Field: springs, in particular springs used in shoes. It is common in human footwear to have a sole material which compresses to absorb impact energy when the mass of the user is transferred to the shoe during each foot strike. Energy is stored in the compression of the sole and then released back as a vertical force on the bottom of the user's foot. The force required to compress the sole must be high enough to decelerate the mass of the user while walking and/or running. Due to the low travel of this “suspension system”, the bounce frequency of a conventional spring will be higher than the natural frequency of the user's walking or running gait. This causes the energy to be returned at a higher frequency than is desirable. A conventional shoe-sole spring will return the stored energy too early in the foot stride. This does not apply a significant portion of the stored energy to the forward motion of the user. A large number of spring shoe designs are known such as in Illustrato U.S. Pat. No. 4,894,934; Chung U.S. Pat. No. 6,553,692; Illustrato U.S. Pat. No. 4,638,575; Vorderer U.S. Pat. No. 4,943,737; and Meschan U.S. Pat. No. 6,996,924 and it is proposed to provide an improvement over these designs of spring shoes.
A spring shoe, and also in particular a spring, as well as a method of returning energy to a user, are provided. In one embodiment, a method and apparatus stores foot strike energy and releases the energy after a slight delay, when the energy will have a forward component. This is accomplished in an embodiment by a spring in the sole which has a decreasing spring force, such that the force required to compress the sole decreases for all or part of the compression displacement as the spring is compressed.
In this way, the force of the user's foot strike can be stored in the elastic deformation of the spring during compression of the sole. The more the sole is compressed past a point of maximum force, the more energy is stored, but the less force the sole exerts vertically on the heel of the user (or anywhere else such a spring or sole construction is used). When the user's weight starts to roll forward to the front of the foot during walking or running, however, the stored energy from the initial foot strike is released as the spring force increases during extension of the sole, propelling the user vertically and forward.
In another embodiment, the spring comprises at least two air chambers, a first chamber acting to provide resistance to compression and another storing gas ejected from the first chamber and then returning the gas to the first chamber after a delay.
The function of the spring is comparable to a compound bow (such as a hunting bow) which takes a large force to draw back, but then requires very little force to hold it in that position. When the string is released, however, the energy which went into elastically deforming the bow is released into the arrow to propel it.
In a similar way, the energy storage and return spring allows the shoe sole to store a large amount of compression energy from a foot strike without exerting a large force when in the fully compressed position. This gives the center of gravity of the user time to move forward (or nearly forward) of the heel and/or ankle before the spring releases the stored energy, providing an upward force on the heel which includes a forward component on the center of gravity of the user.
In one embodiment of an energy storage and return spring, which uses an arched rigid element and an elastic element, the spring may be used in other applications where energy storage and return is desired.
These and other aspects of the device and method are set out in the claims, which are incorporated here by reference.
Embodiments will now be described with reference to the figures, in which like reference characters denote like elements, by way of example, and in which:
Referring to
A spring 110 is set in the sole 102. The spring 110 is shown schematically in
The shoe 100 of
Thus, the exemplary spring shoe 100 is able to return a portion of the compression energy to the user after the user's center of gravity is forward of the user's heel (when the user is walking forward). The spring 110 may be formed of a rigid member and an extensible member that is stretched when the rigid member moves under compression from a foot. In some embodiments of the spring 110, the direction of the primary force which is stretching the extensible member becomes more aligned with the direction of extension of the extensible member for all or part of the compression displacement of the assembly (or shoe sole) as the assembly (or shoe sole) is compressed. In some embodiments of the spring 110, the mechanical advantage of a rigid member as it stretches an extensible member, or compresses a compression member, increases for all or part of the assembly or shoe sole compression displacement as the assembly or shoe sole is compressed.
The spring 110 when compressed by a force, such as the weight (and inertia) applied by a user to the spring 110, will have an oscillating frequency that depends in part on the applied force. If the applied force is less than the force required to compress the spring 110 to the point at which the spring rate of the spring is zero, the spring 110 will have amore conventional oscillating frequency. However, when the applied weight is sufficient to compress the spring 110 into the region where the force reduces, then the spring will not oscillate until the force which is compressing the sole is reduced sufficiently that the spring leaves this region.
