This invention relates to an attachment system for attaching an item of footwear such as a standard walking or hiking boot or shoe for example to sports equipment such as a ski, snowboard, ice skate, inline skate or roller skate.
Footwear for sports such as skiing, snowboarding, mountaineering, or skating, is sport specific. Typically footwear for these sports is heavy, bulky, rigid and difficult to walk in, and only suitable for use in specific sporting applications.
For example, ski and mountaineering boots are typically made of stiff plastic to support the ankle and lower leg. Ski boots are designed for high lateral stiffness for precision and responsiveness when skiing, and mountaineering boots are stiff to facilitate crampon attachment and use. However, such stiff boots are difficult to walk in, heavy, and bulky, so mountaineers typically carry separate approach boots or shoes.
Snowboarding bindings typically use a support that encloses a boot with a soft upper. The support has a stiff base-plate which continues up the back of the ankle and lower leg to rigidly support the soft boot. Snowboarding boots may be stiff or flexible and are bulky so do not facilitate walking more than a short distance, or walking over steep or uneven terrain. Snow board boots and bindings are also heavy and bulky.
Ski-mountaineering and back-country or cross-country skiing combine the sport of skiing with hiking, trekking or mountaineering. In these pursuits, the skier needs to walk or climb to gain altitude without the assistance of chair lifts or tow ropes, and some travel, especially in an approach to a climb, may be over terrain that is not snow covered.
When a back-country skier or mountaineer reaches terrain that can't be traversed on skis, they must remove their skis and traverse that terrain by foot. If the terrain is covered by hard snow or ice, the skier will swap their skis for crampons. This typically involves removing their backpack, and sitting down to attach the crampons to their boots. If the slope is steep and icy, it may be difficult to find a safe place to do this, and a backpack resting on a sloped surface of hard snow or ice is at risk of sliding down the slope. Additionally, when the skier first steps out of their skis, the skier is at risk of slipping until they have fitted crampons.
By nature, ski-mountaineering and back-country skiing trips typically take place in remote, unpatrolled areas and may be multi-day trips, requiring the skier to carry camping gear in addition to equipment such as avalanche rescue gear and survival gear. Therefore, light weight compact gear is highly desirable in these pursuits.
Existing exoskeletons for attaching boots or other footwear to sporting equipment typically have rigid bases so are not suitable for walking. U.S. Pat. No. 6,691,434 describes an exoskeleton design having a rigid base. The rigidity of that system also relies on bracing extending up the back of the leg which makes the system bulky and heavy. Additionally, the system is designed to provide lateral tilting movement/tilting of the boot, which is undesirable for good ski control.
U.S. Pat. No. 5,815,953 and U.S. Pat. No. 4,955,149 also describe brace systems for attaching a walking boot to skis. Both of these systems have rigid soles with a hinge behind the heel to allow some ankle movement. Transverse, flexible straps secure the boot in place but provide little or no lateral stiffness. US 2008/047168 describes a brace that allows some flexure of the foot through the use of an underfoot hinge. This system is permanently secured to the item of sporting equipment and has no straps to retain a boot or shoe in place or to prevent movement of the footwear relative to the brace. This brace provides very little lateral support for the foot.
U.S. Pat. No. 5,823,563 describes a method of attaching ‘crampons’ to the front part of a ski boot and mounting the boot and crampon arrangement to skis. This system requires ski boots and is not suitable for use with standard walking boots. Additionally the ‘crampons’ in this system are only under the front part of the boot, and only have underfoot points with no heel or front points. Therefore, they would be of little practical use on hard snow or ice.
There is a need for an exoskeleton for attaching standard walking or hiking boots or shoes to sports equipment in a way that provides the necessary rigidity to the foot for the sporting pursuit, so a user can wear the same footwear for walking and with the sports equipment. It is desirable for such an attachment to be lightweight and easily dismantled or collapsed for storage or transport.
In this specification where reference has been made to patent specifications, other external documents, or other sources of information, this is generally for the purpose of providing a context for discussing the features of the invention. Unless specifically stated otherwise, reference to such external documents or such sources of information is not to be construed as an admission that such documents or such sources of information, in any jurisdiction, are prior art or form part of the common general knowledge in the art.
It is an object of at least preferred embodiments of the present invention to provide an improved apparatus for attaching an item of footwear to sports equipment, or to at least provide the public with a useful choice.
