along each of the principal axis of stress.
- the Poisson ratio 220 b is also identified.
- the shear modulus 220 c along each principal axis is similarly identified.
- the chart or table illustrates variables 212 , 214 , 216 corresponding to the variables 220 identified in the table.
- listed in the table of FIG. 21 are the tensile strength in the longitudinal direction, and compressive strength in the same direction.
- the longitudinal direction 101 a , the lateral direction 101 b , and the transverse (e.g., nominally vertical) direction 101 c are illustrated in FIG. 1 with respect with the tie 100 .
- transverse tensile strength, transverse compressive strength as well as the through-thickness tensile strength and through-thickness compressive strength are illustrated.
- the values 212 correspond to the continuous fiber mat.
- the values 214 correspond to those of the quadraxial non-crimp fabric mat 140 .
- the properties 216 represent a value 216 for a hybrid relying on both the continuous fiber mat 131 , and the woven or NCF mat 140 .
- the stiffness and strength properties of a polyurethane resin foam or expanded polyurethane resin at various values 222 of density are illustrated.
- the variables 220 are identified as variables 220 d through 220 h .
- the modulus of elasticity 220 d the tensile stress 220 e , the compressive stress 220 f , the shear modulus 220 g , and the shear strength 220 h are all illustrated at various values 222 .
- Those values 222 correspond to the variable 224 of density 224 .
- the values 226 of various densities 224 in pounds per cubic foot of the expanded polyurethane resin (PUR foam), illustrate the change in elastic modulus 220 d , tensile strength 220 e , compressive strength 220 f , shear modulus 220 g , and shear strength 220 h with changes in density.
- This data illustrates the significance of density as it affects the mechanical properties of the fill 104 .
- the bulk of the fill 104 may be a material having one density. Inserts of a more dense material ay be placed into oversized apertures 164 . This will facilitate better pull-out strength for the fasteners 120 as described hereinabove.
- the test configuration contained a rail 112 mounted against a plate 114 , resting on a tie 100 .
- the tie 100 relied on symmetry, having the tie 100 and the plate 114 centered along the length thereof, which was not full length for tie 100 in service. Rather, a segment of a tie 100 supported on a test fixture 228 provided a model of the tie portion under a single rail 112 .
- the fixture 228 may be analogized to the ballast 168 of a road bed on which a rail tie 100 is supported along its length. Meanwhile, a force 230 was applied vertically to the rail 112 , and transferred by the rail 112 into the plate 114 , which in turn applied the load 230 to the tie 100 .
- the tie plate 114 was centered such that the distances 232 from the ends of the model tie 100 were equal.
- the plate 114 had a length of about 14 inches (35 centimeters).
- the plate 114 and tie 100 were subdivided into a mesh 234 of individual elements 236 for analysis.
- the elements 236 represented the structural constituents as understood in the art of structural analysis for the finite element method (FEM) or the finite element analysis (FEA) as those terms are understood in the art of structural engineering analysis.
- the stress distribution throughout the tie 100 is illustrated as the sections 236 a through 236 e of various colors.
- the regions 238 and 240 in contrast represented considerably less stress.
- the directions 101 a , 101 b , and 101 c illustrate the longitudinal, lateral, and transverse directions 101 , respectively.
- the maximum elastic deformation at 100,000 pounds force needed to be no more than one quarter inch.
- the data illustrate the maximum limit 236 a on deformation 236 along with the actual elastic deformation as a function of the density 224 of the expanded polyurethane resin.
- the various charts corresponding to the maximum deformation 236 a permissible, the deformation 236 b corresponding to the continuous fiber mat 131 are illustrated as falling much closer together than similarly situated some distance away from the maximum permissible 236 a .
- the hybrid chart or curve 236 c is virtually coincident with the other curves 236 b , 236 d .
- the fabric or NCF curve 236 d is slightly lower in elastic deformation than is the hybrid curve 236 c . Both of these are lower in elastic deformation 236 than is the curve 236 b of the continuous fiber mat 131 .
- the overall elastic deformation 236 is on the order of 0.06 maximum value 236 for all the configurations. This is well within the permissible 0.25 deformation in inches.
- the chart 238 illustrates values of shell thickness or thickness of the walls 106 of the shell 102 plotted against the density 224 of the expanded polyurethane of the fill 104 .
- each of the curves 240 a , 240 b , 240 c shows additional decrease in required shell thickness, between the curve 240 a representing the continuous fiber mat 132 , the fabric or NCF mat 140 , with the curve 240 c , and a hybrid thereof illustrated by the curve 240 b .
- the shell thickness requirement decreases as the density 224 of the expanded polyurethane resin increases.
- the chart 242 illustrates values for the modulus of elasticity 244 plotted against the density 224 of the expanded polyurethane resin.
- a minimum permissible 244 a is identified and up to about a density of about 20 pounds per cubic foot of the PUR, the moduli of elasticity 244 all exceed the minimum permissible 244 a by a substantial margin.
- the value of the modulus of elasticity 244 b for the continuous fiber mat 132 is seen to have the lowest value while the value for the modulus of elasticity 244 c for the hybrid is intermediate that for the CFM curve 244 b , and the modulus 244 d or curve 244 d corresponding to the straight NCF mat 140 .
- a chart 246 illustrates values of density 224 of the expanded polyurethane resin or PUR foam in pounds per cubic foot, against the modulus of rupture 248 on the vertical axis.
- Each of the curves 248 a through 248 d illustrate the respective performances of the tie 100 having a shell 102 of the material identified in chart 246 .
- the curve 248 b corresponding to the continuous fiber mat 132 performs the most poorly, although well sufficient up to a PUR density of about 20.
- the curve 248 b corresponds to the non woven continuous fiber mat 132
- the intermediate curve 248 c illustrates that a hybrid performs intermediate the behavior of the NCF fabric curve 248 d and the CFM curve 248 b .
- the higher the density of the PUR foam the lower the modulus of rupture 248 .
- Overall the modulus of rupture is not considered a critical parameter in any case even for the lowest values of shell thickness for heavy foam density in the range of about 45 pounds per cubic foot the modulus 248 is typically higher than minimum required.
- the chart 250 illustrates values of weight 252 along the vertical axis against the density 224 along the horizontal axis.
- the curves 252 b illustrates the CFM mat 132
- the curve 252 d corresponds to the fabric 140 .
- the curve 252 c is for they hybrid.
- the bottom wall 106 b may be absent. It has been found that the deflection, strength, stiffness, and other mechanical properties of a tie 100 in accordance with the invention may operate satisfactorily without requiring the bottom wall 106 b . Accordingly, in this illustrated embodiment, the shell 102 includes the sidewalls 106 c and the contiguous and continuous, typically uniformly molded or simultaneously molded (pultruded) top wall 106 a . All are continuous, contiguous, and maybe effectively homogenous. That is, the same material, even though a fiber-reinforced composite. Therefore, the tie 100 is fabricated by manufacturing a shell 102 including pultrusion of all of the walls 106 a , 106 b simultaneously.
- the integrity of the tie 100 is satisfactory, but deflection may be excessive at the comparatively thin dimension of the top wall 106 a required for strength. Accordingly, stiffness benefits may accrue by increasing the depth or thickness and thus the “section modulus” of that top wall 106 a . Accordingly, it has been found that the pultrusion of the shell 102 may include additional composite materials incorporated therein.
- pultrusion shares another characteristic with extrusion, unique to these processes.
- pultrusion and extrusion provide a continuous process in which the die continues to receive and discharge input materials and output product, respectively. This necessitates to a certain extent a requirement that the cross section of a pultruded or extruded part typically remain substantially constant. It need not be uniform throughout, but changes in the locations, densities, materials, and so forth are very difficult to make, yielding large unpredictability in a continuous pultrusion or extrusion process.
- cross section will typically be constant (from a constant die cross section) along the length of an extrusion or pultrusion. It may still vary along its width, across its thickness, or the like.
- the side walls 106 c appear in testing to have sufficient stiffness in all applicable dimensions and sufficient strength. In all applicable dimensions, they serve at comparatively modest thicknesses shown herein. They are engineered and calculated to support the stresses, strains, forces, deflections, and so forth required for rail ties 100 . Thus, whether or not to maintain a uniform thickness across the top wall 106 a and the associated contiguous side walls 106 c is optional. Thus, manufacturing convenience may be the criterion by which a determination is made.
- the pultrusion process may embed different or disparate fillers. They may be distributed among the polymer matrix that cures to form the shell 102 . They may bulk out the reinforcement members such as fabric 140 , roving 141 or other fibers 133 , such as a continuous fiber mat 132 . Thus, in general, any mat 132 , continuous fiber mat 132 , other fibers 133 , fabric 140 or rovings 141 may be formed with, or inserted around other spacing fillers that do not share the mechanical properties of such reinforcements.
- long strands of filaments or other configurations of lighter polymers may fill in between the reinforcement fibers in the matrix of the upper wall 106 a or other portions of the shell 102 .
- another layer (filler) containing sparse amounts of reinforcement fibers and matrix polymer may constitute the majority of the bulk. It may be the literally over half the bulk, and often is many times more than the quantity of reinforcement matrix, devoted to the spacing material.
- EPS expanded polystyrene
- StyrofoamTM materials
- other materials such as polyurethanes, natural fibers, other lightweight synthetic materials, and the like may fit within the thickness of the top wall 106 a of the shell 102 .
- mats 131 , 132 , 140 , or the like, alone or in combination may be formed into both the upper and lower surfaces of the top wall 106 a.
- top wall 106 a therebetween, or therewithin, may be distributed some smaller quantity of reinforcing fibers and the matrix polymer, interspersed with comparatively larger quantities of lightweight, low strength materials.
- the function of these spacing materials is simply the spacing apart of the reinforcement and matrix materials in the top wall 106 a in order to increase the section modulus thereof.
- the strength of the top wall 106 a may be calculated, engineered, and constructed so its stiffness suffices.
- additional stiffness is added by increasing the individual section modulus of the shell 102 , especially, or particularly, in the top wall 106 a.
- the stiffness of the wall 106 a is greatly increased without substantially increasing overall weight, and without substantially increasing material. In fact, the stiffness of the wall 106 a may be greatly increased with virtually no increase in weight or basic reinforcement and matrix materials. Rather, comparatively lower cost, lower weight, lower strength filler materials may separate upper and lower layers of the top wall 106 a , greatly increasing stiffness. In fact, even axial strength along the length of the tie 100 need not be increased in such a configuration.
- FIG. 31 illustrate on the left a conventional extrusion.
- a fiber reinforced matrix 254 or a typical composite is made up of reinforcement fibers in a polymeric matrix. This forms one layer.
- An alternative fiber-reinforced matrix layer 256 may also be adjacent thereto, interleaved therewith, or the like.
- any of the mats 131 , CFM's 132 , fabric 140 , or roving 141 may be laid up in some particular order or arrangement to form a top wall 106 a .
- the wall 106 a captures and preferably adheres to the fill material 104 captured therewithin or captured by the shell 102 .
- the inset on the right shows an alternative embodiment.
- different layers 254 , 256 , or fields 254 , 256 of fiber reinforcement are in a polymer matrix 254 , 256 . They have bound or sandwiched between them a comparatively lighter weight layer 262 .
- That layer 262 may include a rather sparse, fiber-reinforcement-filled polymeric matrix 258 as the structural constituent, surrounding a comparatively lighter weight, lower strength, more bulky spacer material 260 .
- the fill material 260 may be fed as strands, comparatively bulky compared to the reinforcement fibers in roving 141 , fabric 140 , or other mats 131 , 132 .
- the fill material 260 may be secured against pressing through or migrating outward within the upper wall 106 a during fabrication, through free rovings 141 or free fibers of rovings 141 .
- the fill material 104 inside the tie 100 may also have adhesive properties that bond. These provide stress support or bond pull strength and shear strength at sufficient tenacity to provide the stress support. They assure that the fill material 104 cannot separate from any wall 106 of the shell 102 . Thus, whether reactive, to bond chemically, filled into a textured surface of the walls 106 in order to provide a mechanical connection, or otherwise, it has been found preferable to render the fill material 104 adherent to the walls 106 of the shell 102 in order to maintain integrity and best mechanical properties.
- a rail tie 100 may include various optional cross sections or stack ups of materials.
- the walls 106 or the shell 102 may be open such that no lower wall 106 b is used.
- a cross section of the walls 106 may be constructed in any of the forms discussed hereinabove.
- a top coating 122 is added. This may assist in resisting chafing of the reinforcement fibers embedded in the matrix of the top wall 106 a of the shell 102 .
- the third clockwise cross section adds a full coating 108 , including coating on the upper wall 106 a as well as a coating layer 108 b on the bottom surface 124 . Meanwhile, the coating 108 a covers all the walls 106 .
- a lower coating layer 108 b sits juxtaposed to an upper coating 108 a .
- the coatings 108 are not entire, yet can protect against damage from ballast rock against the surface 124 , and against chafing of the rails 112 , and their attachment plates 114 against the upper surface or upper wall 106 a.
- the fifth cross section is trapezoidal in shape. It may have any suitable angle 264 .
- the angle 264 is not required necessarily for draft. Extrusion and pultrusion can produce products where draft is replaced with force. However, this angle 264 may provide for a more stable base. It may also provide an indication of what surface is to go against the ballast and which is to fit against the rail assembly 110 , or the like.
- the coating 108 is continuous from the upper coating 108 a all the way around the side walls 106 c to the bottom coating 108 b.
- an inverse angle 264 results in an effective capture of the fill material 104 between the side walls 106 c and the top wall 106 a .
- the fill material 104 is pressed against the upper wall 106 a by the constraining side walls 106 c in response to any bending moment on the rail tie 100 .
- any of the illustrated cross sections may have a coating 108 on the top, on the bottom, all the way around the outer periphery, or the like.
- Coatings 108 may be filled or unfilled elastomeric polymers.
- reinforcement fibers may be very much more stiff more akin to properties of conventional fiberglass and its composites. It is consequently more brittle. Its fibers are more easily broken individually by impact, chafing, sharp objects, and so forth.
- the materials of the matrix material 266 compared to the embedded fiber material 268 may be any suitable structural polymer.
- Various thermoplastics may be used, but thermosets are usually stronger and more stable, thus better.
- a thermoplastic melts and remelts in response to elevated temperature. It is largely unchanged with remelting. Some degradation may occur, but the material properties and the ability to be remelted to not change dramatically.
- thermoset is a reactive chemical mixture (e.g., like epoxy) in which the initial resins (monomers or mers) react, further polymerize, cross link, or both, resulting in a much stronger and stiffer solid.
- a thermoset polymer matrix upon reheating, will not melt or reverse its condition or state. Rather, it may be destroyed to the point of carbonization in its entirety, yet will typically still remain as an integral, monolithic solid. Its strength may be burned out of it by thermal degradation as it is reduced to a carbon matrix, but it does not melt or reconstitute to its original constituents.
- glass fibers, polyester fibers, carbon fibers, and other fiber or stranded material having a comparatively higher maximum tensile strength (stress) may be embedded in a polymeric matrix having a comparatively lesser (maximum) tensile strength (stress).
- the filler 104 need have even much less tensile strength than any of the foregoing.
- the fill material 104 may be a mixture such as recycled crumb rubber chopped up and embedded within a polyurethane foam.
- the fill material 104 may be a mixture such as recycled crumb rubber chopped up and embedded within a polyurethane foam.
- recycled crumb rubber (RCM), sand, organic natural materials, sawdust, etc. are comparatively inexpensive.
- Polyurethane foam is comparatively more expensive.
- any polymeric matrix 266 is comparatively more expensive.
- the reinforcing fibers 268 are typically used because they are both less expensive than the matrix 266 or polymer 266 , while also having better structural strength along their length. Meanwhile, their compressive and tensile strength between fibers 268 is dictated strictly by the matrix 266 itself (unless fibers cross), which provides all the compressive and tensile support laterally with respect to the longitudinal direction of fibers 268 .
- the fill 104 may be any of the foregoing fill materials, as discussed. Any of these may be an expanded polymer, beads, bubbles, or the like having an engineered fraction of gas or gaps. This type of light, weak, space-filling additive reduces weight without substantially decreasing strength or stiffness modulus (section modulus as understood in engineering) of the polymeric matrix around it. In addition, other fillers enforcing a specific size of gaps (gas, cell, etc.) may also be included.
- Particles of expanded polymers such as polystyrene will reduce the weight of concrete. It also provides additional toughness against fracture. Point loads, sharp impacts, and the like will often fracture conventional concrete.
- Expanded polystyrene (EPS) pellets may be formed of any suitable size. They are commonly available in sizes below one eighth inch diameter. These may be mixed into polymer matrices such as polyurethane thermoplastics, epoxy, other thermosets, or the like to reduce density and increase the gaps in the structural material. Polystyrene foam (EPS) may be mixed in so long as temperatures or processing do not melt it or otherwise destroy its effectiveness.
- EPS Expanded polystyrene
- Microspheres are available from various suppliers and in a variety of materials. Some are simply “bubbles” of air captured in hollow, glass spheres. Others are hollow polymeric (plastic) spheres.
- Minnesota Mining and Manufacturing Company also known under the trademark of 3MTM is one supplier of glass bubbles.
- This company provides numerous manufacturing designations for glass bubbles of type K and type S.
- the majority of the material is a soda lime borosilicate glass. This constitutes the vast majority of its mass with a small percentage remaining of a synthetic, amorphous, crystalline-free silica.
- the material is effectively a hollow glass bead or a hollow glass bubble.
- the shape is basically a hollow sphere having a comparatively thin wall.
