US3318024A - Blast protective footwear - Google Patents

Blast protective footwear Download PDF

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US3318024A
US3318024A US554937A US55493766A US3318024A US 3318024 A US3318024 A US 3318024A US 554937 A US554937 A US 554937A US 55493766 A US55493766 A US 55493766A US 3318024 A US3318024 A US 3318024A
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deflector
heel
blast
apex
footwear
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Edwin S Fujinaka
John L Macdonald
Edward R Barron
George M Stewart
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    • AHUMAN NECESSITIES
    • A43FOOTWEAR
    • A43BCHARACTERISTIC FEATURES OF FOOTWEAR; PARTS OF FOOTWEAR
    • A43B7/00Footwear with health or hygienic arrangements
    • A43B7/32Footwear with health or hygienic arrangements with shock-absorbing means

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  • This invention relates to protective footwear which will reduce the damage to a human foot that would otherwise result from exposure to the blast effects of an anti-personnel land mine and, more particularly, to protective footwear having a deflector in the boot which will reduce the gross impulse and peak transmitted stresses applied to a human foot by an underfoot explosion.
  • the protective footwear of the present invention provides protection against underfoot explosions while not adversely affecting foot flexing properties.
  • the protection aflorded is not complete but is suflicient to reduce the degree of injury in the heel and arch portions of the foot and in the lower leg so that amputation of these parts will not normally be required.
  • an object of the present invention is to provide footwear which will protect the feet and legs of the wearer from the effects of an underfoot explosion.
  • FIGURE 1 is a side elevational view of a boot according to the present invention with a blast-protective deflector shown in phantom;
  • FIGURE 2 is bottom plan view of the sole of the boot of FIGURE 1, illustrating the outsole configuration and showing the deflector in phantom;
  • FIGURE 3 is a vertical transverse sectional view of the blast-protective deflector illustrating the details of its construction
  • FIGURE 4 is a vertical transverse sectional view of a modified deflector.
  • FIGURE 5 is a vertical transverse sectional view of still another deflector of the present invention.
  • FIGURES 1 and 2 of the drawings there is shown an example of the protective footwear of the present invention in the form of a direct molded sole combat boot 10.
  • This boot includes the usual leather upper section designated as an entirety by the number 12 which is generally similar to uppers of conventional boots and a lower section designated as an entirety by the number 14.
  • the lower section comprises a heel portion 16, a shank portion 18 and a sole portion 20.
  • the lower section is made of vulcanizable rubber or rubberlike material of the type commonly used in making direct molded sole footwear so that upper section 12 may be directly molded to lower section 14 by fusing the two sections together along the welt line which is indicated more or less diagrammatically at 22. Protection against the blast of an underfoot explosion is provided by an elongated wedge-shaped deflector 24 which is embedded in the lower section 14- so as to extend over the heel and shank portions thereof.
  • the deflector shown in FIGURES 1 and 2 of the drawing is dimensioned so as to extend over substantially all of the heel and shank areas of the boot.
  • a threeinch wide by six-inch long deflector will, for example, provide coverage or protection to substantially all of the heel and shank portions of the most popular sizes of boots.
  • the deflector, shown in detail in FIGURE 3, is a composite body, wedge-shaped when viewed in transverse section. When embedded in the boot, apex 26 of the deflector is directed downwardly toward the bottom surface of the lower section and the wall surface 28 of the deflector opposite the apex 26 is parallel with the bottom or top surfaces of the lower section.
  • the outermost walls 3t ⁇ forming the apex 26- of the deflector are formed of a single sheet of high tensile strength, non-shatterable material, e.g. stainless steel 9 in thickness, which is bent along its longitudinal center line to form the desired apical angle, eg an included angle of 112.
  • the wall 28 opposite the apex 26 is formed of the same material as walls 30 and is a flat sheet resting on but not otherwise attached to the upper edges of walls 30. It is noted that wall 28 is dimensioned so as to extend laterally a distance beyond the upper edge of each of the walls 30.
  • the walls 30 and 28 have a thickness of at least and preferably when constructed of stainless steel have a thickness of A or ,4
  • a wedge-shaped section of non-elastic, shock-absorbing material 32 occupies the triangular cavity defined by walls 30 and wall 28 and functions to spread the impulsive load over as long a time period as possible and to distribute the load over as large an area as is practicable.
