The present disclosure relates generally to systems and methods for supporting a load on a human frame, such as may be used with wearable ballistic body armor plates and accessories for military and law enforcement personnel, or other wearable load carrying harnesses used in firefighting, search and rescue, weighted exercises, infant carriage, etc.
When an individual carries a load, the load can cause a significant burden on the individual's body depending on the weight and how the load is distributed. For example, in military and certain law enforcement operations, personnel traditionally wear protective gear (e.g., flak jackets and/or ballistic plates) that protects the body from projectiles (e.g., bullets, shrapnel, and the like). The heavy protective gear, in addition to other equipment to be carried (e.g., weapons, ammunition, radios, pyrotechnics/explosives, medical kit, water, and the like), place significant weight on the shoulders of the personnel. Accordingly, the wearer can quickly become exhausted when performing even moderate exercises or drills while wearing such protective gear and the associated equipment. Furthermore, traditional protective gear can limit the wearer's range of motion, e.g. around the waist and arms, creating a potential safety hazard to the wearer, particularly in high-risk environments.
These problems are not limited to military/law enforcement equipment and personnel. Problems with load bearing mobility, fatigue, and muscle strain can also be found, for example, in firefighting, search and rescue, weighted exercise, infant carriage, or any other area in which loads are carried at least partially on or about the torso.
Although various attempts have been made to redistribute load weight, e.g. from the user's shoulders to the user's hips, many of these approaches unduly limit the user's mobility (e.g. bending, twisting, and/or running), or involve complex mechanical structures that add unwanted bulk and/or weight, and/or are cost-prohibitive for such uses. For these and other reasons, there are ongoing needs for improvements in wearable load carriage.
This summary is a high-level overview of various aspects of the disclosure and introduces some of the concepts that are further described in the Detailed Description section below. This summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended to be used in isolation to determine the scope of the claimed subject matter.
According to various aspects of the disclosure, a torso harness may be provided including one or more of a first chest panel; a first back panel; and/or a self-adjusting cummerbund connecting the first chest panel and the first back panel. In embodiments, the self-adjusting cummerbund may include a tensioning mechanism configured to allow the cummerbund to extend and retract.
In embodiments, the tensioning mechanism may be configured to provide varying resistive force. For example, the tensioning mechanism may be configured to provide a first resistive force when flat, and a second resistive force when curved, the second resistive force being greater than the first resistive force. In embodiments, the tensioning mechanism may be configured to allow the harness to expand, via extension of the cummerbund, as the user moves, while maintaining a constrictive pressure on the user.
In embodiments, the cummerbund may be releasably attached to at least one of the chest panel or the back panel via a quick release, the quick release including a buckle affixed to the chest panel or the back panel that is configured to flex about the Z axis, and to resist rotation relative to the Z axis. In embodiments, the buckle may be nested in a conforming portion of the chest panel or the back panel, and may be inhibited from rotating relative to the Z axis via cooperative engagement with the conforming portion of the chest panel or the back panel.
In embodiments, the tensioning mechanism may include one or more of a sliding portion, a continuous patterned length of material that is folded over itself, and an elastic member that is attached to the sliding member and the length of material.
In embodiments, the length of material may be made from HDPE, PP thermoplastic tape yarn sheeting (Tegris®), injection molded sheet material, Boltaron, PVC, PVC/acrylic alloy, and CPVC, thermoformed sheet material, extruded polymer sheets, and/or hybrid or laminated combinations thereof.
In embodiments, the sliding portion and/or the length of material may be at least partially housed within an outer cummerbund sleeve.
Embodiments may further include at least one of a second chest panel and/or a second back panel configured to hold a ballistic plate against the first chest panel and/or first back panel, respectively. That is, in some embodiments, a ballistic chest plate may be held between a first chest panel and a second chest panel, and/or a ballistic back plate may be held between a first back panel and a second back panel.
In embodiments, the second chest panel and/or second back panel may be configured to attach to the respective first chest panel and/or first back panel, via a strap of webbing that winds through the first and second panels.