In a first aspect of the invention an exoskeleton is provided for connecting an item of footwear to sporting equipment. The exoskeleton comprises: an underfoot base; an ankle cuff connected to a heel portion of the underfoot base; a first restraining brace having an anterior end connected to the medial side of a forefoot portion of the underfoot base, and extending rearwardly and diagonally at least to the lateral side of the ankle cuff to provide lateral support to the ankle cuff; and a second restraining brace having an anterior end connected to the lateral side of the forefoot portion of the underfoot base, and extending rearwardly and diagonally at least to the medial side of the ankle cuff to provide medial support to the ankle cuff. The first and second restraining braces are configured such that when an item of footwear is enclosed by the exoskeleton, the restraining braces extend over and support a portion of the item of footwear.
In an embodiment of the invention, the first and second restraining braces are sufficiently stiff to hold their shape in the absence of an external force. The first and second restraining braces may be substantially rigid.
In an embodiment of the invention, the first restraining brace comprises a posterior end positioned adjacent the lateral side of the ankle cuff, and the second restraining brace comprises a posterior end positioned adjacent the medial side of the ankle cuff. The exoskeleton may further comprise a restraining brace connector configured to extend behind the ankle cuff to operatively and detachably connect the posterior end of the first restraining brace to the posterior end of the second restraining brace. The restraining brace connector may be adjustable. For example, the restraining brace connector may be a ratchet strap arrangement.
The first restraining brace and the posterior end of the second restraining brace may be operatively and detachably connected to the ankle cuff and/or pivotally connected to the underfoot base. In an embodiment, the first and second restraining braces are removably connected to the underfoot base.
In an embodiment, the restraining braces comprise carbon fibre. The restraining braces may comprise a stiff or rigid material and a flexible material arranged so that if the stiff or rigid material undergoes a failure, the flexible material will keep the fractured parts connected.
The ankle cuff may be pivotally connected to the underfoot base and is preferably removably connected to the underfoot base. In an embodiment, the ankle cuff has a rear heel cut-out. The ankle cuff may comprise a relatively flexible posterior portion and relatively stiff lateral and medial portions.
In an embodiment of the invention the exoskeleton further comprises an adjustable cuff fastener connected to the ankle cuff, for securing the ankle cuff around the ankle of an item of footwear or around a user's lower leg enclosed in the exoskeleton. The adjustable cuff fastener may be a ratchet strap arrangement or other adjustable fastener or tie.
In an embodiment, the underfoot base has the form of a crampon. The base may comprise at least one crampon point at a periphery of the heel portion of the underfoot base and/or at least four crampon points disposed at the forefoot portion of the underfoot base. The base may optionally comprise at least two crampon points at each of a medial and lateral periphery of the forefoot portion of the underfoot base.
The ankle cuff and/or the restraining braces may further comprise connectors fixed to ends of the ankle cuff/restraining braces, for connecting the ankle cuff/restraining braces to the underfoot base. The connectors may comprise plates which form crampon points.
In an embodiment, the heel portion and the forefoot portion of the underfoot base are substantially rigid and connected by a relatively flexible mid-foot portion to allow vertical motion of the heel portion relative to the forefoot portion.
The exoskeleton may further comprise a flexible heel retaining strap and a flexible toe retaining strap.
The exoskeleton may further comprise an engagement feature for connecting the exoskeleton to an item of sporting equipment.
In a second aspect of the present invention there is provided a footwear attachment system for attaching an item of footwear to an item of sporting equipment. The system comprises: an exoskeleton as outlined above with respect to the first aspect and comprising an engagement feature for connecting the base to an item of sporting equipment; and a toe latch assembly attached to an item of sporting equipment, the toe latch assembly comprising at least one latch suitable for engaging the engagement feature on the exoskeleton.
In an embodiment of the invention, the latch and engagement feature are engaged, and the engagement forms a pivot for the exoskeleton so that the heel portion of the underfoot base is movable up and down with respect to the item of sporting equipment.
The attachment system may further comprise a secondary engagement feature on the forefoot portion of the underfoot base and a complementary secondary engagement feature on the toe latch assembly, wherein the complementary secondary engagement features are selectively engageable with each other to prevent the exoskeleton pivoting relative to the toe latch assembly.
In an embodiment, the base has the form of a crampon. The secondary engagement feature on the forefoot portion of the underfoot base may be provided in a crampon point.