  • the shockabsorbing material used in the present invention should have a crushing strength (sustained stress during longitudinal cell compression) of from about 2500 psi. to about 5000 psi.
  • Preferred materials, which combine high compressive strength with low weight include aluminum hexagonal cell honeycombs having a cell size of %-inch, e.g.
  • honeycomb constructed of foil having a thickness of .004-inch, a gross density of 15.3 pounds per cubic foot, and a crushing strength of 2550 p.s.i., or a honeycomb constructed of aluminum foil .OOS-inch in thickness, having a gross density of 23 pounds per cubic foot and a crushing strength of 4150 p.s.i.
  • the cells of the honeycomb 32 within the triangular cavity are oriented so as to extend in the same direction as the apex and perpendicular to the wall surface 28.
  • An additional layer 34 of honeycomb, having a thickness of A2" to A", is included in the deflector design embodied in FIGURE 3 and is positioned above and flush with the wall surface 28 with its cells oriented so as to be perpendicular to said wall surface.
  • This upper honeycomb layer 34 functions to distribute the transmitted load over as large an area as possible to cushion the impact of the residual velocity retained in the walls 28 and 30 after passage of the stress wave into the foot.
  • a thin, e.g., .0l6-inch, aluminum plate 36 covers the top surface of layer 34. The height of the deflector taken from the the shock-absorbing material may be crushed.
  • thin layer of honeycomb 47 is placed above the upper wall the top surface thereof is from about 1' to 1 t'
  • the cornponentsof the deflector may be held togetier by any suitable mechanical means or adhesive to fa iitate fabrication of the protective footwear. It is important to note, however, that the top wall 28 of the trianml wedge merely rests on the sidewalls 30' or at most is at tached in a manner that will permit separation there from under s icht pressure.
  • This construction permits the sidewalls 30 to partially collapse and spread laterally sc that
  • the outer surfaces of the deflector 24 are coated with a rubber cement compatible with the rt bber compound used to form the heel, shank and sole of the footwear so that the deflector will bond to this rubber compound and to the insole of the boot.
  • the outsole is molded in accordance with known direct moHi rocesses for footwear The deflector thus is embecd id or built into the footwear as shown in FIG- URES 1 and 2.
  • FIGURE 4 there is shown a deflector 40 of modified constructic n.
  • the sidewalls 4-2 for i r the apex 44 are constructe l of an integral sheet of high tensile strength, non'shatte able material, said sheet b: rg thickest at the apex and tapering toward the upper edge thereof.
  • the increased th ckness in the apex provides g "t ater strength and resistance to deformation in this area
  • a wedge-shaped hone comb 46 similar in construction to the honeycomb 32 in FIGURE 3 occupies the triangular cavity defined by the sidewalls 42v and the upper wall 4%.
  • Upper wall 48 is not integral with or permanently attached to the upper edge.
  • FIGURE 5 ofthe drawing illustrates another blast deflector of this invention designated generally'as 50 which is also wedge-shaped in transverse section.
  • the downwardly directed apex 54 of the wedge is formed by bending a flat sheet of high tensile strength, non-shatterable material along its center line until the included angle at the apex is approximately 112.
  • the integral sidewalls forming the apex are identified as 52.
  • Placed across the top edges of the walls 52 is a fiat sheet 56 of the same material used to form the sidewalls. Sheet 56 which rests on and is not affixed to the top edges of the walls 52 extends laterally a short distance beyond each sidewall.
  • shockabsorbing material 58 e.g., an aluminum honeycomb having a crushing strength of 2550 psi. and having the longitudinal axis of the cells thereof oriented in the same direction as the apex 54.
  • the gross impulse of the underfoot explosion transmitted to the protective footwear of this invention can be reduced by minimizing the ground contact area of the boot.
  • Our studies have demonstrated that the greatest reduction in gross impulse without adverse effect on stability and wearing qualities of the boot results when the area of the outsole material in contact with a land mine, e.g. a 3-inch diameter, blast-type, land mine, is reduced to a one-inch long wedge or ridge of outsole material.