- a specific gravity of the beads is on the order of about 0.1 to about 0.6. Since specific gravity is compared with respect to water at standard temperature and pressure, this gives a density of from about 0.1 to about 0.6 grams per cubic centimeter.
- the material is sufficiently fine that it may appear as a powder. That is, with a diameter of less than 100 microns, the beads look like a small or finely divided material. This may be considered a powder, although not necessarily the irregular or plate-like shape of a talc or other powders.
- Processing may be by typical pultrusion, extrusion, injection, and other molding processes.
- the nature of the glass bubbles is such that they may be fractured if processed overly aggressively.
- very aggressive, high-shear stress in vigorously mixed environments may damage them.
- point contact shear such as is found in gear pumps, certain types of roll mills, and the like may be problematic.
- excessive processing in screw extruders may necessitate careful and late placement of the glass bubbles in the flow.
- Properties include a comparatively high cross strength of about 18,000 pounds per square inch (psi).
- the average diameter may be about 30 microns, with a specific gravity of about 0.6, corresponding to about 0.6 grams per cubic centimeter, since specific gravity is simply a comparison with the density of water.
- the temperature in which such glass bubbles melt or begin to soften is typically greater than 600 degrees centigrade. Meanwhile, less than one percent of volatiles exist.
- the glass material is not soluble, and therefor integrates well with virtually any polymer as the matrix in which such glass bubbles may be used as a fill.
- such glass bubbles are sold under the designation S60HS glass bubbles from the 3MTM company of Minneapolis, Minn. USA.
- micro bubbles or microspheres are sold under the trademark SphericelTM. These typically have a density range of from about 0.14 to about 0.8 grams per cubic centimeter. They are used to add to various types of coatings, structural materials, sealants, putties, adhesives, and so forth. Although useful in thermal plastic molding, these have some of the same limitations as glass spheres. Moreover, their melting temperatures are much below the softening temperature of glass.
- plastic microspheres may include a blowing agent or expansion agent within an unexpanded microsphere.
- an encapsulated gas or other expansion agent will react to heat.
- the volume of a microsphere of plastic may actually expand up to about 40 times its initial volume, or even more.
- these microspheres may be added to polymers during processing, and experience their expansion during the heat of processing. Meanwhile, in operation, they provide stable expansion or stable fill having a substantially reduced density (as a gas or air) compared to the remainder of the matrix in which they serve as fill.
- the net effect is substantial reductions in weight with improved performance in receiving and holding a spike.
- Space into which a spike can deflect or direct the matrix material is a valuable aid to entry and securement.
- the result includes a reduction in cost in accordance with reductions in weight of the base matrix, and an ability to design a tie 10 suitable for the specification of the individual customer or purchaser.
- the use of lightweight fill materials to enforce and to size the gaps in the basic structural or matrix material assist in maintaining the desired mechanical properties of the gross fill 104 .
- the difficulty is not one of strength.
- the improvement of section modulus while using less of the principal material to fill 104 does not substantially effect negatively the stiffness modulus or section modulus of a tie 10 in accordance with the invention.
- FIGS. 33 through 36 primarily, while continuing to refer generally to FIGS. 1 through 36 , a process 270 of manufacture 274 in one embodiment of a composite rail tie 100 in accordance with the invention is illustrated.
- core preparation 271 may be done as part of the process 270 , or may already be completed prior to the process 270 beginning.
- the brackets indicate that this step is optional at this location, at this time, or at all.
- shell preparation 272 is extensive. All of the discussion hereinabove discusses at length various means and processes with all their accompanying equipment, procedures, materials, and so forth for preparation 272 of a shell 102 . Thus, shell preparation 272 may include manufacture, inspection, storage, transporting, distribution, and so forth in order to acquire a shell 272 to be matched with a core 290 prepared 271 to form a central portion of the composite tie 100 .
- Core filling 273 involves placement of a core 290 inside a shell 102 .
- Core filling 273 is a process of dealing with the realities of a conventional core 290 .
- a composite structure may rely on a comparatively heavier, stronger, more continuous outer structure that supports the maximum stress loads at the “outermost fiber” as that term is used in the engineering arts.
- the center of such a rail tie 100 or composite tie 100 need not maintain the same mechanical properties, including density, structural strength, stiffness, elastic modulus, and so forth. Accordingly, the center of a tie 100 may be filled with a fill material 104 in the cavity 103 , or a combination of materials constituting the total fill 104 in the cavity 103 of a shell 102 .
- a conventional railroad tie such as the wooden railroad ties well known in the art will typically have flaws that are best treated by filling 273 with a resin.
- Core filling 273 involves filling the flaws in the outer surface of a conventional tie used as a core 290 .
- core filling 273 may involve placing uncured resin in gaps or other inclusions within a core 290 .
- That resin may be partially cured or “B-staged” as known in the art. That is, the resin may be partially cured such that it becomes more-or-less dimensionally stable. It will no longer drip or pour. It will stay in place. Nevertheless, it is not being cured or completely cross linked to achieve its proper or maximum structural properties and strength.
- core filling 273 may involve placing a liquid resin, placing and partially curing a resin to a stage B condition, or may involve filling and completely curing. After the filling 273 of a core 290 or the flaws within a core, it now has a dimensional stability that corresponds to a size suitable to fit inside a shell 102 . Accordingly, assembly may now progress.
- Assembly 274 includes placing the core 290 inside the shell 102 . It may also require placement of spacers 260 , depending on precision or subsequent stability required.
- the resin filling 275 may rely upon any of the processes described hereinabove in order to take up space, add additional fillers, weight reducers, foam, foaming (e.g., gassing) agents, glass or polymeric bubbles or beads, organic fillers or synthetics such as recycled crumb rubber, or the like.
- the process of resin filling 275 is directed principally at the process of filling the space that will exist between a shell 102 (as described hereinabove, in one of its embodiments) and a core 290 that will occupy the majority of the internal volume within the shell 102 .
- Molding 276 may take on various characteristics. For example, molding 276 may involve reliance on the shell 102 exclusively or non-exclusively as a mold cavity. It may include a spacer 298 spacing the core 290 appropriately within the shell 102 . This may be so regardless of the cross section of the shell. Curing the resin 300 may be supported with no more mold than the shell 102 itself.
- an actual separate device may receive the shell 102 with the core 290 and resin 300 .
- the mold 302 may be used to maintain pressure, dimensional stability, add preloading, add heat, or otherwise stabilize or enable the process 270 .
- the resin 300 may ultimately be cured 277 by any appropriate means. This may be a chemical process using catalysis, ultraviolet (UV) curing, heat curing, or any other method of curing that is appropriate to the resin 300 occupying the space between the shell 102 and the core 290 . It may occur with addition or removal of heat.
- UV ultraviolet
- Testing 278 may involve testing for dimensional integrity, structural strength, porosity, proper curing and bonding of the resins 300 , appearance, or the like. Testing 278 pronounces a product 100 adequate or inadequate by virtue of destructive testing 278 or nondestructive testing 278 . Failure, an answer “no,” results in the tie 100 being put to some other disposition.
- coating 279 may occur as discussed hereinabove. Any surface on the outside of the tie 100 may be coated 279 as discussed at length hereinabove.
- a tie 100 may be inventoried 280 or put into inventory 280 for later distribution 281 .
- the objective is installation 282 of a composite tie 100 in service.
- the core preparation process 271 may be a portion of the manufacturing process 270 or may precede it. Accordingly, one may collect 283 conventional, wooden, rail ties. These may be inspected 284 . Suitable ones of those ties may be targeted 285 for use as cores 290 in rail ties 100 in accordance with the invention. Ultimately, a test 286 may be thought of as a sorting or classification whereby those that are not targeted result in a “no” answer to some other disposition thereof.
- trim step 287 or process 287 may involve one or more steps or processes.
- the test 286 may include checking for the presence of residual metal, embedded pieces of metal, portions of spikes, or other metal embedded by any means for any reason or by accident.
- One reason for this test 286 is protecting woodworking machinery. High powered saws, planes, drills, and the like may be damaged or destroyed during high volume processing of used wood products, such as conventional railroad ties.
- part of the test 286 may be an inspection for residual metal.
- Testing 286 may include magnetic inspection, x-ray inspection, or anything else likely to detect the presence of hard materials that cannot be trimmed 287 or that may interfere with the process of trimming 287 .
- a conventional rail tie that passes the test 286 for use may be trimmed 287 by sawing off its surfaces, planing thereof, grinding, sanding, blasting, or otherwise trimming 287 the tie.
- Trimming 287 involves trimming for several functions. One function is to provide a dimensional value that is consistent for each one, within a specified tolerance. Thus, trimming 287 for sizing, shaping, or both purposes is one valuable use of trimming 287 . Also, trimming 287 removes material that is on the outermost fiber or the outermost surface of the conventional rail tie. Thus, this is the wood that is typically dirty, splintered, crushed, chipped, split, nicked, and otherwise damaged. Trimming 287 trims off 287 the worst of the surface, while sizing the core 290 to an appropriate and standardized size and shape. This size will typically be from one quarter to one inch less in overall dimension of width 292 and thickness 293 or height 293 of the tie that becomes a core 290 . It may be a greater reduction.
- Inspection 288 may involve additional testing, and appropriate rejection of ties that will not be suitable for cores 290 . Lack of integrity or stability for handling may be most important. Ultimately, all cores 290 that pass inspection 288 may be inventoried 289 for subsequent distribution and use.
- a process 270 is illustrated with the somewhat idealized versions of cross sections. Initially, one will note effectively ten frames or images in the process 270 . Initially, a core 290 or more properly a core blank is typically constituted by a wooden, conventional, rail tie that is being recycled.
- the width 292 and the height 293 are effectively the dimensions, along with a standard length, for a conventional rail tie. Necessarily, some amount of shrinkage may have occurred. Most significantly, however, may be the gaps 294 .
- the gaps 294 may actually be splits 294 , gouges 294 , cracks 294 , flaws 294 , or the like.
- stresses, and so forth may act to cause cracks 294 , gaps 294 , splits 294 , or the like.
- a core 290 may include chafing, compression, shearing, breakage, and other damage. These come as a result of the history of load bearing by the wooden rail tie 290 that becomes a core 290 .
- Repurposing includes reusing it, not as an entirely foreign use, yet not as a rail tie 100 , but as a core 290 that operates as a filler inside a composite rail tie 100 .
- a used rail tie 290 has a market value considerably less than the value of new, uncured resins 300 .
- rail ties 290 may provide a cost effective filler at the location where strength or stiffness are least required, near the center of a composite rail tie 100 .
- wood is lighter than or has a lower density than most resins.
- the core 290 has been trimmed 287 such that its width 292 and height 293 or thickness 293 are reduced. Those reductions may be equal or unequal. As a direct consequence, the portions of the gaps 294 closest to the outermost surfaces are necessarily removed.
- the step 270 between the first and second images may be characterized by a process 271 that results in a prepared core 290 . That process 271 will typically involve cutting, planing, sanding, machining, sawing, or otherwise reducing the dimensions 292 , 293 of the core 290 . The effect includes reducing the influence and size of the gaps 294 . Their outermost portions having been removed with material. Likewise, the dimensional stability and reliability, sometimes referred to as predictability, repeatability, variation, or tolerance has now come under the control of the process 271 of core preparation 271 .
- the core filling process 273 or step 273 results in a core 290 in which the gaps 294 have all been substantially filled or prepared to be later filled with a resin 300 a .
- the trailing letter on the reference numeral simply indicates a specific instance of the item identified by the reference number (e.g., 300 ).
- the result is the image number three or third image of the figure.
- the perimeter of the core 290 is filled in.
- the gaps 294 are filled with resin 300 , which may be partially or fully cured.
- This fill step 273 may be done in the step 275 , in the alternative.
- the core 290 is ready for assembly 274 .
- the fourth image illustrates the assembly 274 or assembled tie 100 .
- the tie 100 is not complete, because the resin 300 b filling in the gap 294 between the core 290 and the shell 102 into which it is placed has not been cured. Meanwhile, spacers 298 have been used or may typically be used to position the core 290 more precisely within the shell 102 .
- the resin 300 a may be identical to the resin 300 b . In other embodiments, the resins 300 a , 300 b may differ. As discussed hereinabove, the resin 300 a filling in the gaps 294 may be “B-staged” or partially cured in order to stabilize it dimensionally, and render it a gel or a solid. A “B-staged” resin 300 a or a wrapper thereon may permit ready handling of the core 290 in the filled condition, facilitating intermediate storage, inventory collection, or the like.
- assembly 274 may or may not require the spacers 298 .
- the width 292 and thickness 293 of the core 290 may provide a greater or lesser clearance between the core 290 and the shell 102 .
- the clearance or gap 294 between the core 290 and the shell 102 is within the tolerance of placement of the core 290 and the shell 102 .
- the resin 300 b itself, may simply fill. In some instances it may form a very narrow (e.g., one quarter to one eighth inch) interface between the core 290 and the shell 102 .
- the space 294 or gap 294 between the core 290 and the shell 102 may be substantial, even greater than half an inch or an inch. In such a situation, manufacturing tolerances may militate in favor of spacers 298 positioning the core 290 more precisely with respect to the walls 106 of the shell 102 .
- any cross section of shell 102 described hereinabove is a candidate for filling by a core 290 .
- the spacers 298 may typically be bars 298 , dots 298 , rails 298 , or long thin strips 298 .
- the spacers 298 may be applied to the outer surfaces of the core 290 before it is placed into the shell 102 or onto the core 290 .
- the spacers 298 may simply be placed periodically as small monoliths of comparatively small dimension and aspect ratios of all dimensions that are on the order of one.
- small squares or circles of proper thickness may be placed near each end, or at certain distances along the length of a core 290 , a shell 102 , or a combination thereof.
- the spacers 298 may provide greater precision when wider gaps 294 are desired between the core 290 and the shell 102 .
- the fourth image thus leads to the resin filling 275 step.
- Resin filling 275 has been effectively done or is done, as in the fourth image after assembly 274 has placed the core 290 , the spacers 298 , and typically both into the shell 102 , then resin 300 b may be added into the gap 294 therebetween.
- resin 300 b may actually coat the core 290 before the core 290 is placed into the shell 102 .
- Resin 300 on the core 290 may fill the gap 294 .
- Another reason this is a suitable manufacturing process is that the resin 300 b may be selected to be expanding.
- assembly 274 itself may involve placing a coated core 290 into the shell 102 . All fitting or gap filling occurring later may rely on the coating 300 a on the core 290 . It may expand upon activation of itself, before or during ultimate cure of the resin 300 b or itself.
- the step 276 of molding 276 may or may not be required. Alternatively, one may think of the step 276 of molding 276 as having various embodiments.
- an outer mold 302 is actually placed over the outermost dimensions 296 , 297 of the tie 100 .
- One reason for this is that good adhesion or chemical bonding may justify containment by a mold 302 having sufficient structural rigidity and stiffness to sustain necessary pressure and maintain the dimensions of width 296 , and depth 297 (thickness 297 ) desired for the tie 100 .
- molding 276 may or may not require containment by an actual mold 302 .
- the top 303 a may be required to maintain the thickness 297 .
- the base 303 a containing the tie 100 and the cap 303 b or top 303 b enclosing it may or may not be required.
- the base 303 a and top 303 b secured together may provide better dimensional stability on the open side of the shell 102 .
- a foaming agent within the resin 300 b may actually force some of the resin 300 b out of the tie 100 , or out from the gaps 294 between the core 290 and the shell 102 .
- the curing step 277 is represented by the sixth image illustrating as an example.
- the heating 304 or addition of heat 304 to the tie 100 depends on reactants. Curing may or may not involve the addition of heat.
- many types of resin 300 may be cured by catalysis, the natural reaction of mixed resin and hardener, such as an epoxies, or the like. Thermoforming relies on cooling of a melted resin (plastic).
- heat 304 is simply used here by example, and not as a requirement.
- the heat 306 leaving the tie 100 during and after cure need not correspond to the heating 304 that may be used for a cure.
- thermoplastics may be melted in order to conduct the resin filling step 275 .
- Epoxies and the like may be added, as most “thermosets,” as room temperature liquids. Epoxies, in particular, typically create exothermic reactions between a resin and a hardener.
- the heat 306 exiting during and after cure may simply be the thermal rejection 306 required in order to dissipate the heat of reaction.
- Testing 278 may be conducted to assure dimensional suitability, structural integrity, and the like as discussed hereinabove. Ultimately, following testing 278 , a tie 100 as illustrated in the eighth image may now undergo spraying 279 or other coating 279 processes. These may involve spraying 279 by a nozzle 308 , or any other applicator 308 , from a paintbrush 308 , to a dip 308 , or the like.
- Some supply 309 or line 309 may feed an applicator 308 applying a coating 108 .
- the coating 108 may be total, single sided, or the like.
- the tie 100 may first be coated with the coating 108 b on the open side of the tie 100 , or that side of the tie 100 that is not covered by the shell 102 .
- various rationales for the coatings 108 b have been discussed hereinabove.
- the coating process 279 or step 279 is illustrated by the eighth and ninth images.
- the tie 100 may be rotated, moved, or otherwise rendered accessible to an applicator 308 in order to supply the coating 108 a on other surfaces of the shell 102 .
- the tie 100 may be inventoried 280 before or after the process of drilling illustrated in the tenth image. Also, for example, ties may be inventoried before or after coating 279 . Ultimately, the destination of a tie 100 may dictate its condition in order to be suitable for its ultimate application.
- a standard tie 100 may be manufactured and later drilled by a suitable drill 310 and bit 311 to form apertures 164 set at the widths or spacing necessary.
- Conventional railroads run at a certain gauge width.
- Narrow gauge railroads, mining railroads, light rail mass transit, and freight rails may each have their own requirements that change the size of the rail, the spacing thereof, and the spacing apart of the apertures 164 as a direct result.