The system may further comprise a heel latch assembly attached to the item of sporting equipment, wherein the heel latch assembly is selectively engageable with a heel engagement feature on the heel portion of the underfoot base.
In an embodiment, the pivot is positioned so that when a user's foot is secured in the system the pivot is under the user's big toe, providing a more natural walking movement than a pivot positioned forward of the toes.
The term “comprising” as used in this specification means “consisting at least in part of”. When interpreting statements in this specification and claims which include the term “comprising”, other features besides the features prefaced by this term in each statement can also be present. Related terms such as “comprise” and “comprised” are to be interpreted in a similar manner.
It is intended that reference to a range of numbers disclosed herein (for example, 1 to 10) also incorporates reference to all rational numbers within that range (for example, 1, 1.1, 2, 3, 3.9, 4, 5, 6, 6.5, 7, 8, 9 and 10) and also any range of rational numbers within that range (for example, 2 to 8, 1.5 to 5.5 and 3.1 to 4.7) and, therefore, all sub-ranges of all ranges expressly disclosed herein are hereby expressly disclosed. These are only examples of what is specifically intended and all possible combinations of numerical values between the lowest value and the highest value enumerated are to be considered to be expressly stated in this application in a similar manner.
To those skilled in the art to which the invention relates, many changes in construction and widely differing embodiments and applications of the invention will suggest themselves without departing from the scope of the invention as defined in the appended claims. The disclosures and the descriptions herein are purely illustrative and are not intended to be in any sense limiting.
Where specific integers are mentioned herein which have known equivalents in the art to which this invention relates, such known equivalents are deemed to be incorporated herein as if individually set forth.
As used herein the term “(s)” following a noun means the plural and/or singular form of that noun.
As used herein the term “and/or” means “and” or “or”, or where the context allows both.
The invention consists in the foregoing and also envisages constructions of which the following gives examples only.
The present invention will now be described by way of example only and with reference to the accompanying drawings in which:
In this description, the invention is described with reference to the attachment of walking boots to skis. It will be appreciated that other embodiments of this invention may similarly be used for attaching items of footwear such as boots or shoes to snowboards, ice skates, roller skates, inline skates, or other sporting equipment that is attached under a user's foot. Parts of the invention are described using the anatomical terms medial, lateral, anterior, posterior, superior and inferior, in reference to a user's foot or leg when the system is in use.
While the supporting figures and description relate to an apparatus for supporting a left-foot boot, it will be appreciated that the apparatus for supporting a right-foot boot will be provided with the same features, but in mirror image.
The exoskeleton E comprises first and second stiff restraining braces 2a, 2b, an ankle cuff 3, and a base 7. In the preferred embodiment the restraining braces 2a, 2b, ankle cuff 3, and base 7 are detachably coupled to each other. Alternatively, one or more of these pieces may be integral with another, for example the rigid restraining braces 2a, 2b may be a single component. In use, a user's boot is supported on top of the base 7, and the ankle cuff 3 and the restraining braces 2a, 2b fit over the boot to hold the boot and thereby a user's foot securely in place.
As shown in
In a preferred embodiment suitable for telemark skiing, the mid-foot portion may be made from plastic, for example 2 mm thick ultra high molecular weight polyethylene. For an embodiment suitable for downhill skiing the mid-foot portion could be relatively stiff, for example it may be made from aluminium. Alternatively, the mid portion may be substantially rigid.
In an alternative arrangement, the base 7 may be a single integrally formed component.
Each of the restraining braces 2a, 2b is an elongate strap-like member that has an anterior end 2a′, 2b′ and a posterior end 2a″, 2b″. The anterior end 2a′, 2b′ of each restraining brace is operatively connected to the forefoot portion 7a of the base member 7. The anterior end 2a′ of the first restraining brace 2a is operatively connected to the medial side of the forefoot plate 8, and the anterior end of the second restraining brace 2b is operatively connected to the lateral side of the forefoot plate 8. Preferably the restraining braces 2a, 2b are connected to the forefoot portion 7a at points directly below and to the sides of the ball of the user's foot when the system is in use. In an alternative embodiment, the connection points could be higher, but aligned with the ball of the user's foot in a longitudinal direction of the user's foot.