  • the outsole configuration shown in FIGURES 1 and 2 starting at the rear edge of the heel has an approximately l-inch long ridge of material extending across the heel that makes contact with the ground, followed by an approximately one-inch depression in the heel, followed by ariother one-inch ridge of material that contacts the ground. Proceeding along the bottom of the boot the next area thereof to make contact with the ground will be the sole in the vicinity of the ball of the foot.
  • the protective footwear of this invention provides a high level of protection against the impulse load (blast effect) generated by a land mine while not affecting the normal functional qualities of such footwear.
  • the design of the outsole so as to minimize the area thereof coming intocontactwith a mir e, reduces the gross impulse delivered to the boot with ut substantially affecting stability or wearing qualities of the boot.
  • a wedgeshaped deflector in the lower section of the boot, we have replaced the normal flat reflecting surface which would be subjected to a maxmum reflected pressure, with an oblique plane surface which permits the oblique reflection of particles and allows an escape path for the gasses of combustion thereby further reducing the gross impulse.
  • the peak transmitted pressure of a few mic rose :onds duration is reduced by a layered system of im dance mismatched materials.
  • the honeycomb wedge serves to spread the impulsive loadover as long a time period as possible and to distribute the load cver as argc an area as is practical.
  • Damage to a human f explosion is relatedto the ciated with the irnpu sive of our invention des btast effects of an urderi the total impulse 1" mi the peak pressure transmitted tion provides the r m m de without significan ly affe :ting the boot.
  • non-elastic, shock-absorbing material is of honeycomb construction, having the longitudinal axis of the cells thereof oriented in the same direction as the apex of said deflector, and having a crushing strength of at least 2500 p.s.i.
  • Protective footwear according to claim 1 having a layer of non-elastic, shock-absorbing material of substantially uniform thickness extending over and covering said p Wall, and a thin sheet of non-shatterable material covst g i l yer.
  • non-elastic, shock-absorbing material is of honeycomb construction, having the longitudinal axis of the cells thereof oriented in the same direction as the apex of said deflector and having a crushing strength of at least 2500 p.s.i.
  • Protective footwear according to claim 9 wherein said lower section has an outsole configuration beneath said deflector having alternate ridges and grooves which are perpendicular to the longitudinal axis of said lower section whereby the surface area of the outsole that comes into contact with the ground is reduced thereby reducing the gross impulse transmitted to the foot from an underfoot explosion 13.
  • Protective footwear according to claim 12 wherein said sidewalls are formed of an integral sheet of high tensile strength, non-shatterable material, wherein said high tensile strength, non-shatterable material is stainless steel having a thickness of from about to about A", and wherein said non-elastic shock-absorbing material is an aluminum honeycomb having a crushing strength of from about 2500 p.s.i. to about 5000 p.s.i.

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  • Health & Medical Sciences (AREA)
  • Epidemiology (AREA)
  • General Health & Medical Sciences (AREA)
  • Public Health (AREA)
  • Footwear And Its Accessory, Manufacturing Method And Apparatuses (AREA)

Description

y 1967 E. s. FUJINAKA ETAL 3,318,624
BLAST PROTECTIVE FOOTWEAR Filed May 31, 1966 United States Patent G 3,318,024 BLAST PRQTECTIVE FOOTWEAR Edwin S. Fujinaka and John L. MacDonald, Chicago, 111., Edward R. Barron, Framingham, Mass, and George M. Stewart, Bel Air, Md, assignors, by direct and mesne assignments, to the United States of American as represented by the Secretary of the Army Filed May 31, 1966, Ser. No. 554,937 13 Claims. (Cl. 35-25) This invention relates to protective footwear which will reduce the damage to a human foot that would otherwise result from exposure to the blast effects of an anti-personnel land mine and, more particularly, to protective footwear having a deflector in the boot which will reduce the gross impulse and peak transmitted stresses applied to a human foot by an underfoot explosion.