Due to the reduction of spring force as the sole 102 compresses, it is desirable to use two different components, the spring 110 to provide energy storage and a damper 114 to provide energy dissipation. The spring 110, which is an energy storage and return device, may be made of a variety of components including more than one spring element. The spring 110 exhibits a reducing spring force for all or part of its compression displacement and is placed in the shoe sole 102 under the heel of the foot. In some embodiments, one or more springs 110 may be placed in the forefoot 106. During compression, the spring 110 exerts a greater vertical force part way through its compression than it does at or near full compression. At the maximum force position (preferably approximately ⅔rds of the way through the compression displacement or range of travel, but other points in the compression will also work) it is preferable that the spring 110 exerts a vertical force of between 50% and 80% of the total weight of the user. At the maximum force position, the spring constant is zero. When fully compressed, the maximum force of this component is preferably between 20% and 40% of the user's weight. These percentages do not need to be precise for good performance, and it has been found by testing that one spring provides good performance for a wide range of user weights. These are the preferred forces for maximum energy return for a walking shoe. Higher percentages are preferred for a running specific shoe, and lower percentages are preferred for a lower performance shoe that is intended to provide less energy return function such as in a less expensive shoe. There may also be certain applications where the maximum compression force is preferably higher than 60% and the full compression force is lower than 30%. There may also be applications where the maximum compression force is preferably lower than 60% and the full compression force is higher than 30%.
The preferred percentages of user body weight in the previous paragraph are the preferred percentages for a walking shoe. Different variations of the maximum and full compression forces are possible in a device that provides a spring force which increases for the first portion of the compression displacement and then decreases for the next portion of the compression. The spring 110 may also (by itself or in combination with one or more members) provide an increasing spring force again at full compression. This would happen over a relatively short compression displacement and would act as a “bottom out bumper” to prevent unwanted impact at full compression.
Several examples of construction methods for the spring 110 are described. The spring 110, if used only by itself, would compress past the maximum force position with approximately 60% the weight of the user, such as with slightly more weight than when the user is standing with all of his or her weight distributed equally on both heels. The spring 110 may fully compress with a greater or lesser proportion of the user's weight, but it is the belief of the inventors that approximately 60% of the weight of the user is the ideal spring force of this component at the maximum compression position for a walking shoe. The force of the spring 110 at full compression (preferably with a range of travel in the range of 5 mm to 20 mm, but more or less compression travel can also be used in some embodiments) is preferably approximately 30% of the weight of the user.
The purpose of the spring 110 is to allow full or nearly full compression of the shoe sole 102 during the foot strike (initial contact of foot to the ground) phase of each step, and for the spring 110 to stay compressed until the user's center of gravity is forward or nearly forward of the user's heel and/or ankle position before the heel starts to unweight and lift. As the user begins to unweight the heel (
In some embodiments, a damper 114 is used which functions as an energy dissipation material and may be made of one or more components. The damper 114 is also placed in the heel 104 of the shoe sole 102 under the heel of the foot (and in some embodiments may be placed under the forefoot instead or as well). The damper 114 is designed to provide resistance to compression of the shoe sole 102 for the portion of the user's mass and inertia which is not effectively opposed by the energy storage and return spring 110. The damper 114 is biased so that it acts only or primarily during the compression phase of the shoe sole compression and rebound. During the rebound phase, the combination of the spring 110 and damper 114 allows the damper 114 to return to its original shape more slowly, quickly enough so it is available to dissipate energy during the next foot strike, but not as quickly as the spring 110 expands when the user heel begins to lift. This can be accomplished, for example with Sorbothane™ material manufactured by Sorbothane Incorporated, of Kent, Ohio, USA by permanently connecting a compression member of Sorbothane™ material to the shoe sole 102 (or spring) only at the top or the bottom of the Sorbothane™ component. The other end of the damper 114 is in contact with the shoe sole 102 during all or part of the compression phase, but it is allowed to not contact during the expansion phase of the sole 102 so it does not detract from the energy which is being returned to the user by the spring 110.