In embodiments, the combination of the first chest panel and second chest panel, or the first back panel and second back panel, may be configured to allow the harness to accommodate, and hold in a fixed position, ballistic plates of different sizes and/or shapes.
In embodiments, the panels may be made of a material that is elastic when bent, but substantially inelastic in tension and/or compression, such as plastic, etc. As used in this context, “substantially” may be understood as including those materials that exhibit such characteristics under normal operational loads. That is, the material is inelastic in tension and/or compression under normal operational loads, which will be appreciated by those of skill in the art, considering the particular type of equipment
In embodiments, the chest panel(s) and/or back panel(s) may be made of HDPE, PP thermoplastic tape yarn sheeting (Tegris®), injection molded sheet material, Boltaron, PVC, PVC/acrylic alloy, and CPVC, thermoformed sheet material, extruded polymer sheets, and/or hybrid or laminated combinations thereof.
In embodiments, the first chest panel and/or first back panel may include built-in attachment features configured to allow a second chest panel and/or a second back panel to be attached thereto.
Embodiments may further include a removable plate carrier assembly, configured to attach to the first chest panel and/or first back panel.
In embodiments, the first chest panel and/or first back panel may include built-in attachment features for securing tactical equipment thereto.
In embodiments, the harness may be incorporated in at least one of a modular ballistic plate carrier, a ski patrol or rescue harness, a weighted training vest, a baby carrier, a tactical vest, etc.
According to further aspects of the disclosure, a ballistic plate carrier may be provided including one or more of an outer chest panel; an inner chest panel; an inner back panel; an outer back panel; and/or a cummerbund connecting the outer chest panel and the outer back panel. In embodiments, the outer chest panel and the inner chest panel may be configured to hold a ballistic chest plate therebetween, and/or the outer back panel and the inner back panel may be configured to hold a ballistic back plate therebetween.
In embodiments, the outer chest panel and inner chest panel, and/or the outer back panel and inner back panel, may be configured to allow the plate carrier to accommodate, and hold in a fixed position, ballistic plates of different sizes and/or shapes.
In embodiments, the ballistic chest plate may be held in place by one or more webbing straps wound through the outer chest panel and the inner chest panel, and/or the ballistic back plate may be held in place by one or more webbing straps wound through the outer back panel and the inner back panel.
In embodiments, at least one of the webbing straps may be (a) secured to the inner chest panel or inner back panel via a flat friction lock that is formed at least partially of the inner chest panel or inner back panel, and (b) adjustable via the flat friction lock.
In embodiments, at least one of the outer chest panel and the outer back panel may include a cummerbund attachment mechanism that is configured to flex about the Z axis, and/or to resist rotation relative to the Z axis.
In embodiments, at least one of the inner chest panel and the inner back panel may include a waist extension that extends beyond a footprint of the respective ballistic chest plate or ballistic back plate, and that is overlapped by the cummerbund when the plate carrier is worn. In embodiments, the waist extension may include built-in attachment features for securing tactical gear to the waist extension.
In embodiments, at least one of the outer chest panel and the outer back panel may include a plurality of built-in attachment features configured to mount tactical equipment thereto.
In embodiments, the outer chest panel, the inner chest panel, the outer back panel, and/or the inner back panel may be made of a material that is elastic when bent, but substantially inelastic in tension and/or compression, such as sheet plastic.
In embodiments, the outer chest panel, the inner chest panel, the outer back panel, and/or the inner back panel may be made of HDPE, PP thermoplastic tape yarn sheeting (Tegris®), injection molded sheet material, Boltaron, PVC, PVC/acrylic alloy, and CPVC, thermoformed sheet material, extruded polymer sheets, and/or hybrid or laminated combinations thereof.
In embodiments, the cummerbund may include a tensioning mechanism comprising one or more of a sliding portion, a continuous patterned length of material that is folded over itself, and an elastic member that is attached to the sliding portion and/or the length of material. In embodiments, the length of material may be made from HDPE, PP thermoplastic tape yarn sheeting (Tegris®), injection molded sheet material, Boltaron, PVC, PVC/acrylic alloy, and CPVC, thermoformed sheet material, extruded polymer sheets, and/or hybrid or laminated combinations thereof.