- the resins 300 used may be of any suitable type for the functional requirements of strength, adhesion, durability, flexibility, loading, and so forth. In initial prototypes and analyses, it has been determined that an epoxy resin, such as the M1034 resin of Pro-set® along with the M2037 hardener provide expanding epoxy foam that has been deemed suitable for the resin 300 .
- the resin 300 b may be used, to the exclusion of a resin 300 a , by conducting all of the core filling 273 and the resin filling 275 in a single step, such as in the assembled configuration of the fourth image of FIG. 35 .
- the resin 300 a may completely fill the gap 294 instead.
- FIG. 36 while continuing to refer generally to FIGS. 1 through 36 , as has been stated hereinabove, every permutation in combination cannot be illustrated. However, as discussed hereinabove, most of the options can be used with most of the other options. For example, a specific cross section, and the determination of whether that cross section will be open or closed for any specific shell 102 need not control the use of a core 290 .
- the processes 270 , 271 merely need to accommodate that change in configuration.
- the shell 102 is configured as an open channel, whether rectangular, trapezoidal, or the like, it may receive a core 290 that is of a different shape, or a corresponding shape.
- FIG. 36 illustrates various embodiments wherein the core 290 may be of the same or congruent shape or a different shape compared to the cross sectional interior of a shell 102 .
- a core 290 after core preparation 271 , may be laid into the tray or channel that is a shell 102 .
- a core 290 may be passed axially (perpendicular to the cross sectional area) into the cavity 103 of a shell 102 . This will also affect how, at what pressures, and over what times, any resin 300 will be positioned in the gap 294 between the core 290 and the shell 102 . Again, the viscosity, the amount of fill material within the resin 300 , “inner fills,” and the like may all be accommodated by the engineering of the assembly step 274 and the resin filling steps 273 , 275 . Again, the core filling step 273 may be combined with the resin filling step 275 after assembly 274 of the core 290 in the shell 102 in certain embodiments.
- the core 290 actually provides considerable structural stiffness, structural strength, and the like. It does so at a very favorable economic value.
- the recycling of a tie 290 as a core 290 greatly reduces, by up to a greater than ninety percent the amount of resin 300 required as the fill 104 in the cavity 103 of a shell 102 . This can be done with no loss in structural integrity, strength, or stiffness.
- the effective density, weight, specific gravity, or the like of the tie 100 need not be adversely affected by the density of the core 290 . Whereas many resins 300 are substantially heavier (more dense) than wood, they thereby increase the overall weight and thus handling requirements of a tie 100 .
- the core 290 in the illustrated embodiments provides a normalization or reduction of the average weight of a tie 100 made in accordance with an embodiment of a process 270 in accordance with the invention.
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Abstract
A railroad crosstie (tie) may be fabricated from a composite material including a fiber reinforced polymer shell manufactured by pultrusion or other process, and filled by a suitable material, typically selected from expanded elastomeric polymer (such as polyurethane resin or other polymer), concrete, lightweight concrete formed by conventional aggregate, sand, cement, water, and an ultra light filler such as natural materials, sawdust, beads of expanded polymer such as expanded polystyrene, microspheres of glass or plastic, a recycled wooden tie in conjunction with any of the above, or the like. Fasteners may be driven such as spikes, threaded, such as screws, lag screws, spreading screws, rivets, or the like into apertures, pilot holes, or directly into fill absent apertures therein.
Description
- This application: is a divisional application of U.S. patent application Ser. No. 16/275,771, filed Feb. 14, 2019, and due to issue May 31, 2022 as U.S. Pat. No. 11,345,100; which is a divisional application of U.S. patent application Ser. No. 15/003,628, filed Jan. 21, 2016, issued as U.S. Pat. No. 10,213,973 issued on Feb. 26, 2019; which claims the benefit of U.S. Provisional Patent Application Ser. No. 62/106,540, filed Jan. 22, 2015; U.S. Provisional Patent Application Ser. No. 62/197,412, filed Jul. 27, 2015; and U.S. Provisional Patent Application Ser. No. 62/237,941, filed Oct. 6, 2015; all of which are incorporated herein by reference in their entirety.
- This invention relates to railroad crossties and, more particularly, to novel systems and methods for construction thereof from composite structural materials.
- Railroad crossties, sometimes called rail ties or simply ties, have traditionally been constructed of wood. Wood provides a structural platform sitting on top of road ballast, rock of specified size distribution. The crosstie provides sufficient “flotation” (load pressure distribution) to support the substantial weight of the axles of a railroad train passing over the top thereof. Each rail is secured near one end of each crosstie in order to provide support for a train.
- In traditional embodiments, rail ties have been cut from or formed of various wood products, including hardwoods such as oak, as well as softer woods such as pine or spruce. Typically, rail ties have been treated with creosote, a thick, oily liquid that is highly viscous and is typically soaked into the rail ties as an insecticide or pesticide to prevent or resist rotting of the wood.
- Over time, the spikes that have secured plates to the ties, may eventually begin to loosen. As wood weathers, splits, shrinks, and the like, the spikes may loosen. Accordingly, the base plate underneath each rail, on top of a tie, as well as the securement plates that attach over the top of the base of the rail, may work loose and fail to provide adequate securement.
- In due course, railroad ties are typically removed and replaced by road crews working along the railroad tracks.
- In more recent years, various proposals have succeeded in converting some railroad ties to composite materials, such as fiberglass and the like. Similarly, proposals for rubber rail ties have been made. Concrete ties are used in various mass transit rail systems, but appear to be more common in light rail systems, rather than in the heavy or freight rail systems.
- Meanwhile, recycling of the rubber from tires has become a major storage and remanufacturing issue. To this end, recycled crumb rubber (RCR) has been developed. Recycled crumb rubber is made up of the ground up rubber material from tires, usually absent the fibrous cord materials, such as nylon and rayon, or other polymer cords, and substantially devoid of any of the metals that previously formed the bead and the radial bands of seal reinforced tires.
- It would be an advance in the art to provide a suitable composite tie having suitable protection against weather, suitable strength, selectable weight or density, suitable strength, and reproducible manufacturing.
- It would also be an advance in the art to provide a process and product that may be manufactured by mass production techniques, using combinations of polymers, reinforcement within a polymer matrix, suitable fill materials having densities and strengths necessary and suitable for resisting buckling of a fiber reinforced shell, supporting loads within the shell of a tie, and providing suitable weight, as well as anchoring for fasteners securing rails thereto.
- It would also be an advance in the art to provide a tie that performs suitably in service to resist any tendency toward moving with respect to ballast, that is, for example, providing a suitable degree of lateral ballast resistance against lateral motion of the railroad on the underlying ballast.
- In view of the foregoing, in accordance with the invention as embodied and broadly described herein, a method and apparatus are disclosed as including a process method, equipment, and product for making and using railroad ties formed by pultrusion or other molding processes as fiber-reinforced, polymeric, composite materials. In selected embodiments, the processes and devices may produce an outer shell formed of fiber-reinforced polymer engineered to have the proper strength, stiffness, modulus of elasticity, modulus of rupture, and other mechanical properties necessary to serve as a rail tie.
- A fill material may be selected from concrete, lightweight concrete, expanded polymer, expanded elastomer (elastomeric polymer), or the like. Any fill may, in turn, include an “inner fill” or “bulking agent” such as air, glass beads (hollow spheres), polymer bubbles or spheres, to bulk it up while reducing cost and density or total weight. These may include also sawdust, recycled wood, recycled wooden rail ties, or the like
- Meanwhile, the axial cross-section of a tie may be designed to provide the proper mechanical properties to support a railroad rail passing over a tie. These include supporting the load, resisting chafing, securing the rail to the tie, resisting deflection, resisting buckling, retaining a spike or other fastener, and resisting weather, wear, and the other environmental exposure expected for a rail tie.
- The fiber reinforcement may typically be glass, but may be formed of another polymer. However, glass is typically a cost effective solution to fiber reinforcement, having comparatively lower costs and comparatively higher strength and stiffness than other candidate fibers. Meanwhile, the fiber reinforcement may be configured as continuous filament mats (e.g., non-woven) or a woven mat or layup of multiple directions of fibers accessing each of the principal stress directions of zero degrees, 90 degrees, and positive and negative 45 degrees with respect to zero.
- In certain embodiments, a pultrusion system may provide guides to assist in directing fiber reinforcement rovings as strands, CFM mats, or oriented fiber fabrics such as quadraxial non-crimp fabric, into a molding system that embeds the fiber reinforcement into a polymer matrix and the polymer matrix may be a thermoplastic, but may be well suited to various thermoset, including epoxies, polyesters, and so forth.
- Post processing may include curing, cooling, heating, and the like. Typically, a pultrusion system will rely on rollers to grip the solidified, cured product and dry it continuously from the pultrusion system.
- Ties may be cut to length after manufacture as a continuous beam, typically at a length of about 102 inches in accordance with conventional railroad tie sizing. Meanwhile, the lateral and transverse dimensions are typically nine inches and seven inches, respectively, where lateral is a horizontal direction orthogonal to the axial length of a tie, and the transvers direction is the vertical, orthogonal direction with respect to the horizontal, axial direction of the tie in service.
- Typically, fastener systems may be of configurations, sizes, types, and materials best adapted to the fill material in the tie. Fill materials may be drilled, piloted, or otherwise provided with an aperture sized to receive a fastener. Apertures may be formed to provide an interference between the outer dimensions thereof, and may be of any suitable shape, although a round hole is easiest to drill by rotary motion.
- Meanwhile, fasteners may be driven such as spikes, wherein frictional forces secure the fastener within the fill of a tie. Likewise, fasteners may be threaded, barbed, or otherwise designed to provide pullout strength and securement of a rail to the tie. In certain embodiments, an aperture drilled in the fill, and necessarily passing through the outer shell of a tie, may be made oversized such that no interference exists with a fastener, in order to be later back filled with a suitable material for bonding and binding to the fill, in order to provide adequate purchase (grip, holding power) of a fastener with respect to the fill. Thus, a comparatively lighter density of fill may be used, with a comparatively higher density of backfill into an aperture or cavity formed near (e.g. surrounding) a fastener penetrated into the tie, and particularly into the fill thereof after having passed through the shell.
- Various configurations of apertures may include recesses, relief, countersinks, and so forth. Lag systems may be included wherein a compression sleeve is fitted into an aperture in the tie, after which a threaded fastener, such as a lag screw is threaded into the lag sleeve, thus swelling the lag sleeve and forcing it into a compression fit within the fill.
- Fasteners may include self tapping screws, bolts, lag screws, rivets, blind rivets, meaning fastener having a main shank that is segmented along axial lines and perforated through its length. A passage along a center axis receives a swage driven into the fastener after the fastener is in place for use. Thus, the fastener is inserted by whatever mechanism desired, whether hammered, driven axially, threaded in, or the like after which a swage element is driven down the central passage. The swage separates out the multiple segments of the shank, spreading them apart and rendering the fastener effectively a rivet in practice. This particular mechanism is particularly appropriate for a composite tie in accordance with the invention, because it then allows the fiber reinforced polymeric shell to act as part of the mechanism of securement against pullout or relaxation of load.
- Meanwhile, a spreadable, rivet-like fastener may be driven, placed without resistance, or threaded into an aperture before being swaged out. Analyses of various designs, materials, fill densities, and so forth have been conducted and indicate a rail tie system in accordance with the invention as described hereinbelow appears to have the suitable mechanical properties for satisfactory service as a railroad tie.
- The foregoing features of the present invention will become more fully apparent from the following description and appended claims, taken in conjunction with the accompanying drawings. Understanding that these drawings depict only typical embodiments of the invention and are, therefore, not to be considered limiting of its scope, the invention will be described with additional specificity and detail through use of the accompanying drawings in which:
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FIG. 1 is a perspective view of one embodiment of a rail system partially cut away, implementing a tie in accordance with the invention; -
FIG. 2 is a perspective view of one end of a tie in accordance with the invention, also illustrating end cross-sectional views of certain alternative embodiments of the tie; -
FIG. 3 is a perspective view of one embodiment of a continuous fiber mat (CFM) for reinforcing a composite construction for a tie in accordance with the invention; -
FIG. 4 is a perspective view of one embodiment of a stack-up of various oriented fibers being assembled into a quadraxial non-crimp-fabric (NCF) having four different fiber orientations directed to principal stress directions; -
FIG. 5 is a perspective view of one embodiment of a pultrusion system for manufacturing rail ties in accordance with the invention; -
FIG. 6 is a side elevation, cut away, cross-sectional view of a portion of one embodiment of a tie in accordance with the invention, illustrating securement of a rail thereto on a supporting plate anchored by fasteners in apertures within the ties; -
FIG. 7 is a perspective view, partially cut away, of a segment of a tie in accordance with the invention, having an aperture therein for receiving various shapes of fasteners having a variety of cross-sections, and varying amounts of interference; -
FIG. 8 is a side elevation, cross-sectional view, partially cut away, illustrating two different apertures for receiving fasteners into the tie in accordance with the invention; -
FIG. 9 is a side elevation, cross-sectional view of one alternative embodiment of an aperture for receiving a fastener into the tie in accordance with the invention; -
FIG. 10 is side elevation, cross-sectional view of an alternative embodiment of an aperture in a portion of a rail tie in accordance with the invention, this having more of a pilot hole configuration, with comparatively greater interference; -
FIG. 11 is a side elevation, cross-sectional view of another alternative embodiment of an aperture in a portion of a rail tie in accordance with the invention, for receiving a threaded fastener, and having a counter sunk opening; -
FIG. 12 is a perspective view of one embodiment of a fastener, a spike lacking threads and having a rectangular cross section; -
FIG. 13 is a side elevation, cross-sectional view of an alternative embodiment of a fastener having a self tapping point, followed by a threaded shank or shaft thereabove, and driven by a head shaped to receive an internal wrench as a drive tool for installing the fastener; -
FIG. 14 is a side elevation, cross-sectional view of an alternative embodiment of a fastener illustrating two types of shanks, one barbed, and the other not, with a central channel within the fastener for receiving a spreader that operates as a wedge or swage element dividing the shank into multiple segments and spreading them away from one another in order to provide a riveting type of securement process in a tie in accordance with the invention; -
FIG. 15 is a side elevation, cross-sectional view thereof in a deployed configuration; -
FIG. 16 is a side elevation, cross-sectional view of an alternative embodiment of a fastener, in accordance with the invention, providing threads on the shank, between the head and a point thereof, and including a swage element or spreader to spread the diameter of the threaded shank into multiple segments that may then spread apart and secure the fastener within a tie; -
FIG. 17 is a side elevation view of an alternative embodiment of a fastener having threads on a shank and driven by a head, such as a hexagonal head adapted to fit the shape of a wrench; -
FIG. 18 is a perspective view of one embodiment of a portion of a tie evaluated with a top plate to determine the functional properties thereof in service; -
FIG. 19 is an end cross-sectional view of the tie thereof in an embodiment having sharper corners on the lower surface thereof, to increase the section modulus at the bottom extremum of the cross-section; -
FIG. 20 is a table illustrating the stiffness properties of the shell portion of the tie as analyzed; -
FIG. 21 is a table illustrating the strength properties of the shell; -
FIG. 22 is a table illustrating the stiffness and strength properties of the expanded polyurethane or polyurethane resin (PUR) foam at various densities; -
FIG. 23 is a side elevation view of the tie segment, surmounted by the compression plate and a rail, illustrated in cross-sectional view, as loaded for the evaluation; -
FIG. 24 is a perspective view of the grid or mesh of finite elements used in analyzing the performance of the rail tie; -
FIG. 25 is a perspective view of a distribution of vertical displacements thereof in the tie under compression loading; -
FIG. 26 is a chart showing curves of the elastic deformations thereof under a 100,000 pound force compressive load on a tie in accordance with the invention as a function of various constitutions of reinforcing fibers; -
FIG. 27 is a chart illustrating various minimum values of shell thickness and polyurethane resin densities used in analysis to meet the compression, modulus of elasticity (MOE), and modulus of rupture (MOR) wherein the shell thickness-to-fill density region above the curves corresponds to safe tie designs according to the established criteria, and shell thicknesses or fill densities lower than the curves are considered unsafe; -
FIG. 28 is a chart illustrating values of modulus of elasticity as a function of fill density; -
FIG. 29 is a chart illustrating values of modulus of rupture as a function of the fill density; and -
FIG. 30 is a chart illustrating the weight of a single rail tie, having a length of 102 inches, charted against the fill density along the horizontal axis, wherein each curve represents a different reinforcing fiber configuration. -
FIG. 31 is a cut-apart, perspective view of an alternative embodiment of a composite rail tie having no bottom wall, and thereby an open cross section for the shell containing the fill; -
FIG. 32 is a perspective, cut-away view thereof illustrating additional cross sectional views of optional cross sections that may be fabricated in accordance with the invention; -
FIG. 33 is a schematic block diagram of a process for creating a composite, protruded rail tie, having a conventional, used, rail tie as a core or principal filler inside thereof; -
FIG. 34 is a schematic block diagram of a core preparation process that may be part of the process ofFIG. 33 , or may precede it; -
FIG. 35 is a process flow diagram illustrating various cross sectional views of a core and a composite rail tie in accordance with the invention; and -
FIG. 36 is a series of cross sectional views of alternative embodiments of a composite rail tie filled with a portion of a conventional wooden tie as a core, which may take on any of the cross sections and use any of the fill materials around the core that have been discussed herein. - It will be readily understood that the components of the present invention, as generally described and illustrated in the drawings herein, could be arranged and designed in a wide variety of different configurations. Thus, the following more detailed description of the embodiments of the system and method of the present invention, as represented in the drawings, is not intended to limit the scope of the invention, as claimed, but is merely representative of various embodiments of the invention. The illustrated embodiments of the invention will be best understood by reference to the drawings, wherein like parts are designated by like numerals throughout.