In this way, the foot strike phase will cause the spring 110 as well as the damper 114 to compress with a similar increase of force as a conventional linear or increasing rate spring which is capable of decelerating the entire mass of the user without bottoming out harshly. A conventional rate spring would return much of this compression energy (by expanding again) before the user's center of gravity is forward of the user's heel. With shoe 100, however, the damper 114 does not add to the rebound energy (or frequency) because it only significantly acts to slow the compression. The effect is to store a significant portion of the foot strike energy in the spring 110, and to provide a suitable rate of deceleration with the damper 114, and then to return energy which is stored in the spring 110 to the user once the user's center of gravity is forward or nearly forward of the user's heel. In other words, the effect of the combination of these materials to the user is the feeling of the two components (the spring 110 and the damper 114) working together to provide enough compression force and/or resistance to gradually decelerate the mass of the user during the foot strike phase of each step. When the user's center of gravity has moved forward or nearly forward of the user's heel and the user begins to unweight their heel as shown in
Another embodiment of the damper 114 which would provide a high degree of energy dissipation is shown in
In this configuration of
During compression, restriction is preferably provided primarily by the compressible foam member 306 which is adhered to the bottom of the air chamber. This member is preferably open celled foam but can be closed cell for example if it has an air permeable top surface (an open-celled foam with an air permeable top surface can also be used and may even pre preferable for long term function). As the foam compresses, it becomes more dense and the resistance to airflow increases. If it is a closed cell foam, the top surface contact pressure against the orifice region increases with compression and the air permeable top layer increases the air flow resistance. Either way, the air flow resistance increases as the disk compresses, providing a progressively increasing damping effect with compression.
The compressible foam 306 is preferably an open-cell structure with a visco-elastic property which causes the foam to stay compressed momentarily as the disk expands. This allows the air flow restriction to be minimized during expansion of the spring, biasing the damping to compression only. The foam preferably expands quickly enough to be back to near its original shape before the next foot-strike.
The orifice 308 can also be in the bottom seal member (top and bottom as used throughout this disclosure in relation to the spring itself being for discussion sake only—the disk could be used inverted in a shoe) with the foam being adhered to the conical disk instead. The memory foam can be in contact with orifice initially or not (as shown in
Another design for the biased air damper, as shown in
This configuration of a damper integrates a one-way seal and a pressure modulated air resistance as follows: As the disk compresses, the increasing air pressure, acting on the flexible diaphragm 314 compresses the resistor 316 to provide increased air damping during higher velocity compression as the air flows through the resistor material from diaphragm hole/s 318 to bottom seal hole/s 320. The air pressure also decreases as the compression slows down near full compression, as the user's mass is decelerated. This allows the resistor to uncompress and reduce the air flow resistance so the air can be exhausted at full compression without causing an air spring effect, in order to bring the user's mass to a complete downward stop with as little rebound as possible. As the disk rebounds, the flexible diaphragm 314 lifts and allows free flow of air back into the chamber. The resistor 316 may optionally have a hole, preferably concentric with the hole/s in the diaphragm 314, or with the hole/s in the bottom sealing member 186, to allow unrestricted air flow during spring extension.
A compressible secondary sealing/air-flow-resistance member 322 can be used to further increase air flow resistance, or even seal the chamber completely, at nearly full compression to reduce the impact of a full compression movement.
The graphs of
The conical disk 130 and ring 136 is a preferred embodiment of an energy storage and return component. Many other configurations are possible. The slots 134 allow the conical disk 130 to expand circumferentially with little stress on the material of the conical disk 130. When not assembled with the outer ring 136, the conical disk 130 may be compressed into a flat shape with significantly less force than when it is assembled to the ring 136. The conical disk 130 may be made of polypropylene or other negative Poisson's ratio material or other suitable materials such as metals or plastics. If the conical disk 130 is made of a metallic material or a rigid plastic, that is, excluding polypropylene or other negative Poisson's ratio materials, there may need to be continuations E of the slots to the interior edge 138 of the conical disk 130 to allow the disk 130 to flatten without damage to the material of the disk 130. The interior edge 138 of the conical disk 130 forms a circular hinge about which the sides 132 of the conical disk 130 flex. A negative Poisson's ratio material such as, but not limited to, polypropylene may be used without the slots extending to the center because it can act like a live hinge in high strain areas. In some embodiments, slots extending to the center may be contacting, such as with intentional crack lines or ball and socket pivots to prevent the inner ring from closing in/decreasing in radius during compression of the spring.