In embodiments, the sliding portion and/or the length of material may be at least partially housed within an outer cummerbund belt or sleeve.
In embodiments, various torso harnesses and/or carriers described herein may be configured with attachment features for mounting equipment thereto. For example, an attachment feature may include a first connector fixedly attached to the harness and/or carrier, and an accessory holder may be configured to attach to the harness and/or carrier via a complementary second connector that is fixedly attached to the accessory holder. Embodiments may include a release mechanism for releasing the accessory holder from the harnesses and/or carrier. In embodiments, the first connector and second connector may be configured to engage with one another so as to allow the accessory holder to be mounted to and removed from the harnesses and/or carrier. In embodiments, the first connector and second connector may be attachable to one another using a female member of the first connector and a male member of the second connector, or vice versa. In embodiments, the release mechanism may include at least one deflecting component integrally formed or joined with the attachment feature or accessory holder, and configured to be manipulated by a user's finger to allow the accessory holder to be removed from the harnesses and/or carrier. In embodiments, the attachment feature of the harness and/or carrier may include a plurality of first connectors arranged in fixed positions and configured to mount a plurality of accessory holders thereto.
According to further aspects of the disclosure, a webbing buckle may be provided including one or more of a first portion that is integrally formed with a load bearing strap, frame or harness, and a second portion that is made of a rigid material and that at least partially overlaps the first portion. In embodiments, the buckle may be configured to (a) seize a piece of webbing in a jaw formed by the first portion and the second portion when the piece of webbing is woven through the first portion and the second portion and the piece of webbing is put under tension in a first direction, and to (b) release the piece of webbing when the tension in the first direction is removed and tension is applied to the piece of webbing in a second direction, e.g. 90°-180° off of the first direction.
In embodiments, the load bearing strap, frame or harness may be made from a panel of material and the first portion is a patterned portion, of the material. In embodiments, the sheet of material may be made from HDPE, PP thermoplastic tape yarn sheeting (Tegris®), injection molded sheet material, Boltaron, PVC, PVC/acrylic alloy, and CPVC, thermoformed sheet material, extruded polymer sheets, and/or hybrid or laminated combinations thereof.
These and other aspects of the invention will now become apparent to those of ordinary skill in the art upon review of the following description of embodiments of the invention in conjunction with the accompanying drawings.
A detailed description of embodiments of the invention is provided below, by way of example only, with reference to the accompanying drawings, in which:
It is to be expressly understood that the description and drawings are only for the purpose of illustrating certain embodiments of the invention and are an aid for understanding. They are not intended to be a definition of the limits of the invention.
It is understood that the invention is not limited to the particular methodology, protocols, etc., described herein, as these may vary as the skilled artisan will recognize. It is also to be understood that the terminology used herein is used for the purpose of describing particular embodiments only, and is not intended to limit the scope of the invention. It also is to be noted that as used herein and in the appended claims, the singular forms “a,” “an,” and “the” include the plural reference unless the context clearly dictates otherwise. Thus, for example, a reference to “a support” is a reference to one or more supports and equivalents thereof known to those skilled in the art.
Unless defined otherwise, all technical terms used herein have the same meanings as commonly understood by one of ordinary skill in the art to which the invention pertains. The embodiments of the invention and the various features and advantageous details thereof are explained more fully with reference to the non-limiting embodiments and examples that are described and/or illustrated in the accompanying drawings and detailed in the following description. It should be noted that the features illustrated in the drawings are not necessarily drawn to scale, and features of one embodiment may be employed with other embodiments as the skilled artisan would recognize, even if not explicitly stated herein. Descriptions of well-known components and processing techniques may be omitted so as to not unnecessarily obscure the embodiments of the invention. The examples used herein are intended merely to facilitate an understanding of ways in which the invention may be practiced and to further enable those of skill in the art to practice the embodiments of the invention. Accordingly, the examples and embodiments herein should not be construed as limiting the scope of the invention, which is defined solely by the appended claims and applicable law.