The restraining braces are preferably stiff or substantially rigid and shaped or moulded to fit over a walking or hiking boot 1. The braces 2a, 2b are shaped so they are curved around both their longitudinal and transverse axes in a generally helical manner, and extend diagonally rearwardly from their connection at the forefoot plate 8, over the top of the boot to the opposite side of the ankle, so that the first and second restraining braces crossing each other above the mid-part of the foot. By curving around both their longitudinal and transverse axes, the inner surface of each brace can stay in close proximity to, and preferably contact, the top of the item of footwear over a substantial part of their lengths.
The first restraining brace 2a extends rearwardly and diagonally from its anterior end to at least the lateral side of the ankle cuff 3 to provide lateral support to the ankle cuff, and thereby to a boot and a user's foot/lower leg when using the apparatus. The second restraining brace 2b extends rearwardly and diagonally from its anterior end to at least the medial side of the ankle cuff 3 to provide medial support to the ankle cuff, and thereby to a boot and a user's foot/lower leg when using the apparatus. The posterior end 2a″ of the first restraining brace 2a is positioned on the lateral side of the ankle brace 3 and the posterior end 2b″ of the second restraining brace 2b is positioned on the medial side of the ankle cuff 3 opposite the posterior end of the first restraining brace 2a and preferably in line with or slightly above a user's ankle bone (lateral and medial malleolus).
Preferably the restraining braces are made from a material with a high strength-to-weight ratio that is shapeable during manufacture, and that enables the braces to maintain their shapes (in the absence of an external force) when the boot is removed, and they are not easily substantially deformed by the application of external force. In a preferred embodiment, the restraining braces are carbon fibre. Alternatively the restraining braces could be an aramid fibre laminate, fibreglass, another composite, or a metal such as spring steel. In an embodiment having metal restraining braces, the restraining braces may have a plastic coating for comfort and corrosion and wear protection. Preferably the straps are made from a material having a Young's modulus over 100 GPa and/or have a theoretical (untwisted) cantilever stiffness greater than 500 Nm−1 and more preferably greater than 1500 Nm−1.
Preferably the rigid restraining braces 2a, 2b further comprise a flexible or ductile material. It would be undesirable for the restraining braces to undergo brittle failure, particularly at altitude on a mountain. Inclusion of a flexible component in the restraining braces would ensure that if the braces suffered a brittle fracture, they would still remain in one piece. For example, in a preferred embodiment the rigid restraining braces are made from tubular weave carbon fibre with a flexible core from a material such as polyolefin fibre, aramid fibre, or polypropylene fabric tape. A similar configuration could be used for the ankle cuff 3.
In a preferred embodiment, the posterior ends 2a″, 2b″ of the first and second restraining braces 2a, 2b are detachably connected to each other via an attachment system 4 comprising a fastener 4a and an adjustable strap 4b that extends behind the ankle cuff 3. The attachment system is preferably a ratchet-type system, with a first end of the strap 4b fixed to the posterior end 2b″ of the second restraining brace 2b and the ratchet fastener 4a attached to the posterior end 2a″ of the first restraining brace 2a, so the fastener 4a is positioned on the lateral side of the ankle and is easy to reach by the user. Alternatively, the attachment system may comprise a buckle and strap, a cord or tie system, or other adjustable connection means.
In an alternative embodiment, the posterior ends 2a″, 2b″ of the restraining braces may be attached to the ankle cuff.
In another alternative embodiment, the posterior ends 2a″, 2b″ of the restraining braces could be positioned further rearward, and could curve around and support the ankle cuff from behind.
The first and second restraining braces 2a, 2b may be connected to each other at the point where they cross over. This stops the restraining braces moving relative to each other, improving the rigidity of the system. In the embodiment shown in the accompanying drawings, a post 9 projects upward from the second restraining brace 2b and fits through a corresponding aperture in the first restraining brace 2a, which crosses over the top of the second restraining brace.
The ankle cuff 3 is a one piece member that encloses the ankle and lower leg portion of the boot 1. The ankle cuff is operatively connected to the heel portion 7b of the base assembly 7 via a lateral connection and a medial connection. In a preferred embodiment, the ankle cuff has a cut out 3a behind the heel and a cut out 3b at the rear of the cuff above the ankle, to permit free movement of the Achilles tendon and the calf muscle. These cut outs reduce the weight of the ankle cuff 3, and the lower cut out ensures the ankle cuff 3 can be made from a flat piece of material and still achieve a good fit around the boot. The cut out above the ankle may not be necessary for some types of skiing or sports, and the upper cut out will not be present if greater calf stability is required.