When the conical disk 130 is flattened due to a vertical compressive force exerted on the apex D, energy is stored in the outer ring 136 as the ring 136 stretches radially and circumferentially. As the conical disk 130 flattens, the mechanical advantage of the disk on the outer ring increases significantly, and the vertical force of the conical disk 130 reaches a position where it begins to decrease. The outer ring may be made of plastic, such as polycarbonate or a material such as Delrin™ high performance acetal resin copolymer or homopolymer by Dupont, which have a high elongation property and good fatigue life.
An example of the conical disk 130 may be constructed for a 100 kg person with the following dimensions, materials and spring rate: Vertical displacement to maximum force—7 mm Maximum force at this position—60 kg Total maximum vertical displacement—10 mm Force at this position—30 kg Outer diameter of assembly—75 mm. The conical disk 130 may include a damper 114 (not shown in
In another embodiment, one or more additional disks can be used to provide the damping force. The second disk can be secured to the main disk as shown in
Other benefits of the conical disk 130 include the lateral stability which can be achieved. Even though the conical disk 130 allows high travel, it allows the shoe sole 102 to compress in a well defined vertical motion. For this to be effective, the top and bottom of the conical disk 130 need to be secured to upper surface 102A and lower surface 102B to prevent lateral movement. The disk 130 may also be adjusted forward and backward and side to side (such as, for example, with an eccentric cam) to compensate for pronation or supination, or to adjust the for and aft position of the disk under the heel. Many different configurations, material combinations and geometries of the conical disk are possible.
There may be a flexible seal around the disk compartment between the upper and lower sole to keep the disk protected from dirt etc. This may be formed for example of a very light foam that completely encases the disk, or a flexible film or bladder made of a flexible solid material or foam material. This seal material will ideally not add significantly to the spring rate of the shoe sole.
A further simplified embodiment of a spring 110 is shown in
An ideal amount of force required to compress the conical disk member 182 on its own to full or nearly full compression is approximately between 10% to 50% of the maximum force required to compress the conical disk 182 when it is assembled together with the ring spring 184. Ideally, the conical disk 182 and spring 184 are constructed to allow the conical disk 182 to be nearly flat at full compression. This allows the disk spring 184 to be at maximum elongation without exerting a significant vertical force through the conical disk 182. Some vertical force is preferred, however, and this can be provided by the conical disk member 182 which resists being flattened. Other materials may be used, but a polypropylene or other negative Poisson's ratio material is a preferred material for the conical disk 182 because it allows the high strain areas to become living hinges. The radial slots 188, or other shapes which allow circumferential expansion (not shown), are designed to be high strain areas which allow the conical disk member 182 to be deformed from a conical shape to a more planar shape.
By using blind slots 188 (from the top, as shown at 188A, or from the bottom, or from the top and bottom) as opposed to through slots, the conical disk 182, in combination with the ring spring 184 and possibly a separate base member 186, is able to provide a sealed air chamber 185 as it compresses. The slots 188 may also be sealed by a membrane on the inside of the disk 182. During compression, the air in the sealed chamber 185 is compressed to an elevated pressure and is forced to escape through a restriction such as, but not limited to, an orifice or orifices 187 or a porous material (not shown). This provides a compact and light weight method of dissipating a portion of the compression energy. At full compression, most of the air in the chamber 185 will have been discharged through the restriction 187 so that it will have absorbed the impact of the foot strike. Once the mass of the user has been decelerated by the combination of the disk force and the damping force of air exiting the chamber 185, the air (which has now been discharged from the air chamber) will no longer contribute to the vertical force of the disk on the user's foot. This allows the disk 182 to stay compressed until the user begins to unweight their heel (as their center of gravity moves forward of their ankle) and the disk 182 will then expand vertically and propel the user forward. As the disk 182 expands to its original shape, one or more valved air flow openings 189 in the base member 186 in a flexible one-way valve member 189A seated in the base member 186 allow unrestricted air to re-enter the chamber. The openings 189 are sealed during compression of the disk 182 by the flexible one-way valve member 189A. During expansion, some restriction in the flow of air through the openings 189 may be desirable in some applications to slow the energy return slightly. Areas 189B may be used as attachment points to hold the seal 189A on the bottom 186 of the disk 180, for example by welding or adhesive.