In certain embodiments, load carriage system 100 may be a modular system. The load carriage system can be covered by various fabrics or padding so that none of, or only a portion of, wearable load carriage system 100 is exposed when worn. In some embodiments, wearable load carriage system 100 can include front plate assembly 110, shoulder straps 140, back plate assembly 120, and cummerbund elements 130.
Front plate assembly 110 may include an outer chest panel 112, inner chest panel 114, and/or ballistic chest plate 116. Likewise, back plate assembly 120 may include an outer back panel 122, inner back panel 124, and/or ballistic back plate 126. In this case, the ballistic chest plates 116, 126 are held between the outer panels 112, 122, and the inner panels 114, 124, respectively, although other embodiments may not necessarily include both outer and inner panels in the front and/or back plate assemblies, e.g. as discussed in U.S. application Ser. No. 13/506,182, filed Apr. 2, 2012 and entitled “PLATE CARRIER APPARATUS AND METHOD.”
As discussed further below, the outer chest panel 112 may be attached to the inner chest panel 114, and squeeze the ballistic chest plate 116 therebetween, via one or more straps of webbing 118 that wind through openings in the outer chest panel 112 and the inner chest panel 114. Likewise, the outer back panel 122 may be attached to the inner back panel 124, and squeeze the ballistic back plate 126 therebetween, via one or more straps of webbing 128 that wind through openings in the outer back panel 122 and the inner back panel 124.
The outer panels 112, 122, also have built-in attachment features (e.g., holes therethrough) that allow tactical equipment to be attached to the load carriage system 100. For example, the panels 112, 122 (or other rigid panel components described herein) may include a number of holes therein of different sizes and shapes for performing various purposes, including for inserting the webbing straps 118, 128 therethrough and for attaching various equipment (e.g., tactical equipment such as pockets, pouches, holsters, backpacks, etc.) to the load carriage system 100. The load carriage system 100 may be designed as shown in the figures so that the holes therein are shaped to allow attaching of specific tactical equipment, pockets, pouches, backpacks, etc. to the holes. In one example, the one or more pouches may have tabs that extend through the holes in the panels and then wrap around the panel back onto themselves, and the portions of the tabs which overlap themselves may be attached to one another using, for example one or more hook and loop fasteners (e.g., Velcro®) or what is referred to as a “tuck-tab.” In some embodiments, such features may also include built-in attachment mechanisms.
For example, similar to attachment systems described in U.S. application Ser. No. 14/496,575, filed Sep. 25, 2014 and entitled “GEAR TRACK SYSTEM, a built-in attachment feature may include a connector element that is fixedly attached to the outer chest panel 112 and/or other parts of the load carriage system 100 (which may be referred to as the “harness” for ease of description), and an accessory holder (such as a firearm magazine holder) may be configured to attach to the harness via a complementary connector element that is fixedly attached to the accessory holder. Embodiments may include a release mechanism for releasing the accessory holder from the harness. In embodiments, the connector elements may be configured to engage with one another so as to allow the accessory holder to be mounted to and removed from the harness.
In embodiments, connectors may be attachable to one another using a female member of one connector and a male member of the other connector. In embodiments, the release mechanism may include at least one deflecting component integrally formed or joined with the attachment feature (or accessory holder), and configured to be manipulated by a user's finger to allow the accessory holder to be removed from the outer chest panel 112. Preferably, the deflecting component is part of the harness's connector, and the accessory holder's connector is configured to deflect the deflecting component as the two connectors engage. The deflecting component may be further configured to snap back to a locked position when the connector of the accessory holder is fully seated in the connector of the harness.
In embodiments, the attachment feature of the harness may include a plurality of connectors arranged in fixed positions and configured to mount a plurality of accessory holders thereto.