The ankle cuff is laterally stiff to resist medial and lateral bending of the lower leg or ankle and thereby provide medial and lateral support to the lower leg and ankle. The ankle cuff 3 may be entirely or partly rigid, but preferably has some flexibility in the transverse plane so it can bend and be tightened around a user's ankle.
In a preferred embodiment the ankle cuff 3 is made from carbon fibre. Alternatively the cuff could be made from plastic, preferably a thermoset plastic or a high molecular weight thermoplastic such as ultra high molecular weight polyethylene, or another composite material with a high stiffness to weight ratio. For comfort, the ankle cuff 3 may have padding, for example closed cell foam, attached to at least part of the inside of the ankle cuff where the cuff fits directly over the ankle or lower leg rather than over the boot or shoe. More padding would be necessary in an ankle cuff to be worn with shoes than one for use with boots, which may require no padding or only some padding at the top of the ankle cuff 3.
An upper portion 3c of the ankle cuff above the ankle has at least one fastening arrangement for securing the cuff around the user's lower leg or ankle. In a preferred embodiment, the fastening arrangement is a ratchet strap 5 arrangement comprising a strap 5a fixed to the medial side of the cuff 3 and a complimentary ratchet fastener 5b fixed to the lateral side of the cuff 3. The fastening arrangement can be tightened to compress the ankle cuff 3 around the lower leg. Depending on the height of the ankle cuff, multiple fastening arrangements may be used for a more secure fit and to reduce the tension on each fastener.
The overall effect of the rigid restraining braces 2a, 2b, ankle cuff 3, and base 7 is to provide a three-dimensional structure that resists lateral movement and flexing of the boot and foot and user's foot and ankle but allows controlled forward flexing of the boot and foot. The first and second substantially rigid restraining braces are shaped such that when a boot is enclosed by the exoskeleton, the substantially rigid restraining braces extend over and support a portion of the boot.
Flexible heel and toe straps may be used to help retain the boot 1 in the exoskeleton E and prevent the boot moving back or forward relative to the base assembly 7. In a preferred embodiment, a flexible retaining heel strap 17 is attached to an inferior part of the ankle cuff 3 on either side, near where the ankle cuff is connected to the base assembly 7. The flexible retaining heel strap 17 extends around behind the heel of the boot and prevents the boot 1 from overextending backward and distorting the back of the boot. In a preferred embodiment, a flexible retaining toe strap 6 is attached to the medial and lateral sides of the forefoot portion of the base by fasteners 21. A longitudinally extending retaining strap 6b connects the toe straps 6 at point 6a and to the rigid restraining braces 2a, 2b at the point where they cross. In the embodiment shown, the additional retaining strap 6b connects to the post 9 on the second restraining brace 2b.
Alternatively, the base assembly may be configured to fit hiking or trekking boots having heel and toe welts. In place of the flexible retaining heel and/or toe straps, the base assembly 1 could have a heel clamp and toe bail to engage with welts on the boot.
In a preferred embodiment, the ankle cuff 3 and the restraining braces 2a, 2b are connected to the base 7 via metal plates 10a, 10b, 14a, 14b, riveted to the respective ankle cuff or restraining brace. These metal plates strengthen the ankle cuff 3 and restraining braces 2 in the high stress areas where they are connected to the base 7.
In a preferred embodiment the base 7 of the exoskeleton E functions as a crampon when it is not attached to the ski via the toe latch assembly TLA. The heel plate 13 has at least one downwardly extending sharp projection 13a at its periphery. Each of the medial and lateral sides of the fore foot plate 8 has multiple downwardly extending sharp projections 8a, 8b, 8c, 8d and optionally the forefoot plate 8 may have front downwardly extending sharp projections. In the embodiment shown, the metal plates 10a, 10b, 14a, 14b on the ankle cuff 3 and the restraining braces 2a, 2b are shaped to form crampon points when the ankle cuff 3 and the restraining braces 2a, 2b are operably connected to the base 7.