- Referring to
FIG. 1 , asystem 10 in accordance with the invention may implement a composite construction for arail tie 100. In the illustrated embodiment, atie 100 may be of a conventional size in order to meet replacement needs (retro fit) in systems already using conventional ties. Conventional ties are typically cut from wood, treated to extend their service life. Typical height from a railroad bed of a ballast rock is about seven inches. Meanwhile, the typical width of a tie is nine inches. Meanwhile, the conventional length of 102 inches is consistent with the width between rails that was established supposedly by the width of a chariot on the roads of ancient Rome. Thus, thetie 100 may have these traditional dimensions. - A
tie 100 may be formed of ashell 102 formed of a composite structural material. Typically, the composite material of theshell 102 may be a polymeric matrix of resin such as a polyester resin, epoxy resin, or other thermoset resin. A thermoset resin will be cured by any of several means, including heat. However, the addition of heat after cure will not result in liquefaction of the resin. That is, thermoset resins cure. They may require heat to induce the cure, and may be exothermic (giving off heat, rejecting heat) in the process of curing. Thereafter, they will typically maintain a solid state, even to the point of being completely carbonized in a furnace. - Alternatively, the polymer may be a thermoplastic. Thermoplastics differ from thermosets in that a thermoplastic may be reheated to become liquefied again. One benefit to thermosets over thermoplastics is that thermosets are less vulnerable in service to excessive environmental temperatures.
- The
shell 102 is typically filled with afill material 104 or fill 104 formed of a very different constituent, which may also be a composite. In some embodiments, thefill 104 may be concrete. Such concrete materials may be substantially similar to those used for concrete structures in various civil engineering projects. Walls, buildings, sidewalks, and the like use a combination of aggregate, sand, and Portland cement rendered active by the addition of water and mixing. - Meanwhile, various types of concrete may include greater or lesser amounts of sand, greater or lesser amounts of aggregate, greater or lesser amounts of cement, greater or lesser amounts of other additives, and greater or lesser amounts of water and curing agents.
- In one embodiment, the
fill 104 may be concrete having an engineered fraction of expanded polystyrene. It has been found that particles of expanded polymers, such as polystyrene, will reduce the weight of concrete. It also provides additional toughness against fracture. Point loads, sharp impacts, and the like will often fracture conventional concrete. The addition of other polymeric fillers that introduce not only a polymer but additional entrapped air in the expanded polymer have been found to provide additional toughness and resistance to fracture. Moreover, the addition an expanded polymer, such as expanded polystyrene may permit, or perhaps more clearly enable, the engineered control of density of theoverall fill 104 when installed. This enables creation ofties 100 of substantially any desired mass or weight. - In yet another embodiment, recycled crumb rubber has been found to have many properties suitable for application to structural support. In one embodiment, a binding resin may be mixed with recycled crumb rubber (RCR) as a
fill 104 inside theshell 102 of atie 100 in accordance with the invention. - In yet another embodiment, the
fill 104 may be an expanded polyurethane resin (PUR). Polyurethane may be manufactured in a multiplicity of grades, providing various degrees of hardness, various degrees of flexibility, various degrees of density, and so forth. Meanwhile, PUR may be configured in a variety of elasticity and strengths. By elasticity of a material is meant the elastic modulus. That is, the elastic modulus defines the behavior of materials that abide by Hooke's law. - Hooke's law is the law of spring constants. It basically states in mathematical form that a force is equal to the spring constant of a material multiplied by the deflection (movement, distortion, bending, etc.) of the spring material. The force acts opposite to the direction opposite to the deflection. Thus, a spring in compression provides a force in the opposite direction from the compression, proportional to the deflection. That constant of proportionality is often referred to as “k” or the spring constant.
- One benefit of PUR as a
fill 104 is the ability to engineer the mechanical properties such as modulus of elasticity, modulus of rupture, ultimate strength, and so forth. The elastic modulus is related to stress and strain. That is, the elastic modulus is also characterized in a material as the stress (force per unit area) applied to a material, divided by the strain (deflection in length per unit length) undergone by the material being loaded (having a force applied). - In the illustrated embodiment, the
shell 102 is composed ofwalls 106. Herein, a trailing letter following a reference numeral indicates a specific instance of a particular item identified by the reference numeral. Thus, it is proper to speak of awall 106, generally, of ashell 102. For the sake of describing various material properties and other characteristics, we may identify specific walls such as theupper wall 106 a ortop wall 106 a, thebottom wall 106 b, or either of theside walls 106 c. - As can be seen, the
upper wall 106 a (or any wall 106) may be coated with acoating 108. Likewise, thebottom wall 106 b may be coated with thesame coating 108 or another. In fact, theupper wall 106 a may be coated with onematerial 108 a, having one set of properties while thelower wall 106 b is coated with adifferent coating 108 b of different properties. In certain embodiments, the entire exterior or outer surface of theshell 102 may be coated with acoating material 108 selected for universal use on any and all sides. - The purpose of the
coatings 108 may be singular or multiple. For example, the reinforcing material within the polymeric resin that forms theshell 102 is typically glass. It may be some other polymer, or a mixture of materials. However, the cost and performance of glass fiber make glass fiber an excellent candidate as a reinforcing material in a matrix of polymeric resin forming theshell 102 of eachtie 100. - The
coating 108 may provide mechanical damping, mechanical deflection, and stress relief, as well as protection against chafing. For example, acoating 108 may provide protection of the glass fibers and resin in theshell 102 from sharp objects, wear, chipping, impacts, and the like to which they may be susceptible. Also, thecoating 108 may also provide protection against ultra violet or other electromagnetic radiation (e.g., sunlight and its constituent parts), weather (rain, freezing, dust, etc.) chemical attack, or the like. - On the
bottom wall 106 b, thecoating 108 may have different properties to meet different requirements. For example, a significant performance concern forrail ties 100 is lateral ballast resistance. The lateral resistance parameter is important to the ability of railroad tracks to maintain their alignment over time and traffic. Thus, whereas a polymer and its reinforcing material forming theshell 102 may tend to have a comparatively lower coefficient of friction than, for example, a rubber or elastomeric polymer material, the ability to resist lateral motion may be improved by the addition of thelayer 108 b of acoating 108 on thelower wall 106 b. - Moreover, protection against chafing by the rock within the road bed (ballast) supporting a
rail tie 100 may reduce impact, distribute loads, prevent point loads, and otherwise maintain the integrity of theshell 102 under the force of compression represented by a train passing over thetie 100, and “grinding it into” the road bed. Just as acoating 108 a on theupper wall 106 a may prevent chafing by arail assembly 110, thecoating 108 b may provide protection against the chafing of rock. It may provide increased resistance to lateral movement of therail 112, which is longitudinal movement of thetie 100, with respect to the ground and the road bed. - In the illustrated embodiment, the
rail assembly 110 includes arail 112 crossing a sequence ofties 100. Eachrail 112 is typically supported by aplate 114 that distributes the load of therail 112 across a broader surface area of theshell 102 of thetie 100 than would be covered by therail 112 itself. - Meanwhile, the
rail 112 and its underlying, supportingplate 114 are maintained snug against thetie 100 by akeeper 116 securing therail 112 to thetie 100. Typically, within the length of atie 100, and typically comparatively closer to each of theends rail assembly 110, including aplate 114, akeeper 116 on each side of arail 112, and the rail itself crossing thattie 100. Traditionally,fasteners 120 have beenspikes 120 driven through apertures in thekeeper 116 andplate 114. - Meanwhile, a portion of the
keeper 116 extends over the bottom of therail 112 in order to secure it in place. Typically, thekeeper 116 registers therail 112 along the length or longitudinal direction of thetie 100. Also, thekeeper 116 holds therail 112 down in contact with theplate 114, keeping both theplate 114 andrail 112 snugged down against thetie 100. - One may note that the
top surface 122 andbottom surface 124 of thetie 100 are illustrated with acoating 108. Thecoating 108 is not required. In some embodiments, the resin selected to form theshell 102 may have a degree of flexibility that dispenses with the benefits or some of the benefits of acoating 108. Regardless, thetop surface 122 may be referred to as the top surface of thetie 100, as completed with thecoating 108, or absent such. Similarly, thebottom surface 124 may be the surface of theshell 102, or may be the ultimate surface of thetie 100 after theshell 102 has received acoating 108. - The
rail 110 is constituted by anupper flange 125 that actually carries the wheel of a rail vehicle (e.g., locomotive, car, etc.) while alower flange 126 provides a base 126 on thetie 100. Aweb 127 connects theupper flange 125 to thelower flange 126. Typically, the bending loads on theentire rail 112 render the “I” shape of therail 112 an effective beam. In order to support the loads imposed on therail 112, the I-beam construction provides for the maximum stiffness at the minimum weight required to support the load. - That is, the section modulus (used here as the term is used in engineering) is the mechanical property of a material that reflects the effect in bending. It reflects the location of the material away from the “neutral axis” near the midway line, as the maximum compression is imposed at one “outermost fiber” while the maximum tension is imposed on the opposite “outermost fiber.” “Outermost” is at the points most distant from the neutral axis.
- Thus, a rail car wheel presents a load in compression against the
upper flange 125, putting it into local compression. Meanwhile, thelower flange 126 is placed in tension in response to the tendency of therail 112 to bend between supporting points, such asadjacent ties 100. - The same principles of section modulus (an engineering term defining the exact relationship between the cross-sectional shape and the stiffness of that shape) applies not only to the
rail 112 but also theshell 102. In the illustrated embodiment, theupper corners shell 102 will typically be rounded at some value of a radius in order to minimize stress concentration factors at thosecorners 128. - Meanwhile, the
lower corners tie 100 by increasing the section modulus. - The section modulus is proportional to a power of the distance from the neutral axis to the outermost fiber. Thus, the overall stiffness is greatly improved by putting a comparatively small proportion of the overall cross-sectional area farther away from the neutral axis, and especially at or near the outmost fiber. The
upper corners 128 andlower corners 130 need not have the same radius, nor contain the same amount of material. - Referring to
FIG. 2 , while referring generally toFIGS. 1 through 36 , various cross-sections provide different benefits in atie 100 in accordance with the invention. In the perspective view, thetie 100 is shown with a radius at eachcorner tie 100 a is rounded on allcorners tie 100 e and thetie 100 f. In an alternative arrangement, theties lower corner 130 on each side with theradiused corners ties coating 108. In contrast, thetie 100 c is fully coated about itsouter surface 122 while thetie 100 d has acoating layer 108 a on the top and acoating layer 108 b on the bottom. Similarly, thetie 100 e has acoating 108 a on top with acoating layer 108 b on the bottom, whereas thetie 100 f is fully coated about itsouter surface 122. Thus, in the various embodiments, thecoating 108 a may provide for protection against weathering from sun, rain, or chemical environments, as well as providing for resistance to chafing, stress concentrations (stress risers), or the like from loading by theplate 114 against thetie 100. - Meanwhile, each of the
layers 108 b or theportion 108 b of thecoating 108 about atie 100 provides protection against stress concentrations, chafing, weathering, and other factors. Specifically, a suitable thickness of acoating 108 b with the engineered properties of toughness, spring constant or elastic modulus, durometer value of hardness, texture variation along the surface thereof, and the like may be engineered to promote stress distribution of loads of underlying ballast rock against thebottom surface 124. Likewise, the material properties of thecoating 108 b should be engineered to provide a coefficient of friction against the underlying ballast rock of the railroad bed to provide for lateral support of the railway, meaning resistance to axial motion by thetie 100 in its axial direction, which is laterally orthogonal to the travel direction of therails 112 of a railroad system. - The fiber reinforced composite that constitutes the
shell 102 may include one or more mats or the like. For example, afiber reinforcement 131 ormat 131 may be constituted by a continuous filament mat 132 (CFM 132). This type of amat 132 is manufactured by spinning out a continuous filament 133 (or actually many filaments 133) that are permitted, actually encouraged, to lie flat on a manufacturing surface. Typically, these many filaments run continuously, thus forming the continuous filament orfilaments 133 of themat 132. - Typically, some adhesive material is included to bond the
various filaments 133 together into a mat of stable dimensions. Themat 132 thus becomes a non-woven fabric of sorts. Themat 132 has a thickness that may be selected in manufacturing to be of any desired amount. The dimensions of such amat 132 may also be selected for length and width according to the desired shape into which it will be molded. In the illustrated embodiment, thefilaments 133 overlap one another, cross one another, and otherwise provide a random layout of fibers extending without break. - Thus, structurally stronger than chopped fiber and other materials that are more easily molded, the
mat 132 must be folded, deflected, formed, and so forth while maintaining its integrity, in order to form a particular shape. Such geometries as cylinders, rectangular tubing, and the like, may thus be formed by overlapping the edges of themat 132. Of course, themat 132 may be a continuous mat fed from a roll, into a molding system in order to form a fiber reinforced composite material of a particular shape. - Referring to
FIG. 4 , in an alternative embodiment, areinforcement mat 131 may be configured as a quadraxial layup in which the principal axes of zero degrees, 90 degrees, 45 degrees, and −45 degrees are all laid up in asingle mat 131, constituting the quadraxialnon-crimp fabric 140 orfabric mat 140.Longitudinal fibers 134 may be alternated withdiagonal fibers 135 at 45 degrees, and followed by otherorthogonal fibers 136 in a lateral direction. Thus, thelongitudinal fibers 134 lie at 90 degrees with respect to thelateral fibers 136 and vice versa. - Meanwhile,
diagonal fibers 135 at 45 degrees are juxtaposed to otherdiagonal fibers 137 at −45 degrees. Thus, thediagonal fibers various layers - Referring to
FIG. 5 , in one embodiment, a pultrusion process may occur in apultrusion apparatus 142. Typically,rovings 141 of any particular form may be constituted by fibers, such as bundles of fiberglass. A roving 141 is typically not woven, but rather simply constituted by an untied bundle of fibers all progressing in approximately the same direction. Some amount of twist may exist, but it is not maintained by a tight twisting such as in a rope, nor necessarily any other ties between fibers. Thus, a roving 141 of fiber may be in any form. - In certain embodiments, the roving 141 may actually be a
mat 131. In certain embodiments, the roving 141 may be a layup ofmultiple mats 131, constituted by bothCFM mats 132 andNCF mats 140. After all, the thicknesses of themats fabric mat 140 may be on each side or each surface of a non woven,CFM mat 132. -
Rovings 141 may be controlled and directed byguides 143 to orient therovings 141 to pass into amolding system 144. In the illustrated embodiment, it is contemplated that themolding system 144 is apultrusion system 142 that draws therovings 141 or the roving 141 into the die, while pumps and presses drive the polymer matrix into the same die. As thefiber reinforcement mats molding system 144, they are completely soaked through with the resin matrix selected and exposed to curing conditions, such as the addition of heat. - Typically, the
pultrusion system 142 may include apost processing system 146 for one or several purposes. For example, apost processing system 146 may include curing heat, cooling air or cooling liquids, cooled extension of the die cross-section, or the like. Ultimately, thepost processing system 146 must discharge to a pulling system 148 a blank 150 or atie blank 150. The blank 150 is atie 100 of substantially infinite length. That is, thesystem 142 may operate continuously. - The pulling
system 148 may include two, three, or fourrollers 152 that grip the blank 150 between them. Rotating on or withshafts 154, driven by motors, not shown, therollers 152 grip against the surfaces of the blank 150, drawing it out of themolding system 144. Tremendous forces may be involved on the orders of hundreds or thousands of pounds. High pressures (tens of thousands of Psi), high velocities, large pull forces (e.g., tons), and the like may occur. - Meanwhile, drawing the
rovings 141, typically one or more of themats mats system 142 is started up by drawing therovings 141 completely through thesystem 152 with no resin. Thus, they may more easily fit through the die, and be grasped by suitable machinery or by hand downstream from the pullingsystem 148. - Once the
rovings 141 can be initially drawn, resin can be added through the molding process and themolding system 144. Eventually, after cure and sufficient cooling to maintain proper strength, the blank 150 may exit themolding system 144. Thepost processing system 146, acting on the blank 150 as a solid that can then be manipulated mechanically by the pullingsystem 148, may provide a continuous production of the cross-section established by the dies in themolding system 144. - Ultimately, a station for cutting the
blanks 150 to a standard length will be necessary, because the pultrusion process of thesystem 142, as illustrated, is a continuous process, not a batch process. - Referring to
FIG. 6 , atie 100 is illustrated in cross-section, taken axially with respect to the rail, and in a transverse plane of thetie 100, parallel to the longitudinal direction of the tie, but also looking orthogonally thereto across the lateral width of thetie 100. Of course, thetie 100 may have any suitable height, illustrated by the illustrated break in the continuity of thefill 104. Thefill 104 may be injected into theinner cavity 156 of thetie 100. Theinner cavity 156 becomes thefill region 104 after completion. - As discussed hereinabove, the
fill 104 may be concrete, lightweight concrete containing particles of an expanded polymer, special compounds of rubber, other elastomers, recycled crumb rubber bonded together by binders, expanded foams (expanded polymers) such as polyurethane resin (PUR), or the like. - In the illustrated embodiment, the
rail 112 is seated on top of aplate 114, whichplate 114 sits on the top of thesurface 122 of thetie 100. Thekeeper 116 grips thebottom flange 126 of therail 112. Thekeeper 116 is secured to thetie 100 by afastener 120. Thefastener 120 may have apoint 158 at the distal end of ashaft 160 orshank 160 of thefastener 120. In the illustrated embodiment, thehead 162 may be sized to support hammering or other driving of thefastener 120 into thefill 104 inside thetie 100. - In the illustrated embodiment, an
aperture 164 in thetie 100 is sized to receive theshank 160 of thefastener 120 with a certain amount of interference. In some embodiments, theaperture 164 need not be provided in thefill 104. In such embodiments, afastener 120, such as a lag screw or acommon railroad spike 120 may be driven into thefill 104, which provides resistance, grip, and securement of theshank 160 therein. In other embodiments, apilot hole 164 oraperture 164 may be sized to provide an interference fit in which theshank 160 compresses away from itself thefill material 104. - The