In embodiments, the panels 112, 114, 122, 124 may be made of a “rigid” material, which, as used herein, should be understood as including those materials that, in appropriate thicknesses, resist deformation under operational loads, as well as those that naturally return to their original shape after deformation (e.g. bending) under operational loads. Such materials may preferably include, for example, plastics, laminates, etc. In embodiments, the panels 112, 114, 122, and/or 124 may be made of HDPE, PP thermoplastic tape yarn sheeting (Tegris®), injection molded sheet material, Boltaron, PVC, PVC/acrylic alloy, and CPVC, thermoformed sheet material, extruded polymer sheets, and/or hybrid or laminated combinations thereof.
By making the panels 112, 114, 122, 124, out of these types of material, the panels (or other components described herein) may be substantially (i.e. greater than 90%) liquid, chemical, and biohazard resistant. These types of material can also be easily decontaminated. Forming the panels from these types of material also eliminates any extra weight being added to the material when the load carriage system 100 is submerged in water.
As shown in
The chest and back plates 116, 126, provide ballistic protection to the wearer. The plates 116, 126 may include any type or material of body armor plate which provides ballistic protection to the wearer known to those skilled in the art. The level of protection of the body armor plate is typically specified by the armor manufacturer and could range from protection from low-velocity projectiles (e.g. shrapnel) to protection from high-velocity rifle bullets. One example of materials which the body armor plate may be constructed from includes a formed, rigid ceramic plate with a soft woven Kevlar backing, the ceramic plate and backing sandwiched together into one singular plate.
In some embodiments, the panels 112, 114, 122, and/or 124 may generally correspond to the size, shape, and curvature of the ballistic plate 116 and/or 126. In this regard, the outer chest panel 112 and/or inner chest panel 114 may generally correspond (at least partially) to the size, shape, and curvature of the chest plate 116, and the outer back panel 122 and/or inner back panel 124 may generally correspond (at least partially) to the size, shape, and curvature of the back plate 126. However, in embodiments that use a “cinching” mechanism, such as webbing straps 118, 128, the outer perimeters of the panels may be smaller than, and/or include portions that extend within, the outer perimeter of the corresponding ballistic plate. This can allow, for example, the load carriage system 100 to accommodate, and hold in a fixed position, ballistic plates of different sizes and/or shapes.
As discussed further below, the cummerbund element(s) 130 may be “self-adjusting,” and include a tensioning mechanism configured to allow the cummerbund to extend and retract while being worn by the user, and during donning and removing the load carriage system 100.
The cummerbund element 130 may be releasably attached to the chest panel (and/or the back panel) via a quick release at buckle 132. A cooperating buckle 134 of the quick release mechanism is affixed to the outer chest panel 112 (and/or the outer back panel), and is configured to flex about the Z axis (i.e. in and out of the page of
In the embodiments shown in
As used herein, attachments like screws 127 that typically require tools to attach and/or detach may be referred to as “fixed attachments” and distinguished from other “quick-release” attachments, such as Velcro®, side release buckles, slot connectors, etc., that may be readily attached and/or detached without tools. Unless otherwise specified, “fixed attachments” may also include attachment means that are not intended to be taken apart, such as rivets, welds, etc.
It should also be appreciated that, although the embodiment depicted in
In some embodiments, the panels 112, 114, 122, and/or 124 may include, or be joined with, panel extensions, e.g. additional panel portions that may be constructed with similar materials and/or attachment features, and that increase the effective size of the panel. These may be attached to and/or formed in a lower portion of the panel, and may general extend under the arms of the user in the vicinity of the cummerbund element(s) 130. For example, the inner chest panel 114 may include and/or be attached to chest panel extensions 115 (as shown in
As shown in
In embodiments, various other tactical items may be secured to panel extensions and/or side armor in the vicinity of the cummerbund element 130. This may be accomplished, at least in some examples, by providing attachment features to the panel extensions and/or side armor, and due to the extendibility of the cummerbund element, which allows it to provide additional space (between the panel extensions and/or side armor) in which the additional items may be accommodated.