Other possible features of this embodiment include an eccentric locator 183 on the top and bottom of the disk with a detent positioning system (using flexible protrusion 181 as a detent) to allow the disk 182 to be fine tuned from side to side to compensate for pronation or supination. The locating eccentric 183 on the bottom may also have a quick-release engagement system which allows the disk to be removed or inserted (by turning the disk to a non-detent position) but holds it securely when in any of the detent positions. Adjustable valving of the openings 189 and restriction 187 can also be used to control the air flow in and out of the damping chamber 185.
The air flow from the chamber of a sealed conical disk 182 may be modulated by a computer controlled valve which adjusts for various user and terrain variables. A simple but effective self-adjusting airflow resistance system is shown in
In
Further embodiments of a spring 110 are shown in
In a further embodiment, a spring 110 is formed using an air diaphragm system. An embodiment of an air diaphragm system 210 is illustrated in
The spring air diaphragm system 210 uses the vertically downward energy from the foot strike to force a portion of the air in diaphragm 220 into the air reservoir 222 through conduit 224 and one way valve 226. As a result, a portion of the energy which the user applies to compress the air diaphragm 220 is contained and stored in the air reservoir 222 and the the now deflated air diaphragm 220 remains at this lower volume until return valve 236 is activated. As the user's center of gravity moves forward of the user's ankle (this example takes place on a flat surface, for simplicity of explanation) the pressure in the air diaphragm 220 will start to drop rapidly as a result of the user's weight rolling forward and off of the heel. When the pressure in the air diaphragm 220 becomes significantly lower than the elevated pressure in the air reservoir 222, the return valve 236 opens and the elevated pressure air in the air reservoir 222 rushes back into the air diaphragm 220, creating a vertical force which propels the user with an upward force having a forward component.
The design of return valve 236 is a critical element of the air diaphragm spring system 210. Ideally it is designed to seal completely until the pressure in the air diaphragm 220 reaches a certain percentage of the pressure in the air reservoir 222 (such as 60%, but higher and lower may work as well depending on various other design considerations). When the return valve opens, it creates very little resistance to flow until the pressure in the air diaphragm 220 and the air reservoir 222 have equalized. When this has happened, the valve 236 closes again.
A preferred construction of such a valve 236 is shown in
The valve sealing element 238 may be a rigid or semi rigid disk or cylinder with a flat end with a significantly larger sealed diameter than the hole it seals from the reservoir 222 to the diaphragm 220.
The sealing surface of the return valve 236 is preferably flat, but may also be conical or some other shape. Many different spring and flow configurations are possible, which use a similar surface area differential. A pre-set or adjustable flow resistance mechanism may be used which will increase the resistance of the flow enough to prevent the diaphragm to re-inflate too rapidly.
In some embodiments, it may be desirable to have airflow resistance change depending on how much pressure is in the system or how fast the air is flowing from reservoir 222 to the diaphragm 220. This may be accomplished a number of different ways including an airflow path which is turbulent enough that higher flow rates create significantly higher flow resistance, or a construction where high flow rates actually reduce the resistance of the air flow so more air is transferred faster.
An optional but preferred element of the diaphragm spring 210 is a full compression air pump 246 under the heel of the shoe 211. The full compression air pump 246 increases the pressure of the entire system by adding atmospheric air (other compressible gases may also be used, but air is preferred because it can be supplied by and vented to atmosphere) to the diaphragm 220 and/or to the air reservoir 222 any time the air diaphragm 220 reaches full compression. There may be more than one diaphragm 220 and reservoir 222 in a spring shoe. The air pump 246 allows the shoe to self adjust for various user weights and for when the user is walking or running etc.
A preferred design goal, for foot wear incorporating a spring 110, is to use as much of the available “travel” as possible at all times, whether the user is walking, running or jogging etc. If a full compression air pump is used, a method of reducing the air pressure such as a vent valve (not shown) may be provided when the user is no longer running (for example) and is no longer using the full “travel’ of the diaphragm. In this case it is necessary to bleed off enough air to the atmosphere until the user is once again compressing the diaphragm 220 completely. This can be accomplished by a constant bleed system, but is preferably accomplished with an electronically activated miniature valve which is controlled by a CPU. The CPU will detect that full compression is no longer happening and will open the vent valve to reduce the system pressure. This sensing can be done a number of different ways including with a contact or proximity sensor between the bottom of the reservoir and the top of the reservoir, or by a pressure sensor in the soul, or by sensing whether or not there is airflow from the pump, or by sensing whether the one-way valve from the pump to the reservoir and/or the diaphragm is activated on each step.