fastener 120 may be made of a similar material, such as steel, reinforced polymer, or the like as thekeeper 116. Accordingly, it would not be proper for thefastener 120 to be responsible to pierce by itspoint 158 thekeeper 116 material. Rather, anaperture 166 in thekeeper 116 may be fabricated therein or drilled after fabrication in order to provide easy access. Meanwhile, it is advisable that theaperture 164 at least pass through the shell 102 (thetop wall 106 a) in order to not fracture the material thereof. In the illustrated embodiment, anaperture 167 in theplate 114 is aligned and consistent with the size of thefastener 120, and the size of theaperture 166, and thekeeper 116. Likewise, theaperture 164 may have anupper region 165 or anaperture 165 that provides complete clearance with no interference for theshank 160 of thefastener 120. For example, theupper aperture 165 will typically be larger than theaperture 164 within thefill 104 in order to provide clearance for theshank 160 to pass through theupper wall 106 a, quite freely, while providing interference substantial enough to secure theshank 160 within thefill 104. - The
shank 160 may be threaded. Likewise, theshank 160 may be split and a swaging element 200 (SeeFIGS. 14 through 16 ) driven through the center of thehead 120 and theshank 160 in order to separate theshank 160 into segments 204 that deflect and swell by the presence of theswaging element 200 to increase their “purchase” or grip and holding ability within thefill 104. As mentioned hereinabove, theaperture 164 may cease with theupper region 165, requiring that thepoint 158 andshank 160 penetrate thefill 104 without the assistance of apilot hole 164 orother interference aperture 164. - On the
bottom wall 106 b, the support forces of theballast 168 must support and counteract, in accordance with Newton's laws of physics, the load imposed by a train wheel rolling on therail 112 supported by theupper wall 106 a. Again, addition of acoating 108 b on thelower wall 106 b may be designed to provide more grip by theindividual rocks 169 that form theballast 168 of the railroad bed. In certain embodiments, thecoating 108 b may be comparatively softer than the coating 108 a. For example, a material that may deform or mold over time, but not respond quickly, may encourage therocks 169 against thebottom surface 124 to embed into thecoating 108 b, thus increasing the effective friction coefficient to a value greater than would otherwise exist between the smooth surfaces of such materials. - For example, a coefficient of friction operates according to the equation that a force of friction is equal to a coefficient of friction (usually the Greek letter Mu) multiplied by the normal force (force perpendicular) urging the two surfaces of the two materials together. Friction may provide a certain amount of resistance to the sliding in the axial direction of the
tie 100, and thus in the lateral direction of the railroad, by thetie 100. - However, if the material of the
coating 108 b has certain adhesive properties, a certain degree of molding or forming to therocks 169, or the like, then additional engagement may exceed a simple coefficient of friction between therocks 169 and thetie 100. Meanwhile, as theballast 168 settles over time, one may expect thetie 100 to settle into theballast 168, also assisting in lateral resistance to motion by the railroad. Theballast 168, according to studies on the subject, becomes more resistant to lateral displacement ofties 100, where lateral is with respect to the railroad direction. Resistance to motion along an end-wise direction for the longitudinal dimension of thetie 100 improves with consolidation of theindividual rocks 169 together in theballast 168. This suggests that the resistance of theindividual rocks 169 to individual motion of one another may have increased. This may also indicate that atie 100 has settled somewhat deeper into theballast 168, thus providing some support for lateral loads on the railroad rails 112. - It may also suggest that the
individual rocks 169 may have engaged more completely thebottom surface 124 of thetie 100. This may be a matter ofindividual rocks 169 cutting in or orienting to engage various depressions or concavities that may exist in thebottom surface 124. Thus, resistance is offered by a combination of friction, direct mechanical engagement by therocks 169 of thebottom surface 124, and its various topography, as well as mechanical resistance by the consolidation ofindividual rocks 169 into theballast 168 at either end 118 a, 118 b of thetie 100. - Referring to
FIG. 7 , thefill 104 within atie 100 is illustrated in a perspective view, and having anaperture 164 prepared therein. Typically, theaperture 164 may be drilled to extend through theshell 102 and into thefill 104. It is contemplated that various types offasteners 120 may be installed to engage the inner surface of theaperture 164. Engagement typically may be facilitated by an interference between the outermost dimensions of thefastener 120 and a compressed portion of thefill 104 immediately surrounding theaperture 164. Thus, various embodiments are illustrated for the engagement of thefasteners 120 by theapertures 164. - In the illustrated embodiment of
FIG. 7 , various configurations offasteners 120 are illustrated, penetrated intoapertures 164. Various shapes and degrees of interference are illustrated. For example, afastener 120 may be configured to have a round shape, threaded shape, barbs, segments that may be divided away from one another along axial cuts or separations, and so forth. - For example, in general, a
fastener 120 may have ahead 162 that is configured to receive a driver, such as a hex wrench, a bolt-like head 162 to receive an adjustable wrench or other hexagonal wrench fitting around the exterior thereof, or the like. The profile image of afastener 120 illustrated includes apoint 158 in order to engage theaperture 164, and possibly cut into thefill material 104. Likewise, theshank 160 is illustrated generically, and may be threaded, barbed, flat or smooth sided, textured, or otherwise designed to engage thefill 104 surrounding theaperture 164. - Meanwhile, it is contemplated that the
head 162 has a top 172 into which a fitting for a wrench is formed into thehead 162. Likewise, theedge 174 of thehead 162 may be shaped to fit another type of wrench that engages the exterior surface of theedge 174. An example of this would be a conventional hex head commonly used with end wrenches, socket wrenches, adjustable end wrenches, and so forth. Similarly, square heads have been ubiquitous for centuries. - The effect of driving the
shank 160 of afastener 120 into anaperture 164 or simply directly into thefill material 104 is to grip theshank 160 in theaperture 164 or thematerial 104 such that theshoulder 176 of thefastener 120 maintains a compressive force against thekeeper 116. Meanwhile, thekeeper 116 maintains in compression thebottom flange 126 of therail 112 against theplate 114. - As a practical matter, the function of a
fastener 120 is to hold thelower flange 126 of therail 112 in compression toward thetie 100. As a consequence of this compressive force exerted by theshoulder 176 against thekeeper 116, and of thekeeper 116 against thebottom flange 126 is to capture theplate 114 under thebottom flange 126 of therail 112, thus maintaining therail assembly 110 secure against motion in substantially all degrees of freedom (e.g., rail longitudinal direction, rail lateral direction, rail transverse/vertical direction, and any bending or rolling about any of those directions as axes). - The
fasteners 120 a through 120 f are simply alternative embodiments for the engagement by thefasteners 120 with theaperture 164, fill 104, or both. Thefastener 120 a is illustrated in cross-section with theshank 160 as it would appear embedded in thefill 104 immediately surrounding it without any pre formedaperture 164. Thus, for example, aspike 120 a having a rectangular cross-section may be driven by force applied to ahead 162 in order to drive theshank 160 into thefill material 104 without apre-drilled aperture 164. - The
fastener 120 b is similar to thefastener 120 a, having the same type ofshank 160, but having a certain degree of relief provided by anaperture 164 b that is nearly apilot hole 164 b. That is, the interference between theshank 160 and theaperture 164 b is substantial. Theshank 160 does not have to drive its own penetration into thefill 104, because the pilot provides a certain amount of relief. Nevertheless, substantial interference, and therefore substantial pressure on theshank 160 by the surroundingfill 104 may tend to hold thefastener 120 b securely in thefill 104. - The
fastener 120 c provides less interference between theshank 160 and a substantiallylarger aperture 164 b. Theshank 160 must drive, cut, or otherwise displace the amount offill 104 existing between the profile of theaperture 164 b, and the profile of theshank 160. - By the same token, the
fastener 120 d is illustrated with anaperture 164 d that actually has interference near the corners of theshank 160, and clearance between the flat sides of theshank 160 and the circumference of theaperture 164 d. - In the embodiment of the
fastener 120 e, the outermost diameter of theshank 160 is larger than a drilled, circular aperture 164 e. This may be a drivenshank 160 that is simply driven like aspike 120. Alternatively, theshank 160 may be threaded, helical threaded, barbed, separable, or otherwise designed to engage thefill 104 surrounding the initial aperture 164 e. Again, with thefasteners 120 a through 120 f, thefill material 104 and theaperture 164 in each will eventually conform to the outer surface of each of therespective shanks 160. - Thus, the illustrated interference is the interference that would exist before the
shank 160 is driven into theaperture 164 or the surroundingfill material 104. The interference largely or entirely disappears, as theshank 160 forces the material 104 to move out of the path of theshank 160. One result is that the spring force or the elastic force of thefill material 104 provides a frictional, shear, or other engagement of the outer surface of theshank 160 by thematerial 104. - Likewise, the
fastener 120 f illustrates a comparativelysmall aperture 164 f operating substantially as a pilot, with theshank 160 f driving into thepilot aperture 164 f, withthreads 170 engaging by either displacing, cutting, or otherwise penetrating outward radially into thefill material 104. Thus, for example, thethreads 170 orflutes 170 may compress thefill 104, or cut into it as theshank 160 drives down into thefill material 104, piloted by the comparativelysmaller aperture 164 f. - Referring to
FIG. 8 , arail tie 100 may have a distance or length of thetie 100 extending outwardly beyond the rails mounted thereon. That is, historically,ballast 168 supports atie 100, and thetie 100 then supports tworails 112 or more running across or laterally across theties 100. Thus, theties 100 may extend substantially beyond therails 112 in order to provide a spreading of the load represented by therails 112 against theties 100. Thus,fasteners 120 may exist on each side of eachrail 112 toward eachend tie 100. - In
FIG. 8 is illustrated one embodiment of anaperture 164 g and anaperture 164 h. In the illustrated embodiments, theaperture 164 g has not yet received afastener 120. In contrast, theaperture 164 h has received afastener 120 securing akeeper 116 andunderlying plate 114 to thetie 100. Theapertures - In the embodiment of the
aperture 164 g, anupper aperture 165 represents additional space in which afastener 120 may pass through theshell 102 without any substantial interference. Typically, the mechanical properties of theshell 102 are sufficiently stiff, hard, strong, brittle, and so forth, that theupper aperture 165 is not designed to stretch or displace to accommodate thefastener 120. Instead, afastener 120 may be inserted through theupper aperture 165 without substantial resistance, after which interference will exist between afastener 120 and themain aperture 164 g, as described hereinabove. - One may notice that the
upper aperture 165 may have a bottom surface that may be tapered, flat, or dictated by the artifacts of whatever type of tool is used to form it. Likewise, theaperture 164 h is amere pilot hole 164 h providing nearly total interference between thefill material 104 and the insertedfastener 120. Thefastener 120 in theaperture 164 h is illustrated also with anupper aperture 165 terminating in a taper. - Also, no artifacts have been illustrated on the
shank 160 of thatfastener 120, because theshank 160 may be of any type, including rectangular, circular, or other shape in cross-section, such as a star, triangle, or any other suitable shape. Meanwhile, theshank 160 may also include threads, flutes, barbs, straight sides, textured sides, or the like in order to facilitate engagement by theshank 160 of the material 104 or fill 104 surrounding it. - Referring to
FIGS. 9 through 11 , various embodiments offasteners 120 are illustrated with theirvarious shanks 160. Various configurations ofapertures 164, andupper apertures 165 are illustrated. In each, afastener 120 may be passed through anupper aperture 165 formed in theshell 102, and possibly, not necessarily, extending some distance into thefill 104. Eventually, thefastener 120 engages withthreads 170 or other artifacts (features, shapes) on theshank 160, theouter walls 179 of therespective apertures 164. - The
upper aperture 165 is substantially circular in cross-section, thus forming a right circular cylinder, but terminates with a taper such as may result from the point of a drill bit. Meanwhile, theupper aperture 165 ofFIG. 10 provides a flat shoulder or milled bottom surface of theupper aperture 165. Meanwhile, theupper aperture 165 ofFIG. 11 illustrates a countersink. Any of theapertures 164 providing any degree of interference with ashank 160 of afastener 120 may use any appropriateupper aperture 164 deemed appropriate to accommodate theshank 160, ahead 162, or the like. - No heads are shown for the
shanks 160 of thevarious fasteners 120, because any head may be used. In fact, thethreads 170 may be very comparatively short pitched, that is, thethreads 170 are close together as a conventional screw. In other embodiments, the pitch may be extremely long including a single rotation or revolution or less of onethread 170 between thehead 162 and thepoint 158. Thus, as a twist nail, each of thehelical threads 170 may simply curve or rotate some minimum number of turns or a fraction of a turn in order to support driving thereof into theaperture 164. - Referring to
FIGS. 12 through 17 , various embodiments offasteners 120 may engage theapertures 164 in theties 100 in accordance with the invention. For example, a spike ofFIG. 12 may be driven by placing thepoint 158 into theupper aperture 165 of anyparticular tie 100 and driven by pounding thehead 162. The axial movement of theshank 160 causes engagement of theouter surface 179 orouter wall 179 of theaperture 164 by thesurfaces 178. - Meanwhile, the
edge 174 of a drivenspike 120 ofFIG. 12 need only have sufficient thickness to provide astable shoulder 176 for securing thekeeper 116 to thetie 100. Typically, a hammer or other driver may simply provide an impact load on the top 172 orupper surface 172 of thehead 162, singly or repeatedly, in order to drive thepoint 158 andshank 160 deeply into thefill 104. - Referring to
FIG. 13 , on a threadedfastener 120 thethreads 170 are shown in cross-section. The hidden lines illustratethreads 170 on the back side of thefastener 120. Ahead 162, shows one embodiment of ahexagonal recess 190 for receiving a male hex wrench. In this illustrated embodiment, thepoint 158 is augmented by atap 180 in order to render thefastener 120 a self-tappingdevice 120. - The
tap 180 may include adrilling edge 182 ordrill edge 182 that cuts as it passes into thefill 104. Meanwhile, athread cutter 184 is formed by therelief 186 orrelief region 186 cut into the distal end of thefastener 120. For example, typically, 90 degrees of arc may be removed from near thepoint 158 of thefastener 120. Leaving sharp edges onthreads 170, renders themcutters 184. This self-tapping mechanism may assure that theshank 160 cuts into thefill 104, rather than simply pushing or displacing it outward, to engage thethreads 170. - The
crest 188 of eachthread 170 may be thought of as the outermost point or extent of the diameter of theshank 160. Thus, the broken lines illustrate the hiddencrest 188 of the threads as they pass around the back surface of thefastener 120 illustrated in cross-section here. - Referring to
FIG. 14 , in one embodiment, afastener 120 may act as a something of a rivet. In this embodiment, theshank 160 may include asurface 178 that is smooth, illustrated on the left side of the embodiment.Barbs 194 are illustrated on the right side thereof. Thebarbs 194 may be individual elements that extend or project away from thesurface 178. Alternatively, they may pass completely and continuously around the circumference of theshank 160. They may appear like threads, completely circumnavigating theshank 160, but not progressing helically.Barbs 194 do not progress with rotation of thefastener 120. They progress by driving of thefastener 120 andshank 160 into thetie 100. - The
fastener 120 is provided with achannel 196 down its center. Also, theshank 160 is divided into at least two, and preferably three or even four segments about its circumference. For example, thechannel 196 may be formed as a slot passing straight through from side to side in one, two, or more directions. Alternatively, thechannel 196 may be cut at 120 degree angles about the circumference of theshank 160, in order to render the shank 160 a rivet when the segments are separated. - The effect of the
fastener 120 in service is to be driven by pounding, rotation, or both into anaperture 164 in atie 100. Ashaft 198 formed as part of aswage 200 orspreader 200 may be driven into thechannel 196 after theshank 160 is fully engaged and fully penetrated into thetie 100. Theswage 200 may be placed into thechannel 196 after theshank 160 has been driven into thetie 100, or before. - For example, if the
head 162 is adapted to fit a wrench and theshank 160 is threaded, thehead 162 may be rotated to thread theshank 160 into theaperture 164. Alternatively, theswage 200 may be placed in thechannel 196 after thehead 162 has already been pounded to drive theshank 160 into thetie 100. By either mode, thehead 202 of theswage 200 is hammered or otherwise driven in order to force theshaft 198 down thechannel 196 with an interference fit. - The interference causes the
shaft 198 to spread thechannel 196, thus opening upsegmented portions shank 160 is already divided (e.g., 2, 3, 4, etc.). Theconstriction 206 orshoulder 206 may be placed at an appropriate location along the length of theshank 160 to engage by interference theshaft 198. The result is swaging the segments 204 outward in anexpansion 208 orexpansion direction 208 also asserting aforce 208 andmotion 208 on the segments. - A peculiar benefit of the
fastener 120 is that spreading 208 the segments 204 compresses the fill 204 between the segments 204 and theshell 102. Thus, theshell 102 now may assist more directly to retain thefastener 120, and thus provide a more affirmative engagement and securement of thekeeper 116 andsupport plate 114 along with therail 112 supported thereby. - Referring to
FIG. 15 , one sees the approximate shape of thefastener 120 once theswage 200 has been engaged. One may note that the amount of interference between theshaft 198 of theswage 200 and thechannel 196 may be selected, and may vary at any specific rate. For example, theshank 198 may have a degree of taper. The shape of the channel may also have some degree of taper providing a greater orlesser expansion 208 of the segments 204 and a higher or lower initiation of the spreading 208 thereof along the length of theshank 160. - Referring to
FIG. 16 , yet another alternative embodiment of afastener 120 may rely on ahead 162 adapted to the use of a driver, wrench, hammer, impact device, or the like. The device may likewise havethreads 170 andsegments channel 196 into which is received aswage 200. In this embodiment, thechannel 196 near thehead 162 is sufficiently wide to receive thehead 202 of theswage 200, while theshaft 198 thereof penetrates gradually into thechannel 198, thus spreading apart the segments 204 from one another. In this embodiment,threads 170 are illustrated schematically and in broken lines inasmuch as they would be on the opposite side from the viewer of this cross-sectional view of afastener 120. - Referring to
FIG. 17 , in this embodiment, a side elevation view of thefastener 120 illustrates an alternative embodiment of ahead 162 havingflats 210 orsurfaces 210 shaped to receive a wrench thereon. In this embodiment,threads 170 orflutes 170 around theshank 160 render it a screw, lag screw, bolt, or the like. Anyfastener 120 may have ashank 160 designed according to any of the embodiments illustrated herein, and ahead 162 appropriate thereto for engaging the tooling or tool that will drive thefastener 120 into thefill 104 of atie 100. The use of apilot aperture 164 or other interference-basedaperture 164 may assure securement of theshank 160 in thefill 104. - As a practical matter, the chemistry of the
fill 104 or the structure may also be altered. For example, anoversized aperture 164 may be drilled or otherwise formed through theshell 102 and into thefill 104. Thereafter, a stiffer, stronger, or otherwise modified material may be infused into theaperture 164. This provides better distribution of forces into thefill 104, and better support against pull-out by thefastener 120. Thus, theaperture 164 may be drilled well over size and filled with a suitable holding material, which serves as a modifiedfiller 104. Thereafter, asecond aperture 164 is drilled for receiving and holding theshank 160 of any particular embodiment of afastener 120. - Referring to
FIG. 18 , while continuing to refer generally toFIGS. 1 through 36 , a configuration of a modelledtie 100 is illustrated. Atie 100 comprising ashell 102 containingfill 104 within thecavity 103 thereof was arranged with aplate 114 thereupon. - Referring to