In some examples, the webbing straps 118 may be two pieces of webbing, e.g. with one webbing strap 118A securing the upper portion of the front plate assembly, and another webbing strap 118B securing the lower portion of the front plate assembly. An embodiment with this configuration is shown in
The first portion 172 shown in
As will be appreciated by the example shown in
In certain embodiments, load carriage system 200 may be a modular system. The wearable load carriage system can be covered by various fabrics or padding so that none of, or only a portion of, wearable load carriage system 200 is exposed when worn. In some embodiments, load carriage system 200 can include front plate structure 210, shoulder straps 240, back harness panel 220, and cummerbund elements 230.
Front plate assembly 210 may be constructed in a similar manner to front plate assembly 110 in
As discussed elsewhere herein, the outer chest panel 212 may be attached to the inner chest panel 214, and squeeze the ballistic chest plate 216 therebetween, via one or more straps of webbing 218 that wind through openings in the outer chest panel 212 and the inner chest panel 214.
A cummerbund element 230 may attach the front plate assembly and the back harness panel 220. The cummerbund element 230 may be a self-adjusting and/or extending cummerbund as described elsewhere herein. The back harness panel 220 may be constructed in similar manner, using similar materials, to other panels described herein, such as panels 112, 114, 122, 124.
The back pack attachment features 222 may take various forms, such as hooks, loops, Velcro®, side release buckles, slot connectors, etc., and may be used to secure various pieces of equipment to the back harness panel 220. In the example shown in
The removable back plate assembly 260 may also include shoulder straps 265, which may be used to perform various functions. For example, the shoulder straps 265 may be integrated with the load carriage system 200 when the removable back plate assembly 260 is attached, e.g. running over, under or within shoulder straps 240. The shoulder straps 265 may also be configured for a user to easily don and doff the removable back plate assembly 260 without the use of separate attachment features, e.g. for emergency use.
The outer panels of front plate assembly 210 and/or removable back plate assembly 260 have built-in attachment features (e.g., holes therethrough, attachment mechanisms, etc.) that allow tactical equipment to be attached to the load carriage system 200, similar to methods and features described above.
As described above, the panels of front plate assembly 210 and/or removable back plate assembly 260 may also have unnecessary material removed, e.g. to decrease the weight that is loaded on the user. In such cases, the panels may include a continuous outer perimeter, with voids inside the perimeter that may equal, for example, 50% or more of the total surface area of the panel.
In some embodiments, the panels of front plate assembly 210 and/or removable back plate assembly 260 may generally correspond to the size, shape, and curvature of the ballistic plate. However, in embodiments that use a “cinching” mechanism, such as webbing straps 218, 268, the outer perimeters of the panels may be smaller than, or include portions that extend within, the outer perimeter of the corresponding ballistic plate. This can allow, for example, the load carriage system 200 to accommodate, and hold in a fixed position, ballistic plates of different sizes and/or shapes.
As discussed herein, the cummerbund element(s) 230 may be “self-adjusting,” and include a tensioning mechanism configured to allow the cummerbund to extend and retract while being worn by the user, and during donning and removing the load carriage system 200.
The cummerbund element 230 may be releasably attached to the chest panel (and/or the back panel) via a quick release at buckle 232. A cooperating buckle 234 of the quick release mechanism is affixed to the outer chest panel 212 (and/or the outer back panel), and is configured to flex about the Z axis (i.e. in and out of the page of
In the embodiment shown in
It should also be appreciated that, although the embodiment depicted in
As with the examples described above, the panels of the front plate assembly 210 and/or back harness panel 220 may include, or be joined with, panel extensions, e.g. additional panel portions that may be constructed with similar materials and/or attachment features, and that increase the effective size of the panel. These may be attached to and/or formed in a lower portion of the panel, and may generally extend under the arms of the user in the vicinity of the cummerbund element(s) 230. For example, the inner chest panel 214 may include and/or be attached to chest panel extensions 215 (as shown in
In embodiments, various other tactical items may be secured to panel extensions and/or side armor in the vicinity of the cummerbund element 230. This may be accomplished, at least in some examples, by providing attachment features to the panel extensions and/or side armor, and due to the extendibility of the cummerbund element, which allows it to provide additional space (between the panel extensions and/or side armor) in which the additional items may be accommodated.