Small, blast-type, anti-personnel, land mines are used extensively in areas of military conflict to produce nonlethal, incapacitating injuries. Such mines are normally triggered by the pressure of a foot stepping on the mine and the blast effect is exerted primarily on the foot and lower portion of the leg. While any injury to the foot or lower leg is serious, destruction of the heel or arch of the foot or a serious shattering of the lower leg, the probable consequence of such an underfoot explosion, is likely to require immediate amputation of at least a portion of the lower extremity. If the heel and arch portions of the foot and the lower portion of the leg can be protected from the blast of anti-personnel land mines, much of the devastating and permanent damage of these areas can be obviated. While protective devices have been used heretofore, especially by personnel clearing mine fields, such devices interfere with normal foot flexing movements and, consequently, greatly im pede the mobility of the wearer. The protective footwear of the present invention provides protection against underfoot explosions while not adversely affecting foot flexing properties. The protection aflorded is not complete but is suflicient to reduce the degree of injury in the heel and arch portions of the foot and in the lower leg so that amputation of these parts will not normally be required.
Accordingly, an object of the present invention is to provide footwear which will protect the feet and legs of the wearer from the effects of an underfoot explosion.
It is also an object of this invention to provide protection against the blast effect of an anti-personnel land mine exploding underfoot by providing a protective component in conventional footwear which will not interfere with normal foot flexing movements.
These and other objects, advantages and capabilities of the invention will become apparent from the following description wherein reference is had to the accompanying drawing in which:
FIGURE 1 is a side elevational view of a boot according to the present invention with a blast-protective deflector shown in phantom;
FIGURE 2 is bottom plan view of the sole of the boot of FIGURE 1, illustrating the outsole configuration and showing the deflector in phantom;
FIGURE 3 is a vertical transverse sectional view of the blast-protective deflector illustrating the details of its construction;
FIGURE 4 is a vertical transverse sectional view of a modified deflector.
FIGURE 5 is a vertical transverse sectional view of still another deflector of the present invention.
Referring to FIGURES 1 and 2 of the drawings, there is shown an example of the protective footwear of the present invention in the form of a direct molded sole combat boot 10. This boot includes the usual leather upper section designated as an entirety by the number 12 which is generally similar to uppers of conventional boots and a lower section designated as an entirety by the number 14. The lower section comprises a heel portion 16, a shank portion 18 and a sole portion 20. The lower section is made of vulcanizable rubber or rubberlike material of the type commonly used in making direct molded sole footwear so that upper section 12 may be directly molded to lower section 14 by fusing the two sections together along the welt line which is indicated more or less diagrammatically at 22. Protection against the blast of an underfoot explosion is provided by an elongated wedge-shaped deflector 24 which is embedded in the lower section 14- so as to extend over the heel and shank portions thereof.
The deflector shown in FIGURES 1 and 2 of the drawing is dimensioned so as to extend over substantially all of the heel and shank areas of the boot. A threeinch wide by six-inch long deflector will, for example, provide coverage or protection to substantially all of the heel and shank portions of the most popular sizes of boots. The deflector, shown in detail in FIGURE 3, is a composite body, wedge-shaped when viewed in transverse section. When embedded in the boot, apex 26 of the deflector is directed downwardly toward the bottom surface of the lower section and the wall surface 28 of the deflector opposite the apex 26 is parallel with the bottom or top surfaces of the lower section. The outermost walls 3t} forming the apex 26- of the deflector are formed of a single sheet of high tensile strength, non-shatterable material, e.g. stainless steel 9 in thickness, which is bent along its longitudinal center line to form the desired apical angle, eg an included angle of 112. The wall 28 opposite the apex 26 is formed of the same material as walls 30 and is a flat sheet resting on but not otherwise attached to the upper edges of walls 30. It is noted that wall 28 is dimensioned so as to extend laterally a distance beyond the upper edge of each of the walls 30. The walls 30 and 28 have a thickness of at least and preferably when constructed of stainless steel have a thickness of A or ,4
A wedge-shaped section of non-elastic, shock-absorbing material 32 occupies the triangular cavity defined by walls 30 and wall 28 and functions to spread the impulsive load over as long a time period as possible and to distribute the load over as large an area as is practicable. The shockabsorbing material used in the present invention should have a crushing strength (sustained stress during longitudinal cell compression) of from about 2500 psi. to about 5000 psi. Preferred materials, which combine high compressive strength with low weight, include aluminum hexagonal cell honeycombs having a cell size of %-inch, e.g. an aluminum honeycomb constructed of foil having a thickness of .004-inch, a gross density of 15.3 pounds per cubic foot, and a crushing strength of 2550 p.s.i., or a honeycomb constructed of aluminum foil .OOS-inch in thickness, having a gross density of 23 pounds per cubic foot and a crushing strength of 4150 p.s.i. The cells of the honeycomb 32 within the triangular cavity are oriented so as to extend in the same direction as the apex and perpendicular to the wall surface 28.