FIG. 19 , a cross-sectional view of thetie 100 is illustrated. The height was about seven inches and the width was nine inches. Various radii for thecorners 128 were posited. It was found that in order to support aconventional plate 114, the radius of 0.625 inches (two centimeters) was necessary in order to provide full support beneath theplate 114 on theupper wall 106 a of theshell 102. - In the illustrated embodiment, in order to increase the section modulus (an engineering term used here in as per the engineering definition thereof) relating the cross-sectional area to the stiffness thereof, was increased by decreasing the radius on the
lower corners 130 to approximate a sharp corner. Thus, more material existed at the outermost fiber. Analyses were done for the design in order to assess the functional performance of atie 100 in accordance with the invention in service. - Referring to
FIGS. 20 through 22 , while continuing to refer generally toFIGS. 1 through 36 , various properties of materials are identified. For example, referring toFIG. 20 , thevalues mat 131 orreinforcement 131 used in ashell 102 in accordance with the invention. The values 212 represent values corresponding tocontinuous fiber mat 132. The values 214 refer to the layered quadraxialnon-crimp fabric mat 140. Each of these values 212, 214, 216 corresponds to aparticular variable 220. For example, the variable 220 a is theunidirectional modulus 220 a along each of the principal axis of stress. ThePoisson ratio 220 b is also identified. Similarly, theshear modulus 220 c along each principal axis is similarly identified. These properties are the stiffness properties of the shell. - Referring to
FIG. 21 , the chart or table illustrates variables 212, 214, 216 corresponding to thevariables 220 identified in the table. For example, listed in the table ofFIG. 21 are the tensile strength in the longitudinal direction, and compressive strength in the same direction. Again, thelongitudinal direction 101 a, thelateral direction 101 b, and the transverse (e.g., nominally vertical)direction 101 c are illustrated inFIG. 1 with respect with thetie 100. Thus, transverse tensile strength, transverse compressive strength as well as the through-thickness tensile strength and through-thickness compressive strength are illustrated. - One will note a great disparity between the longitudinal and transverse strengths compared to the through-thickness strengths. Of course this is to be expected considering the orientation of the
fibers - Meanwhile, shear strengths in plane, transverse between the first and third planes and between the second and third planes are also identified. Here again, the values 212 correspond to the continuous fiber mat. The values 214 correspond to those of the quadraxial
non-crimp fabric mat 140. Meanwhile, the properties 216 represent a value 216 for a hybrid relying on both thecontinuous fiber mat 131, and the woven orNCF mat 140. - Referring to
FIG. 22 , while continue to refer generally toFIGS. 1 through 36 , the stiffness and strength properties of a polyurethane resin foam or expanded polyurethane resin atvarious values 222 of density are illustrated. In this table, thevariables 220 are identified asvariables 220 d through 220 h. The modulus ofelasticity 220 d thetensile stress 220 e, thecompressive stress 220 f, theshear modulus 220 g, and theshear strength 220 h are all illustrated atvarious values 222. Thosevalues 222 correspond to the variable 224 ofdensity 224. - The
values 226 ofvarious densities 224, in pounds per cubic foot of the expanded polyurethane resin (PUR foam), illustrate the change inelastic modulus 220 d,tensile strength 220 e,compressive strength 220 f,shear modulus 220 g, andshear strength 220 h with changes in density. This data illustrates the significance of density as it affects the mechanical properties of thefill 104. Meanwhile, the bulk of thefill 104 may be a material having one density. Inserts of a more dense material ay be placed intooversized apertures 164. This will facilitate better pull-out strength for thefasteners 120 as described hereinabove. - Referring to
FIGS. 23 through 25 , the test configuration contained arail 112 mounted against aplate 114, resting on atie 100. Thetie 100 relied on symmetry, having thetie 100 and theplate 114 centered along the length thereof, which was not full length fortie 100 in service. Rather, a segment of atie 100 supported on atest fixture 228 provided a model of the tie portion under asingle rail 112. - For example, the
fixture 228 may be analogized to theballast 168 of a road bed on which arail tie 100 is supported along its length. Meanwhile, aforce 230 was applied vertically to therail 112, and transferred by therail 112 into theplate 114, which in turn applied theload 230 to thetie 100. Thetie plate 114 was centered such that thedistances 232 from the ends of themodel tie 100 were equal. Theplate 114 had a length of about 14 inches (35 centimeters). - Referring to
FIG. 24 , for the analysis, theplate 114 and tie 100 were subdivided into amesh 234 ofindividual elements 236 for analysis. Theelements 236 represented the structural constituents as understood in the art of structural analysis for the finite element method (FEM) or the finite element analysis (FEA) as those terms are understood in the art of structural engineering analysis. - Referring to
FIG. 25 , the stress distribution throughout thetie 100 is illustrated as thesections 236 a through 236 e of various colors. Theregions plate 114 was most intense, with the stress being eventually transferred away therefrom into theside walls 106 c from thetop wall 106 a of theshell 102 of thetie 100. Meanwhile, thedirections FIG. 25 , the maximum elastic deformation at 100,000 pounds force needed to be no more than one quarter inch. - Referring to
FIG. 26 , the data illustrate themaximum limit 236 a ondeformation 236 along with the actual elastic deformation as a function of thedensity 224 of the expanded polyurethane resin. Notice that the various charts corresponding to themaximum deformation 236 a permissible, thedeformation 236 b corresponding to thecontinuous fiber mat 131, are illustrated as falling much closer together than similarly situated some distance away from the maximum permissible 236 a. Likewise, the hybrid chart orcurve 236 c is virtually coincident with theother curves NCF curve 236 d is slightly lower in elastic deformation than is thehybrid curve 236 c. Both of these are lower inelastic deformation 236 than is thecurve 236 b of thecontinuous fiber mat 131. - As a general proposition, the overall
elastic deformation 236 is on the order of 0.06maximum value 236 for all the configurations. This is well within the permissible 0.25 deformation in inches. - Referring to
FIG. 27 , thechart 238 illustrates values of shell thickness or thickness of thewalls 106 of theshell 102 plotted against thedensity 224 of the expanded polyurethane of thefill 104. In thechart 238, each of thecurves curve 240 a representing thecontinuous fiber mat 132, the fabric orNCF mat 140, with thecurve 240 c, and a hybrid thereof illustrated by thecurve 240 b. Again, as thedensity 224 of the expanded polyurethane resin increases, the shell thickness requirement decreases. - Referring to
FIG. 28 , thechart 242 illustrates values for the modulus ofelasticity 244 plotted against thedensity 224 of the expanded polyurethane resin. Again, a minimum permissible 244 a is identified and up to about a density of about 20 pounds per cubic foot of the PUR, the moduli ofelasticity 244 all exceed the minimum permissible 244 a by a substantial margin. Again, the value of the modulus ofelasticity 244 b for thecontinuous fiber mat 132 is seen to have the lowest value while the value for the modulus ofelasticity 244 c for the hybrid is intermediate that for theCFM curve 244 b, and themodulus 244 d orcurve 244 d corresponding to thestraight NCF mat 140. - Referring to
FIG. 29 , achart 246 illustrates values ofdensity 224 of the expanded polyurethane resin or PUR foam in pounds per cubic foot, against the modulus ofrupture 248 on the vertical axis. Each of thecurves 248 a through 248 d illustrate the respective performances of thetie 100 having ashell 102 of the material identified inchart 246. - One will note again that the
curve 248 b corresponding to thecontinuous fiber mat 132 performs the most poorly, although well sufficient up to a PUR density of about 20. Thus, thecurve 248 b corresponds to the non wovencontinuous fiber mat 132, while theintermediate curve 248 c illustrates that a hybrid performs intermediate the behavior of theNCF fabric curve 248 d and theCFM curve 248 b. As expected the higher the density of the PUR foam, the lower the modulus ofrupture 248. Overall the modulus of rupture is not considered a critical parameter in any case even for the lowest values of shell thickness for heavy foam density in the range of about 45 pounds per cubic foot themodulus 248 is typically higher than minimum required. - Referring to
FIG. 30 , thechart 250 illustrates values ofweight 252 along the vertical axis against thedensity 224 along the horizontal axis. Again, thecurves 252 b, illustrates theCFM mat 132, and thecurve 252 d corresponds to thefabric 140. Thecurve 252 c is for they hybrid. - Referring to
FIGS. 31 and 32 , while continuing to refer generally toFIGS. 1 through 36 , in certain embodiments of anapparatus 10 orsystem 10 in accordance with the invention, thebottom wall 106 b may be absent. It has been found that the deflection, strength, stiffness, and other mechanical properties of atie 100 in accordance with the invention may operate satisfactorily without requiring thebottom wall 106 b. Accordingly, in this illustrated embodiment, theshell 102 includes thesidewalls 106 c and the contiguous and continuous, typically uniformly molded or simultaneously molded (pultruded)top wall 106 a. All are continuous, contiguous, and maybe effectively homogenous. That is, the same material, even though a fiber-reinforced composite. Therefore, thetie 100 is fabricated by manufacturing ashell 102 including pultrusion of all of thewalls - It has been found that additional stiffness may be necessary or beneficial in preventing excessive deflection by the
top surface 122 of thetie 100 in order to reduce deflection of thetop surface 122. It may be advisable to increase the thickness of at least theupper wall 106 a ortop wall 106 a. It has been found that stress distribution through thewalls 106 and into thefill material 104 is satisfactory by the time forces, pressures, stresses, loads generally, and so forth are transmitted from therail 112 through thetie 100 and into the ballast below thebottom surface 124. - Testing has demonstrated that the integrity of the
tie 100 is satisfactory, but deflection may be excessive at the comparatively thin dimension of thetop wall 106 a required for strength. Accordingly, stiffness benefits may accrue by increasing the depth or thickness and thus the “section modulus” of thattop wall 106 a. Accordingly, it has been found that the pultrusion of theshell 102 may include additional composite materials incorporated therein. - For example, hereinabove, the concept of
rovings 141,fabrics 140, orfabric mats 140, and the like were described and explained. One aspect of pultrusion that sets it apart from most other manufacturing methods, such as batch molding, injection molding, pressing, extrusion, and so forth is the fact that reinforcement members contribute to the strength and stiffness of the cross section thereof. This supports pulling of the reinforcement members (e.g.,rovings 141,fabric 140, and so forth) relied upon to provide tensile strength. This is true even within the die where the uncured polymer matrix lacks substantially any, and certainly not sufficient, tensile strength to provide any mechanical support for pulling. - In addition, pultrusion shares another characteristic with extrusion, unique to these processes. Typically, pultrusion and extrusion provide a continuous process in which the die continues to receive and discharge input materials and output product, respectively. This necessitates to a certain extent a requirement that the cross section of a pultruded or extruded part typically remain substantially constant. It need not be uniform throughout, but changes in the locations, densities, materials, and so forth are very difficult to make, yielding large unpredictability in a continuous pultrusion or extrusion process.
- This is basically to say that the cross section will typically be constant (from a constant die cross section) along the length of an extrusion or pultrusion. It may still vary along its width, across its thickness, or the like.
- In the instant case, this means to the illustrated embodiment of an
apparatus 100 andsystem 10 in accordance with the invention, that a change in the thickness of theupper wall 106 a ortop wall 106 a and, optionally, a change in thickness of theside walls 106 c may be beneficial, possible, and even practical. Theside walls 106 c appear in testing to have sufficient stiffness in all applicable dimensions and sufficient strength. In all applicable dimensions, they serve at comparatively modest thicknesses shown herein. They are engineered and calculated to support the stresses, strains, forces, deflections, and so forth required for rail ties 100. Thus, whether or not to maintain a uniform thickness across thetop wall 106 a and the associatedcontiguous side walls 106 c is optional. Thus, manufacturing convenience may be the criterion by which a determination is made. - However, it is beneficial to increase the bending stiffness or section modulus of the
upper wall 106 a and of theshell 102. The pultrusion process, or even an extrusion process, which is also an option, may embed different or disparate fillers. They may be distributed among the polymer matrix that cures to form theshell 102. They may bulk out the reinforcement members such asfabric 140, roving 141 orother fibers 133, such as acontinuous fiber mat 132. Thus, in general, anymat 132,continuous fiber mat 132,other fibers 133,fabric 140 orrovings 141 may be formed with, or inserted around other spacing fillers that do not share the mechanical properties of such reinforcements. - For example, in one currently contemplated embodiment, long strands of filaments or other configurations of lighter polymers, such as expanded polymeric materials may fill in between the reinforcement fibers in the matrix of the
upper wall 106 a or other portions of theshell 102. This means, for example, that an upper surface or the uppermost reinforcement of any type ofmat - Materials such as expanded polystyrene (EPS, Styrofoam™), other materials, such as polyurethanes, natural fibers, other lightweight synthetic materials, and the like may fit within the thickness of the
top wall 106 a of theshell 102. In some embodiments,mats top wall 106 a. - Therebetween, or therewithin, may be distributed some smaller quantity of reinforcing fibers and the matrix polymer, interspersed with comparatively larger quantities of lightweight, low strength materials. The function of these spacing materials is simply the spacing apart of the reinforcement and matrix materials in the
top wall 106 a in order to increase the section modulus thereof. Thus, the strength of thetop wall 106 a may be calculated, engineered, and constructed so its stiffness suffices. Thus, additional stiffness is added by increasing the individual section modulus of theshell 102, especially, or particularly, in thetop wall 106 a. - Increasing the section modulus occurs by moving more of the reinforcing material and the matrix material enclosing those fibers toward outermost extremes (e.g., toward the “outermost fiber” in structural engineering parlance). The stiffness of the
wall 106 a is greatly increased without substantially increasing overall weight, and without substantially increasing material. In fact, the stiffness of thewall 106 a may be greatly increased with virtually no increase in weight or basic reinforcement and matrix materials. Rather, comparatively lower cost, lower weight, lower strength filler materials may separate upper and lower layers of thetop wall 106 a, greatly increasing stiffness. In fact, even axial strength along the length of thetie 100 need not be increased in such a configuration. - For example, the insets of
FIG. 31 illustrate on the left a conventional extrusion. A fiber reinforcedmatrix 254 or a typical composite is made up of reinforcement fibers in a polymeric matrix. This forms one layer. An alternative fiber-reinforcedmatrix layer 256 may also be adjacent thereto, interleaved therewith, or the like. Thus, any of themats 131, CFM's 132,fabric 140, or roving 141 may be laid up in some particular order or arrangement to form atop wall 106 a. Thewall 106 a captures and preferably adheres to thefill material 104 captured therewithin or captured by theshell 102. - In order to increase stiffness by increasing the section modulus (see any structural engineering text for this definition), the inset on the right shows an alternative embodiment. Here,
different layers polymer matrix polymeric matrix 258 as the structural constituent, surrounding a comparatively lighter weight, lower strength, more bulky spacer material 260. - In one embodiment of an apparatus and method in accordance with the invention, the fill material 260 may be fed as strands, comparatively bulky compared to the reinforcement fibers in roving 141,
fabric 140, orother mats upper wall 106 a during fabrication, throughfree rovings 141 or free fibers ofrovings 141. This would suggest the benefit of having at least one layer of fabric in the fiber reinforcedlayers upper wall 106 a also results. - In certain embodiments, it may be advisable to provide reactive polymeric adhesives between the
fill material 104 and thewall 106 of theshell 102. In other embodiments, thefill material 104 inside thetie 100 may also have adhesive properties that bond. These provide stress support or bond pull strength and shear strength at sufficient tenacity to provide the stress support. They assure that thefill material 104 cannot separate from anywall 106 of theshell 102. Thus, whether reactive, to bond chemically, filled into a textured surface of thewalls 106 in order to provide a mechanical connection, or otherwise, it has been found preferable to render thefill material 104 adherent to thewalls 106 of theshell 102 in order to maintain integrity and best mechanical properties. - Referring to
FIG. 32 , in certain embodiments, arail tie 100 may include various optional cross sections or stack ups of materials. For example, beginning clockwise from the lower right corner ofFIG. 32 , in certain embodiments, thewalls 106 or theshell 102 may be open such that nolower wall 106 b is used. Meanwhile, a cross section of thewalls 106 may be constructed in any of the forms discussed hereinabove. - In the first cross sectional view proceeding clockwise, no
coating top coating 122 is added. This may assist in resisting chafing of the reinforcement fibers embedded in the matrix of thetop wall 106 a of theshell 102. The third clockwise cross section adds afull coating 108, including coating on theupper wall 106 a as well as acoating layer 108 b on thebottom surface 124. Meanwhile, thecoating 108 a covers all thewalls 106. - Moving clockwise to the fourth cross section, a
lower coating layer 108 b sits juxtaposed to anupper coating 108 a. In this embodiment, thecoatings 108 are not entire, yet can protect against damage from ballast rock against thesurface 124, and against chafing of therails 112, and theirattachment plates 114 against the upper surface orupper wall 106 a. - In an alternative embodiment, the fifth cross section, counted clockwise from the lower right, is trapezoidal in shape. It may have any suitable angle 264. The angle 264 is not required necessarily for draft. Extrusion and pultrusion can produce products where draft is replaced with force. However, this angle 264 may provide for a more stable base. It may also provide an indication of what surface is to go against the ballast and which is to fit against the
rail assembly 110, or the like. - One will note in the fifth cross section that only the
upper layer 108 a andlower layer 108 b ofcoating 108 are relied upon. In the sixth cross section, thecoating 108 is continuous from theupper coating 108 a all the way around theside walls 106 c to thebottom coating 108 b. - In the seventh cross section illustrated, an inverse angle 264 results in an effective capture of the
fill material 104 between theside walls 106 c and thetop wall 106 a. In this embodiment, thefill material 104 is pressed against theupper wall 106 a by the constrainingside walls 106 c in response to any bending moment on therail tie 100. - Of course any of the illustrated cross sections may have a
coating 108 on the top, on the bottom, all the way around the outer periphery, or the like. These are simply illustrations of various embodiments in which resistance to damage by ballast rock from below,rail assemblies 110 from above, general damage from handling, or the like may be minimized. One reason why this resistance to damage may be available and valuable is the fact that the matrix is typically much stiffer and less compliant than thecoating 108.Coatings 108 may be filled or unfilled elastomeric polymers. Meanwhile, reinforcement fibers may be very much more stiff more akin to properties of conventional fiberglass and its composites. It is consequently more brittle. Its fibers are more easily broken individually by impact, chafing, sharp objects, and so forth. - Typically, the materials of the matrix material 266 compared to the embedded fiber material 268 may be any suitable structural polymer. Various thermoplastics may be used, but thermosets are usually stronger and more stable, thus better. A thermoplastic melts and remelts in response to elevated temperature. It is largely unchanged with remelting. Some degradation may occur, but the material properties and the ability to be remelted to not change dramatically.