As shown in
In some examples, the webbing straps 268 may be two pieces of webbing, e.g. with one webbing strap securing the upper portion of the back plate assembly 260, and another webbing strap securing the lower portion of the back plate assembly, as discussed above.
The inner panel 264 may also include securing straps and flat friction lock features according to certain aspects of the present disclosure. Each of webbing straps 268 may have a standing end that is fixed or otherwise attached to inner back panel 264, and a free end that is routed through slots in the outer back panel, and inner chest panel 264, and flat friction lock 270. The ballistic chest plate 266 may thereby be securely fastened in a fixed position between the outer chest panel and the inner chest panel 264. It should be further appreciated that, using this configuration, a variety of differently sized and/or shaped ballistic chest plates may be accommodated by the removable back plate assembly 260.
Although the embodiments shown in
As mentioned previously, embodiments may further include cummerbunds that can extend, and retract via their own internal mechanisms. For example, a cummerbund assembly 330 may assume a non-extended position when no tension is applied (e.g. as shown in
As will be appreciated looking at
As shown in
In embodiments, the length of material 334 may be made from HDPE, PP thermoplastic tape yarn sheeting (Tegris®), injection molded sheet material, Boltaron, PVC, PVC/acrylic alloy, and CPVC, thermoformed sheet material, extruded polymer sheets, and/or hybrid or laminated combinations thereof.
In embodiments, a tensioning mechanism of the cummerbund element 330 may be configured to provide varying resistive force. For example, the tensioning mechanism may be configured to provide a first resistive force when flat, and a second resistive force when curved, the second resistive force being greater than the first resistive force. Such variation may be provided, for example, based on an increase in the friction between the length of material 334 and the sliding portion 336 when the cummerbund element 330 is wrapped around a user's torso or otherwise curved. This friction may be reduced when the cummerbund element 330 is laid flat or otherwise straightened out. Such variation may be beneficial, for example, in allowing a user to easily extend the cummerbund when donning the harness, and then providing increased resistance while being worn, which can improve the comfort and/or load distribution of the harness.
In embodiments, the tensioning mechanism may be configured to allow the harness to expand, via extension of the cummerbund, as the user moves, while maintaining a constrictive pressure on the user, e.g. via a tension applied by elastic member 341 or similar mechanism.
Embodiments disclosed herein provide a plate frame or other torso harnesses which hold body armor and/or any other loads, in a manner more streamlined and/or comfortable than prior art vests. The load bearing harness is also capable of holding accessory pouches and providing access to accessory pouches and other attachments to the harness.
Any feature of any embodiment discussed herein may be combined with any feature of any other embodiment discussed herein in some examples of implementation.
Certain additional elements that may be needed for operation of certain embodiments have not been described or illustrated as they are assumed to be within the purview of those of ordinary skill in the art. Moreover, certain embodiments may be free of, may lack and/or may function without any element that is not specifically disclosed herein.
Although various embodiments and examples have been presented, this was for the purpose of describing, but not limiting, the invention. Various modifications and enhancements will become apparent to those of ordinary skill in the art and are within the scope of the invention, which is defined by the appended claims.
This application claims priority to U.S. Provisional Application 62/539,809, filed Aug. 1, 2017 and entitled “LOAD BEARING HARNESS,” the contents of which are hereby incorporated by reference for all purposes. The present disclosure is also related to U.S. Pat. No. 9,777,997, issued Oct. 3, 2017 and entitled “PLATE CARRIER APPARATUS AND METHOD;” U.S. application Ser. No. 14/496,575, filed Sep. 25, 2014 and entitled “GEAR TRACK SYSTEM;” and U.S. Pat. No. 9,995,431, issued Jun. 12, 2018 and entitled “WEARABLE SUPPORT SYSTEM FOR LOAD DISTRIBUTION,” the contents of which are hereby incorporated by reference for all purposes.
Number | Date | Country | |
---|---|---|---|
62539809 | Aug 2017 | US |