In this way, the foot strike shock is very effectively dissipated, and energy is stored for release until the user begins to un-weight their heel. In actuality, the ideal release of the air pressure from the reservoir 222 to the diaphragm 220 may begin before the user's center of gravity is forward of the heal, as long as there is a momentary delay, and as long as a portion of the energy which has been stored in the reservoir is released after the user's center of gravity is forward of the ankle.
The intake for the atmospheric air pump 246 should be filtered, preferably through a relatively large surface area of waterproof/air-permeable material such as Gortex™ fabric by Dupont, to prevent any foreign matter such as dust or water from entering the system. This filter (or membrane) is preferably of a large enough surface area (for example as a panel on the outside of the shoe) to allow sufficient air flow for the highest air flow which the pump 246 will generate during use. Similarly, a filter of some sort, such as venting air to the inside of the shoe and drawing it back in through a filter, should be used for an air sealed embodiment disc as for example shown in
Diaphragm 220 may be of many different shapes and sizes, and may also be used under the forefoot. The diaphragm 220 may be of a flexible, expandable material, but is preferably a flexible, non-elastic material, such as a fabric reinforced rubber or elastomer, so as little compression energy as possible is stored in the stretching of the diaphragm. Instead, as much energy as possible is preferably stored in the elevated pressure reservoir 222.
The elevated pressure reservoir 222 may be of many different shapes and sizes and preferably of a rigid or semi-rigid material but possibly even a flexible/expandable material(s). It would preferably have a volume which is similar to or smaller than the air volume of the diaphragm 220 which are linked to it. The ideal volume may be determined by testing.
The elevated pressure reservoir 222 may also be integrated into the shoe upper 214 or sole 212 by using small diameter (preferably ⅛″ ID but larger or smaller is possible) tube which is molded or bonded into the soul or integrated into the upper by stitching or bonding or other method. Such a tubing reservoir could be mounted anywhere on the shoe 211, but would preferably wrap around the outer upper edge of the sole 212 and be long enough to contain the required volume for the desired energy storage characteristics. The air reservoir 222 can also be located under the forefoot as part of the shoe sole 212.
The one-way valve 226 may be of a ball type or a flap type or any other type of one-way valve configuration. It is also preferable to have a preset, or adjustable flow mechanism which will increase the resistance of the flow enough to prevent the diaphragm from reaching full compression before the user's energy has been completely stored (or in other words, to keep the “suspension” from “bottoming out”).
It may be desirable for this airflow resistance to change depending on how much pressure is in the system or how fast the air is flowing from the diaphragm 220 to the reservoir 222. Ideally, the airflow will be fast enough to use the entire travel on each foot strike, but slow enough to prevent the diaphragm 220 from compressing too rapidly in the case of sudden high flow rates. This may be accomplished a number of different ways including an airflow path which is turbulent enough that higher flow rates create significantly higher flow resistance.
The vent valve (not shown) is used to reduce the system pressure any time higher pressure is no longer necessary. Many different types of valves may be used, such as the “X-valve” by Parker Hannifin, or possibly a miniature piezo-electric valve. The valve can reduce the system pressure over a duration of several user steps or more, and does not, therefore, need to be very high flow.
A simple delayed opening return valve has been presented. Other methods with active electronically controlled valves or different pressure sensors to indicate the correct timing of energy release may also be used.
Instead of venting or drawing air from the atmosphere, it may be preferable for certain applications to use a sealed, closed system using a fluid or fluids other than air. With this arrangement it would also be possible to use other gases such as nitrogen. Other energy storage systems may be used such as the movement of a noncompressible fluid which is used to compress a mechanical spring or pressurized gas or expand a flexible chamber.
Referring to
All of the devices and embodiments and possible variations (mentioned here or discussed, but not described in detail etc) may be used in combination with other shoe sole structures and devices such as air bladders, foam materials etc.
A lightweight, low profile reducing force spring may have value for many other applications beside shoes.
All of these examples may include a combination of different materials with different properties, or they may include components or members of the same material in various thicknesses and cross sections to produce different rigidity and extensibility characteristics. For example, a semi-rigid material could be used for the rigid compression load members as well as the extensible elastic members, if the elastically extensible section is constructed as a waved or bellows type of cross section, so it can be extended with primarily bending deformation of the material.