- In contrast, a thermoset is a reactive chemical mixture (e.g., like epoxy) in which the initial resins (monomers or mers) react, further polymerize, cross link, or both, resulting in a much stronger and stiffer solid. Moreover, upon reheating, such a thermoset polymer matrix will not melt or reverse its condition or state. Rather, it may be destroyed to the point of carbonization in its entirety, yet will typically still remain as an integral, monolithic solid. Its strength may be burned out of it by thermal degradation as it is reduced to a carbon matrix, but it does not melt or reconstitute to its original constituents.
- Thus, in the illustrated embodiments, glass fibers, polyester fibers, carbon fibers, and other fiber or stranded material having a comparatively higher maximum tensile strength (stress) may be embedded in a polymeric matrix having a comparatively lesser (maximum) tensile strength (stress). Meanwhile, the
filler 104 need have even much less tensile strength than any of the foregoing. - In order to control costs, the
fill material 104 may be a mixture such as recycled crumb rubber chopped up and embedded within a polyurethane foam. Thus, bulk, density, stiffness, and the like may be imparted, while requiring much lower expense in fillers than in the matrix polymers. - For example, recycled crumb rubber (RCM), sand, organic natural materials, sawdust, etc. are comparatively inexpensive. Polyurethane foam is comparatively more expensive. Meanwhile, any polymeric matrix 266 is comparatively more expensive.
- Likewise, the reinforcing fibers 268 are typically used because they are both less expensive than the matrix 266 or polymer 266, while also having better structural strength along their length. Meanwhile, their compressive and tensile strength between fibers 268 is dictated strictly by the matrix 266 itself (unless fibers cross), which provides all the compressive and tensile support laterally with respect to the longitudinal direction of fibers 268.
- In one embodiment, the
fill 104 may be any of the foregoing fill materials, as discussed. Any of these may be an expanded polymer, beads, bubbles, or the like having an engineered fraction of gas or gaps. This type of light, weak, space-filling additive reduces weight without substantially decreasing strength or stiffness modulus (section modulus as understood in engineering) of the polymeric matrix around it. In addition, other fillers enforcing a specific size of gaps (gas, cell, etc.) may also be included. - Particles of expanded polymers, such as polystyrene, will reduce the weight of concrete. It also provides additional toughness against fracture. Point loads, sharp impacts, and the like will often fracture conventional concrete.
- The addition of other polymeric fillers that introduce not only a polymer but additional entrapped air in the expanded polymer have been found to provide additional toughness and resistance to fracture. Moreover, the addition of an expanded polymer, such as expanded polystyrene may permit, or perhaps more clearly enable, the engineered control of density of the
overall fill 104 when installed. This enables creation ofties 100 of substantially any desired mass or weight. Thus, strength, durability, and other mechanical properties including limits on stress, strain, and the like may be engineered into the product. - Expanded polystyrene (EPS) pellets may be formed of any suitable size. They are commonly available in sizes below one eighth inch diameter. These may be mixed into polymer matrices such as polyurethane thermoplastics, epoxy, other thermosets, or the like to reduce density and increase the gaps in the structural material. Polystyrene foam (EPS) may be mixed in so long as temperatures or processing do not melt it or otherwise destroy its effectiveness.
- Also, has been found that permanent “bubbles” or air gaps may be enforced by the addition of microspheres. Microspheres are available from various suppliers and in a variety of materials. Some are simply “bubbles” of air captured in hollow, glass spheres. Others are hollow polymeric (plastic) spheres.
- For example, Minnesota Mining and Manufacturing Company, also known under the trademark of 3M™ is one supplier of glass bubbles. This company provides numerous manufacturing designations for glass bubbles of type K and type S. The majority of the material is a soda lime borosilicate glass. This constitutes the vast majority of its mass with a small percentage remaining of a synthetic, amorphous, crystalline-free silica. The material is effectively a hollow glass bead or a hollow glass bubble.
- The shape is basically a hollow sphere having a comparatively thin wall. In fact, a specific gravity of the beads is on the order of about 0.1 to about 0.6. Since specific gravity is compared with respect to water at standard temperature and pressure, this gives a density of from about 0.1 to about 0.6 grams per cubic centimeter. Typically, the material is sufficiently fine that it may appear as a powder. That is, with a diameter of less than 100 microns, the beads look like a small or finely divided material. This may be considered a powder, although not necessarily the irregular or plate-like shape of a talc or other powders.
- Processing may be by typical pultrusion, extrusion, injection, and other molding processes. Of course, the nature of the glass bubbles is such that they may be fractured if processed overly aggressively. For example, very aggressive, high-shear stress in vigorously mixed environments may damage them. Likewise, point contact shear such as is found in gear pumps, certain types of roll mills, and the like may be problematic. Similarly, excessive processing in screw extruders may necessitate careful and late placement of the glass bubbles in the flow.
- Properties include a comparatively high cross strength of about 18,000 pounds per square inch (psi). In certain commercial densities, the average diameter may be about 30 microns, with a specific gravity of about 0.6, corresponding to about 0.6 grams per cubic centimeter, since specific gravity is simply a comparison with the density of water.
- Being glass, the temperature in which such glass bubbles melt or begin to soften is typically greater than 600 degrees centigrade. Meanwhile, less than one percent of volatiles exist. The glass material is not soluble, and therefor integrates well with virtually any polymer as the matrix in which such glass bubbles may be used as a fill. In one embodiment, such glass bubbles are sold under the designation S60HS glass bubbles from the 3M™ company of Minneapolis, Minn. USA.
- Various other suppliers exist for micro bubbles or microspheres. Not only hollow glass but also polymeric or plastic spheres are sold under the trademark Sphericel™. These typically have a density range of from about 0.14 to about 0.8 grams per cubic centimeter. They are used to add to various types of coatings, structural materials, sealants, putties, adhesives, and so forth. Although useful in thermal plastic molding, these have some of the same limitations as glass spheres. Moreover, their melting temperatures are much below the softening temperature of glass.
- One interesting property of plastic microspheres is that they may include a blowing agent or expansion agent within an unexpanded microsphere. Thus, for example, in certain embodiments, an encapsulated gas or other expansion agent will react to heat. Thus, as the thermoplastic shell softens, the volume of a microsphere of plastic may actually expand up to about 40 times its initial volume, or even more. Thus, these microspheres may be added to polymers during processing, and experience their expansion during the heat of processing. Meanwhile, in operation, they provide stable expansion or stable fill having a substantially reduced density (as a gas or air) compared to the remainder of the matrix in which they serve as fill.
- The net effect is substantial reductions in weight with improved performance in receiving and holding a spike. Space into which a spike can deflect or direct the matrix material is a valuable aid to entry and securement. The result includes a reduction in cost in accordance with reductions in weight of the base matrix, and an ability to design a
tie 10 suitable for the specification of the individual customer or purchaser. - As described above, the use of lightweight fill materials to enforce and to size the gaps in the basic structural or matrix material assist in maintaining the desired mechanical properties of the
gross fill 104. For example, as seen from the data, the difficulty is not one of strength. Thus, the improvement of section modulus while using less of the principal material to fill 104 does not substantially effect negatively the stiffness modulus or section modulus of atie 10 in accordance with the invention. - Referring to
FIG. 33 , particularly, butFIGS. 33 through 36 primarily, while continuing to refer generally toFIGS. 1 through 36 , aprocess 270 ofmanufacture 274 in one embodiment of acomposite rail tie 100 in accordance with the invention is illustrated. In this process,core preparation 271 may be done as part of theprocess 270, or may already be completed prior to theprocess 270 beginning. The brackets indicate that this step is optional at this location, at this time, or at all. - Similarly,
shell preparation 272 is extensive. All of the discussion hereinabove discusses at length various means and processes with all their accompanying equipment, procedures, materials, and so forth forpreparation 272 of ashell 102. Thus,shell preparation 272 may include manufacture, inspection, storage, transporting, distribution, and so forth in order to acquire ashell 272 to be matched with a core 290 prepared 271 to form a central portion of thecomposite tie 100. - Core filling 273 involves placement of a
core 290 inside ashell 102. Core filling 273 is a process of dealing with the realities of aconventional core 290. Typically, a composite structure may rely on a comparatively heavier, stronger, more continuous outer structure that supports the maximum stress loads at the “outermost fiber” as that term is used in the engineering arts. - Meanwhile, the center of such a
rail tie 100 orcomposite tie 100 need not maintain the same mechanical properties, including density, structural strength, stiffness, elastic modulus, and so forth. Accordingly, the center of atie 100 may be filled with afill material 104 in thecavity 103, or a combination of materials constituting thetotal fill 104 in thecavity 103 of ashell 102. - It has been found that used, wooden, conventional, rail ties have certain benefits. They provide a cost effective portion of the
fill 104 that will eventually fill thecavity 103 of ashell 102 forming atie 100. They also may reduce weight substantially. Less importantly, they provide strength, stiffness, and toughness (as those terms are used in engineering parlance). Also, disposition by recycling may be simplified. - However, during the
core preparation 271, observation of thecore 290 will often show defects due to wear, weathering, impact, and so forth. Thus, a conventional railroad tie, such as the wooden railroad ties well known in the art will typically have flaws that are best treated by filling 273 with a resin. Core filling 273 involves filling the flaws in the outer surface of a conventional tie used as acore 290. Thus, core filling 273 may involve placing uncured resin in gaps or other inclusions within acore 290. - That resin may be partially cured or “B-staged” as known in the art. That is, the resin may be partially cured such that it becomes more-or-less dimensionally stable. It will no longer drip or pour. It will stay in place. Nevertheless, it is not being cured or completely cross linked to achieve its proper or maximum structural properties and strength.