In a preferred embodiment, the metal end plates 10a, 10b, fixed to the rigid restraining braces 2a, 2b, are pivotally mountable on the shank 11a of the half turn connectors 11 via a bush 12. This arrangement pivotally attaches the braces 2a to the forefoot portion 7a of the base 7. The metal end plates 10a, 10b have an aperture comprising an opening 10a with a diameter to fit the bush 12, and a rectangular slot 10b to fit the head of the half turn connectors 11. The end plates (and therefore the rigid restraining straps 2a, 2b) are removable from and connectable to the base assembly 7 by rotating the end plates 10a, 10b so the rectangular slot 10b aligns with the head 11b of the respective half turn connector 11, and sliding the endplate on or off the shank 11a and bush 12. The slot is oriented so it forms an angle with the head of the half turn connector 11 when the respective rigid restraining strap is positioned over a boot enclosed by the exoskeleton. In the embodiment shown in the figures, the slot 10b is oriented so it forms an angle of about 60 degrees with the head of the half turn connector 11 when the respective rigid restraining strap is positioned over a boot enclosed by the exoskeleton.
A similar connection is used in the heel portion 7b of the base 7 for removably and pivotally connecting the ankle cuff 3 to the base, as shown in
As shown in
To disengage the latches 26a, 26b, a primary lever 30 rests on a resilient latch support 33 and is operably connected to the latches 26a, 26b via an axle assembly 35. When a downward force is applied to the end of the primary lever 33, the latches 26a, 26b are rotated, freeing the pivot bar 24 that is attached to forefoot plate 8.
A preferred embodiment of the toe latch assembly TLA further comprises a sliding latch 22 that can engage with a second engagement feature on the base 7. In the embodiment shown in the figures, a second engagement feature is provided by a hook 8e in rear crampon points of the forefoot plate 8. A secondary lever 31 is connected to the anterior end of lever 30. The secondary lever pivots about an axle 34 at its posterior end, between a substantially horizontal position and an upright position (shown in
When the secondary lever 31 is in the substantially horizontal position and the sliding latch 22 clears the hooks 8e in the forefoot plate, the forefoot plate will freely pivot relative to the item of sports equipment about pivot bar 24. This configuration is suitable for telemark skiing.
In an arrangement for telemark skiing, the design of the lever 30 and secondary lever 31 must provide space for the toe of the boot to rotate as shown in
Alternatively or additionally, an engagement feature could be provided in the heel portion of the base 7, and a corresponding heel latch assembly fixed to the sports equipment. This latch assembly could be selectively engageable to engage the heel for downhill skiing or to disengage the heel for telemark skiing.
Where an embodiment of the invention is configured for telemark skiing and the base 7 includes crampon points, any front crampon points need to be angled and of a length so that they don't contact the board when the heel is lifted and the base assembly pivoted about pivot bar 24. In the embodiment shown, the heel crampon points rest directly on the ski or sporting equipment, but preferably a block or support is fixed to the surface of the ski or sporting equipment to support the underside of the heel plate 13 above the surface of the ski to prevent the crampon points from contacting the surface. The heel block may be a commercially available heel block and may include a heel bail for changing the boot angle for skiing up hill.
The base assembly 7 may alternatively have no crampon points and alternative features would be provided in the heel and/or forefoot plates for engaging with a toe latch assembly TLA, and optionally a heel latch assembly. For example, for inline skating, crampons are unlikely to be useful.
In an alternative embodiment, a known engagement mechanism or assembly may be used for attaching the exoskeleton E to the ski, and the exoskeleton adapted to engage with that engagement mechanism or assembly.
In an alternative embodiment, the base 7 could alternatively be an integral part of the item of sporting equipment. In such an embodiment, for example for use with roller skates, the rigid restraining braces would connect directly to the sporting equipment and there would be no toe latch assembly TLA.
To use the invention, a user secures his or her boot 1 in the open exoskeleton shown in
To remove a boot, the exoskeleton E may be first disengaged from the toe latch assembly, TLA. In the embodiment shown, the latches 26a, 26b may be disengaged by applying downward pressure on primary lever 30. The user can then walk in the boot attached to the exoskeleton and crampon arrangement. The boot can be lifted out of the exoskeleton by releasing the ratchet straps 4, 5 and rotating the ankle cuff 3 and rigid restraining straps 2a, 2b away from the boot so the exoskeleton is in the open position of
Embodiments of the invention have been described by way of example only and modifications may be made thereto without departing from the scope of the invention without departing from the scope of the accompanying claims.
Number | Date | Country | |
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61471887 | Apr 2011 | US |