The rigid member in this disclosure refers to members which are rigid enough to withstand the compression load required to stretch the extensible member, without the compression load member buckling or bending significantly except as necessary, by design, to maintain the required force transfer from the foot strike to the extensible member.
Exemplary materials for the rigid or semi-rigid compression load members of the spring 110 include polypropylene or some other negative Poisson's ratio material, Delrin™ acetal resin, an injection moldable fiber reinforced nylon, or they may be metallic or other type of plastic or fiber reinforced composite. Material for the elastically extensible component/s is preferably Delrin™ acetal resin, but may be made of other types of plastics or metals or composites.
All of these systems may be sold with the option of various spring modules or elastic member stiffnesses to suit various users weights and uses and styles of walking or running. The speed of the energy release may also be controlled by the visco-elasticity of the extensible material. Lower visco-elastic properties may be preferable for high performance athletic footwear, while higher visco-elastic properties may be beneficial for shock absorption and consistent feel for more “pedestrian” applications.
Many people buy different types of shoes for different uses such as walking or running. The ideal starting point for a user to determine the spring stiffness for a particular pair of shoes for walking, is to choose a spring which just barely compresses completely with all of the users weight on one heel. This way, the weight of walking will compress the shoe sole. For running and jogging, a stiffer spring will likely be better suited. Spring shoes may also be particularly useful for high impact sports such as skateboarding. These applications may use stiffer springs than for running or jogging. In some cases, energy return may not be a benefit and can be minimized or eliminated, but the energy dissipation and lateral stability can be maximized for injury prevention.
Many other sole constructions are possible which exhibit a decreasing force spring for all or part of the compression of the heel and/or other portions of the sole. The methods described here are given as the preferred examples of decreasing force spring systems in terms of characteristics such as simplicity and cost. It is envisioned by the inventor that the entire sole could be molded or constructed with all or part of the sole having a decreasing force spring characteristic for all or part of the compression displacement. The spring 110 could also be used under other parts of the foot, such as the ball of the foot, to increase speed, efficiency and comfort of walking and/or running. Configurations of one or more embodiments of the invention may also be used in a multiple array or pattern of springs in a shoe sole.
Other benefits such as improved shock absorption due to a delayed rebound response, are also known to be a benefit of the spring 110.
The examples given are intended to show a variety of configurations of the spring 110. Other variations are not limited to, but include, right side up and/or upside down disk/s, non-perfect/symmetrical conical disks and/or non-circular ring springs, various materials including metallic conical disks or metallic ring springs, stacks of right side up and/or upside down disks for greater compression travel, and a separate damper component (such as but not limited to an air diaphragm/s) that is inside the disk/s or outside the disk/s, or enveloping the disk/s. Any or all of the embodiments disclosed here can be used in combination with one or more other energy storage and return components and/or energy dissipation components of the same or different design. Energy storage and return devices, preferably combined with one-way energy dissipation devices can be used in the heel and/or the forefoot of a human shoe. Variations of the energy storage and return devices and/or energy dissipation devices can also be used in specialty shoes such as dress shoes or high heeled shoes to provide similar benefits as when used in a walking, running, or sports shoe. Variations of the devices disclosed in this provisional can also be used in non-shoe related applications such as sporting goods or industrial mechanisms which require, for example, a decreasing spring force. One of many possible examples would be the use of a decreasing spring force component according to an embodiment of the present invention to provide an increasing/decreasing spring rate to tension an archery bow string. This would simplify the present pulley system that is used in compound bows. Many other applications for the present invention such as, but not limited to suspension system components and variable spring actuators for various linkage systems are conceivable.
In the claims, the word “comprising” is used in its inclusive sense and does not exclude other elements being present. The indefinite article “a” before a claim feature does not exclude more than one of the feature being present. Each one of the individual features described here may be used in one or more embodiments and is not, by virtue only of being described here, to be construed as essential to all embodiments as defined by the claims.
Immaterial modifications may be made to the embodiments described here without departing from what is covered by the claims.
This application claims the benefit under 35 USC 119(e) of provisional patent applications Nos. 60/970,263; 60/992,920; 61/016,555; 61/016,558 and 61/024,898 filed Sep. 6, 2007; Dec. 6, 2007; Dec. 24, 2007; Dec. 24, 2007; and Jan. 30, 2008 respectively.
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