- Thus, core filling 273 may involve placing a liquid resin, placing and partially curing a resin to a stage B condition, or may involve filling and completely curing. After the filling 273 of a core 290 or the flaws within a core, it now has a dimensional stability that corresponds to a size suitable to fit inside a
shell 102. Accordingly, assembly may now progress. -
Assembly 274 includes placing thecore 290 inside theshell 102. It may also require placement of spacers 260, depending on precision or subsequent stability required. - Once the
assembly 274 is complete, then additional filling 275 (e.g., by resin) is possible. In the various embodiments of aprocess 270, the resin filling 275 may rely upon any of the processes described hereinabove in order to take up space, add additional fillers, weight reducers, foam, foaming (e.g., gassing) agents, glass or polymeric bubbles or beads, organic fillers or synthetics such as recycled crumb rubber, or the like. Thus, the process of resin filling 275 is directed principally at the process of filling the space that will exist between a shell 102 (as described hereinabove, in one of its embodiments) and acore 290 that will occupy the majority of the internal volume within theshell 102. - Molding 276 may take on various characteristics. For example,
molding 276 may involve reliance on theshell 102 exclusively or non-exclusively as a mold cavity. It may include aspacer 298 spacing thecore 290 appropriately within theshell 102. This may be so regardless of the cross section of the shell. Curing theresin 300 may be supported with no more mold than theshell 102 itself. - In other embodiments, an actual separate device called a
mold 302, may receive theshell 102 with thecore 290 andresin 300. In such amolding process 276 as this, themold 302 may be used to maintain pressure, dimensional stability, add preloading, add heat, or otherwise stabilize or enable theprocess 270. - While in such a configuration, or thereafter, the
resin 300 may ultimately be cured 277 by any appropriate means. This may be a chemical process using catalysis, ultraviolet (UV) curing, heat curing, or any other method of curing that is appropriate to theresin 300 occupying the space between theshell 102 and thecore 290. It may occur with addition or removal of heat. - Testing 278 may involve testing for dimensional integrity, structural strength, porosity, proper curing and bonding of the
resins 300, appearance, or the like. Testing 278 pronounces aproduct 100 adequate or inadequate by virtue ofdestructive testing 278 ornondestructive testing 278. Failure, an answer “no,” results in thetie 100 being put to some other disposition. - Meanwhile, if testing 278 provides an answer of “yes” as to the suitability of the
tie 100 for use, then coating 279 may occur as discussed hereinabove. Any surface on the outside of thetie 100 may be coated 279 as discussed at length hereinabove. Atie 100 may be inventoried 280 or put intoinventory 280 forlater distribution 281. Ultimately, the objective isinstallation 282 of acomposite tie 100 in service. - Referring to
FIG. 34 , while continuing to refer principally toFIGS. 33 through 36 , and generally toFIGS. 1 through 36 , thecore preparation process 271 may be a portion of themanufacturing process 270 or may precede it. Accordingly, one may collect 283 conventional, wooden, rail ties. These may be inspected 284. Suitable ones of those ties may be targeted 285 for use ascores 290 inrail ties 100 in accordance with the invention. Ultimately, atest 286 may be thought of as a sorting or classification whereby those that are not targeted result in a “no” answer to some other disposition thereof. - Meanwhile, those that pass the
test 286 and may affirmatively be considered as useful in thecores 290 or ascores 290 in theties 100 may move on to atrim process 287. Thetrim step 287 orprocess 287 may involve one or more steps or processes. - For example, the
test 286 may include checking for the presence of residual metal, embedded pieces of metal, portions of spikes, or other metal embedded by any means for any reason or by accident. One reason for thistest 286 is protecting woodworking machinery. High powered saws, planes, drills, and the like may be damaged or destroyed during high volume processing of used wood products, such as conventional railroad ties. Thus, part of thetest 286 may be an inspection for residual metal. Testing 286 may include magnetic inspection, x-ray inspection, or anything else likely to detect the presence of hard materials that cannot be trimmed 287 or that may interfere with the process of trimming 287. - A conventional rail tie that passes the
test 286 for use, may be trimmed 287 by sawing off its surfaces, planing thereof, grinding, sanding, blasting, or otherwise trimming 287 the tie. - Trimming 287 involves trimming for several functions. One function is to provide a dimensional value that is consistent for each one, within a specified tolerance. Thus, trimming 287 for sizing, shaping, or both purposes is one valuable use of trimming 287. Also, trimming 287 removes material that is on the outermost fiber or the outermost surface of the conventional rail tie. Thus, this is the wood that is typically dirty, splintered, crushed, chipped, split, nicked, and otherwise damaged. Trimming 287 trims off 287 the worst of the surface, while sizing the
core 290 to an appropriate and standardized size and shape. This size will typically be from one quarter to one inch less in overall dimension ofwidth 292 andthickness 293 orheight 293 of the tie that becomes acore 290. It may be a greater reduction. -
Inspection 288 may involve additional testing, and appropriate rejection of ties that will not be suitable forcores 290. Lack of integrity or stability for handling may be most important. Ultimately, allcores 290 that passinspection 288 may be inventoried 289 for subsequent distribution and use. - Referring to
FIGS. 35 and 36 , while continuing to refer generally toFIGS. 1 through 36 , aprocess 270 is illustrated with the somewhat idealized versions of cross sections. Initially, one will note effectively ten frames or images in theprocess 270. Initially, acore 290 or more properly a core blank is typically constituted by a wooden, conventional, rail tie that is being recycled. - Thus, in the first frame or image, the
width 292 and theheight 293 are effectively the dimensions, along with a standard length, for a conventional rail tie. Necessarily, some amount of shrinkage may have occurred. Most significantly, however, may be thegaps 294. Thegaps 294 may actually besplits 294,gouges 294,cracks 294,flaws 294, or the like. Typically, as wood weathers, particularly as it is subjected to sun for the drying it beyond its original new condition, as well as freezing and thawing cycles, stresses, and so forth may act to causecracks 294,gaps 294, splits 294, or the like. Similarly, in directions other than a radial direction with respect to the axial center line of acore 290 may include chafing, compression, shearing, breakage, and other damage. These come as a result of the history of load bearing by thewooden rail tie 290 that becomes acore 290. - One valuable reason for reusing a worn, aged, damaged,
rail tie 290 is the fact that such anarticle 290 must be disposed of. One effective way to dispose of thatarticle 290 is to recycle it into another use. This may be considered repurposing. Repurposing here includes reusing it, not as an entirely foreign use, yet not as arail tie 100, but as acore 290 that operates as a filler inside acomposite rail tie 100. - In the illustrated embodiment, additional benefits accrue from the fact that a used
rail tie 290 has a market value considerably less than the value of new,uncured resins 300. Thus, to the extent that rail ties 290 are available, they may provide a cost effective filler at the location where strength or stiffness are least required, near the center of acomposite rail tie 100. Moreover, wood is lighter than or has a lower density than most resins. - In the second image, the
core 290 has been trimmed 287 such that itswidth 292 andheight 293 orthickness 293 are reduced. Those reductions may be equal or unequal. As a direct consequence, the portions of thegaps 294 closest to the outermost surfaces are necessarily removed. Thestep 270 between the first and second images may be characterized by aprocess 271 that results in aprepared core 290. Thatprocess 271 will typically involve cutting, planing, sanding, machining, sawing, or otherwise reducing thedimensions core 290. The effect includes reducing the influence and size of thegaps 294. Their outermost portions having been removed with material. Likewise, the dimensional stability and reliability, sometimes referred to as predictability, repeatability, variation, or tolerance has now come under the control of theprocess 271 ofcore preparation 271. - In one embodiment, the
core filling process 273 or step 273 results in acore 290 in which thegaps 294 have all been substantially filled or prepared to be later filled with aresin 300 a. Of course, the trailing letter on the reference numeral simply indicates a specific instance of the item identified by the reference number (e.g., 300). The result is the image number three or third image of the figure. Now the perimeter of thecore 290 is filled in. Thegaps 294 are filled withresin 300, which may be partially or fully cured. Thisfill step 273 may be done in thestep 275, in the alternative. - Having now a properly shaped, filled, reinforced, or otherwise rehabilitated surface, and the like, the
core 290 is ready forassembly 274. The fourth image illustrates theassembly 274 or assembledtie 100. In reality, thetie 100 is not complete, because theresin 300 b filling in thegap 294 between the core 290 and theshell 102 into which it is placed has not been cured. Meanwhile,spacers 298 have been used or may typically be used to position thecore 290 more precisely within theshell 102. - In certain embodiments, the
resin 300 a may be identical to theresin 300 b. In other embodiments, theresins resin 300 a filling in thegaps 294 may be “B-staged” or partially cured in order to stabilize it dimensionally, and render it a gel or a solid. A “B-staged”resin 300 a or a wrapper thereon may permit ready handling of the core 290 in the filled condition, facilitating intermediate storage, inventory collection, or the like. - Ultimately,
assembly 274 may or may not require thespacers 298. Typically, for precision, and maintaining tolerances otherwise, thewidth 292 andthickness 293 of thecore 290 may provide a greater or lesser clearance between the core 290 and theshell 102. To the extent that the clearance orgap 294 between the core 290 and theshell 102 is within the tolerance of placement of thecore 290 and theshell 102, then nospacer 298 need be required. Theresin 300 b, itself, may simply fill. In some instances it may form a very narrow (e.g., one quarter to one eighth inch) interface between the core 290 and theshell 102. - In other embodiments, the
space 294 orgap 294 between the core 290 and theshell 102 may be substantial, even greater than half an inch or an inch. In such a situation, manufacturing tolerances may militate in favor ofspacers 298 positioning thecore 290 more precisely with respect to thewalls 106 of theshell 102. - In this regard, one should also note that any cross section of
shell 102 described hereinabove is a candidate for filling by acore 290. Thespacers 298 may typically bebars 298,dots 298,rails 298, or longthin strips 298. In fact, thespacers 298 may be applied to the outer surfaces of thecore 290 before it is placed into theshell 102 or onto thecore 290. In other embodiments, thespacers 298 may simply be placed periodically as small monoliths of comparatively small dimension and aspect ratios of all dimensions that are on the order of one. - For example, small squares or circles of proper thickness may be placed near each end, or at certain distances along the length of a
core 290, ashell 102, or a combination thereof. Thus, thespacers 298 may provide greater precision whenwider gaps 294 are desired between the core 290 and theshell 102. - The fourth image thus leads to the resin filling 275 step. Resin filling 275 has been effectively done or is done, as in the fourth image after
assembly 274 has placed thecore 290, thespacers 298, and typically both into theshell 102, thenresin 300 b may be added into thegap 294 therebetween. However, in certain embodiments, particularly where thegap 294 between the core 290 and theshell 102 is comparatively small, such as on the order of about an eighth of an inch,resin 300 b may actually coat thecore 290 before thecore 290 is placed into theshell 102.Resin 300 on thecore 290 may fill thegap 294. Another reason this is a suitable manufacturing process is that theresin 300 b may be selected to be expanding. It may expand by heat, a foaming agent, air injection, or other mechanisms. Thus, in certain embodiments,assembly 274 itself may involve placing acoated core 290 into theshell 102. All fitting or gap filling occurring later may rely on thecoating 300 a on thecore 290. It may expand upon activation of itself, before or during ultimate cure of theresin 300 b or itself. - The
step 276 ofmolding 276 may or may not be required. Alternatively, one may think of thestep 276 ofmolding 276 as having various embodiments. In the fifth image, anouter mold 302 is actually placed over theoutermost dimensions tie 100. One reason for this is that good adhesion or chemical bonding may justify containment by amold 302 having sufficient structural rigidity and stiffness to sustain necessary pressure and maintain the dimensions ofwidth 296, and depth 297 (thickness 297) desired for thetie 100. - Nevertheless, depending on the pressures generated by the reactions and foaming of the
resin 300 b,molding 276 may or may not require containment by anactual mold 302. The top 303 a may be required to maintain thethickness 297. Thus, the base 303 a containing thetie 100 and thecap 303 b or top 303 b enclosing it may or may not be required. - Typically, where the
shell 102 may be configured as a channel, the base 303 a and top 303 b secured together may provide better dimensional stability on the open side of theshell 102. For example, a foaming agent within theresin 300 b may actually force some of theresin 300 b out of thetie 100, or out from thegaps 294 between the core 290 and theshell 102. - Regardless of whether the
molding process 276 requires or uses amold 302, the curingstep 277 is represented by the sixth image illustrating as an example. Theheating 304 or addition ofheat 304 to thetie 100 depends on reactants. Curing may or may not involve the addition of heat. For example, many types ofresin 300 may be cured by catalysis, the natural reaction of mixed resin and hardener, such as an epoxies, or the like. Thermoforming relies on cooling of a melted resin (plastic). Thus,heat 304 is simply used here by example, and not as a requirement. - In that respect, with respect to image seven, the
heat 306 leaving thetie 100 during and after cure need not correspond to theheating 304 that may be used for a cure. For example, thermoplastics may be melted in order to conduct theresin filling step 275. Epoxies and the like may be added, as most “thermosets,” as room temperature liquids. Epoxies, in particular, typically create exothermic reactions between a resin and a hardener. Thus, theheat 306 exiting during and after cure may simply be thethermal rejection 306 required in order to dissipate the heat of reaction. - Testing 278 may be conducted to assure dimensional suitability, structural integrity, and the like as discussed hereinabove. Ultimately, following
testing 278, atie 100 as illustrated in the eighth image may now undergo spraying 279 orother coating 279 processes. These may involve spraying 279 by anozzle 308, or anyother applicator 308, from apaintbrush 308, to adip 308, or the like. - Some supply 309 or
line 309 may feed anapplicator 308 applying acoating 108. Again, thecoating 108 may be total, single sided, or the like. For example, in the illustrated embodiment, having a channel-shapedshell 102, thetie 100 may first be coated with thecoating 108 b on the open side of thetie 100, or that side of thetie 100 that is not covered by theshell 102. Again, various rationales for thecoatings 108 b have been discussed hereinabove. Likewise, the benefits and burdens ofvarious coatings 108. Here, thecoating process 279 or step 279 is illustrated by the eighth and ninth images. Thetie 100 may be rotated, moved, or otherwise rendered accessible to anapplicator 308 in order to supply thecoating 108 a on other surfaces of theshell 102. - Ultimately, the
tie 100 may be inventoried 280 before or after the process of drilling illustrated in the tenth image. Also, for example, ties may be inventoried before or after coating 279. Ultimately, the destination of atie 100 may dictate its condition in order to be suitable for its ultimate application. - For example, a
standard tie 100 may be manufactured and later drilled by asuitable drill 310 andbit 311 to formapertures 164 set at the widths or spacing necessary. Conventional railroads run at a certain gauge width. Narrow gauge railroads, mining railroads, light rail mass transit, and freight rails may each have their own requirements that change the size of the rail, the spacing thereof, and the spacing apart of theapertures 164 as a direct result. - The
resins 300 used may be of any suitable type for the functional requirements of strength, adhesion, durability, flexibility, loading, and so forth. In initial prototypes and analyses, it has been determined that an epoxy resin, such as the M1034 resin of Pro-set® along with the M2037 hardener provide expanding epoxy foam that has been deemed suitable for theresin 300. - In particular, the
resin 300 b may be used, to the exclusion of aresin 300 a, by conducting all of the core filling 273 and the resin filling 275 in a single step, such as in the assembled configuration of the fourth image ofFIG. 35 . However, theresin 300 a may completely fill thegap 294 instead. Meanwhile, the discussion hereinabove regarding the use of hollow glass beads, polymeric beads, bubbles, or the like as fillers within anyresin 300 also apply. - Referring to
FIG. 36 , while continuing to refer generally toFIGS. 1 through 36 , as has been stated hereinabove, every permutation in combination cannot be illustrated. However, as discussed hereinabove, most of the options can be used with most of the other options. For example, a specific cross section, and the determination of whether that cross section will be open or closed for anyspecific shell 102 need not control the use of acore 290. - The
processes shell 102 is configured as an open channel, whether rectangular, trapezoidal, or the like, it may receive acore 290 that is of a different shape, or a corresponding shape. Thus,FIG. 36 illustrates various embodiments wherein thecore 290 may be of the same or congruent shape or a different shape compared to the cross sectional interior of ashell 102. In this regard, acore 290, aftercore preparation 271, may be laid into the tray or channel that is ashell 102. - In the case of a
shell 102 that is closed on all sides, acore 290 may be passed axially (perpendicular to the cross sectional area) into thecavity 103 of ashell 102. This will also affect how, at what pressures, and over what times, anyresin 300 will be positioned in thegap 294 between the core 290 and theshell 102. Again, the viscosity, the amount of fill material within theresin 300, “inner fills,” and the like may all be accommodated by the engineering of theassembly step 274 and theresin filling steps core filling step 273 may be combined with theresin filling step 275 afterassembly 274 of the core 290 in theshell 102 in certain embodiments. - Ultimately, the
core 290 actually provides considerable structural stiffness, structural strength, and the like. It does so at a very favorable economic value. The recycling of atie 290 as acore 290 greatly reduces, by up to a greater than ninety percent the amount ofresin 300 required as thefill 104 in thecavity 103 of ashell 102. This can be done with no loss in structural integrity, strength, or stiffness. - Moreover, the effective density, weight, specific gravity, or the like of the
tie 100 need not be adversely affected by the density of thecore 290. Whereasmany resins 300 are substantially heavier (more dense) than wood, they thereby increase the overall weight and thus handling requirements of atie 100. Thecore 290 in the illustrated embodiments provides a normalization or reduction of the average weight of atie 100 made in accordance with an embodiment of aprocess 270 in accordance with the invention. - The present invention may be embodied in other specific forms without departing from its purposes, functions, structures, or operational characteristics. The described embodiments are to be considered in all respects only as illustrative, and not restrictive. The scope of the invention is, therefore, indicated by the appended claims, rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
Claims (21)
1-14. (canceled)
15. An apparatus, shaped as a rail tie and comprising:
a shell formed of materials resistant to bending and to environmental damage;
a first fill as a solid within the shell;
a second fill, pourable and distinct from the first fill, supporting the first fill by filling spaces inside the shell left by the first fill; and
The first and second fill being configured to receive fasteners penetrating thereinto.
16. The rail tie of claim 15 wherein the first fill is resistant to bending.
17. The rail tie of claim 16 , wherein the first fill is selected from recycled rubber, polymeric fibers, fibrous solids, and wood.
18. The rail tie of claim 15 , wherein:
the materials forming the first and second fills are configured to receive and directly engage securely therewithin the fasteners; and
the first fill is a solid, at all stages of formation of the apparatus, configured as at least one of particles, fibers, and a continuous member.
19. The apparatus of claim 15 , wherein the solid is configured as at least one of particles, fibers, and a continuous member.
20. The apparatus of claim 15 , wherein:
the second fill is selected from concrete, lightweight concrete, polymer, filled polymer, composite polymer, expanded polymer, and a combination thereof; and
the second fill has a shear strength different from that of the first fill.
21. The apparatus of claim 15 , wherein the first and second fills are selected to be capable of frictionally securing the fasteners within the shell by compression.
22. The apparatus of claim 15 , wherein the fasteners are selected from a spike, a screw, a lag screw, a rivet, a barbed spike, a spreadable spike, a spreadable screw, and a bonded fastener effective to compress a portion of the solid.
23. The apparatus of claim 15 , wherein:
the first fill is characterized by gaps filled by the second fill; and
the first fill comprises a constituent of lower density than that of the second fill.
24. The apparatus of claim 15 , wherein the first fill is a solid at all stages of formation of the apparatus.
25. An apparatus, functional as a rail tie and comprising:
a shell capable of resisting bending and compression;
a first fill inside the shell and capable of resisting compression and bending of the apparatus;
a second fill inside the shell supporting the first fill by backfilling spaces located in at least one of spaces between the first fill and cavities within the first fill;
the shell, first fill, and second fill being configured together to receive a fastener penetrating through the shell and into the first and second fills.
26. The apparatus of claim 25 , wherein the first fill is a solid.
27. The apparatus of claim 26 , wherein the first fill remains a solid throughout formation of the apparatus.
28. The apparatus of claim 27 , wherein the first fill is configured as at least one of particles, fibers, and a continuous member.
29. The apparatus of claim 25 , wherein the second fill is selected from concrete, aerated concrete, lightweight-filled concrete, polymer, filled polymer, composite polymer, expanded polymer, and a combination of at least two thereof
30. The apparatus of claim 25 , wherein the second fill fits at least partially within the first fill and has a shear strength different from that of the first fill.
31. The method of claim 25 , wherein the first and second fills are capable of securing the fasteners based on elastic resilience of at least one of the first fill and the second fill.
32. The apparatus of claim 31 , wherein the first and second fills are configured to receive the fasteners of a type selected from a spike, a screw, a lag screw, a rivet, a barbed spike, a spreadable spike, a spreadable screw, and a bonded solid member.
33. The apparatus of claim 25 comprising a third fill distinct from the first and second fills and selected to change a physical property of the apparatus selected from stiffness, density, strength, elasticity, toughness, softness, friction, and deflection under load.
34. A method of supporting a rail as a track in a railroad, the method comprising:
providing an apparatus capable of operating as a rail tie and including a shell defining a length and containing a first fill and a second fill dispersed throughout the shell;
positioning the apparatus on a ballast;
positioning a rail on the apparatus;
securing the apparatus to the rail by penetrating the shell, the first fill, and the second fill onsite with fasteners securing the rail onto the apparatus.
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US10213973B2 (en) * | 2015-01-22 | 2019-02-26 | Michael A. Hawkins | Composite rail tie apparatus and method |
JP2019049168A (en) * | 2017-09-12 | 2019-03-28 | 積水化学工業株式会社 | Sleeper and sleeper manufacturing method |
US11584041B2 (en) | 2018-04-20 | 2023-02-21 | Pella Corporation | Reinforced pultrusion member and method of making |
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CA2794871A1 (en) | 2010-04-01 | 2011-10-06 | Michael Griffiths | Utility pole |
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US10213973B2 (en) | 2019-02-26 |
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