An additional layer 34 of honeycomb, having a thickness of A2" to A", is included in the deflector design embodied in FIGURE 3 and is positioned above and flush with the wall surface 28 with its cells oriented so as to be perpendicular to said wall surface. This upper honeycomb layer 34 functions to distribute the transmitted load over as large an area as possible to cushion the impact of the residual velocity retained in the walls 28 and 30 after passage of the stress wave into the foot. A thin, e.g., .0l6-inch, aluminum plate 36 covers the top surface of layer 34. The height of the deflector taken from the the shock-absorbing material may be crushed.
. thin layer of honeycomb 47 is placed above the upper wall the top surface thereof is from about 1' to 1 t' The cornponentsof the deflector may be held togetier by any suitable mechanical means or adhesive to fa iitate fabrication of the protective footwear. It is important to note, however, that the top wall 28 of the trianml wedge merely rests on the sidewalls 30' or at most is at tached in a manner that will permit separation there from under s icht pressure. This construction permits the sidewalls 30 to partially collapse and spread laterally sc that The outer surfaces of the deflector 24 are coated with a rubber cement compatible with the rt bber compound used to form the heel, shank and sole of the footwear so that the deflector will bond to this rubber compound and to the insole of the boot. When. the deflector is fixed'in position, the outsole is molded in accordance with known direct moHi rocesses for footwear The deflector thus is embecd id or built into the footwear as shown in FIG- URES 1 and 2.
In FIGURE 4, there is shown a deflector 40 of modified constructic n. The sidewalls 4-2 for i r the apex 44 are constructe l of an integral sheet of high tensile strength, non'shatte able material, said sheet b: rg thickest at the apex and tapering toward the upper edge thereof. The increased th ckness in the apex provides g "t ater strength and resistance to deformation in this area A wedge-shaped hone comb 46, similar in construction to the honeycomb 32 in FIGURE 3 occupies the triangular cavity defined by the sidewalls 42v and the upper wall 4%. Upper wall 48 is not integral with or permanently attached to the upper edge. of the sidewalls 42 but merely rests thereon so that the sidewalls may :more easily deform under the transmitted load of an underfoot explosion. An additional 48 and is covered with a thin sheet 49 of non-shatterable material. The included angle of the apex 44, as measured from the outside surfaces of sidewalls 42 is 112".
FIGURE 5 ofthe drawing illustrates another blast deflector of this invention designated generally'as 50 which is also wedge-shaped in transverse section. The downwardly directed apex 54 of the wedge is formed by bending a flat sheet of high tensile strength, non-shatterable material along its center line until the included angle at the apex is approximately 112. The integral sidewalls forming the apex are identified as 52. Placed across the top edges of the walls 52 is a fiat sheet 56 of the same material used to form the sidewalls. Sheet 56 which rests on and is not affixed to the top edges of the walls 52 extends laterally a short distance beyond each sidewall. The interior of the wedge-shaped deflector is filled with shockabsorbing material 58, e.g., an aluminum honeycomb having a crushing strength of 2550 psi. and having the longitudinal axis of the cells thereof oriented in the same direction as the apex 54.
The gross impulse of the underfoot explosion transmitted to the protective footwear of this invention can be reduced by minimizing the ground contact area of the boot. Our studies have demonstrated that the greatest reduction in gross impulse without adverse effect on stability and wearing qualities of the boot results when the area of the outsole material in contact with a land mine, e.g. a 3-inch diameter, blast-type, land mine, is reduced to a one-inch long wedge or ridge of outsole material. The outsole configuration shown in FIGURES 1 and 2 starting at the rear edge of the heel has an approximately l-inch long ridge of material extending across the heel that makes contact with the ground, followed by an approximately one-inch depression in the heel, followed by ariother one-inch ridge of material that contacts the ground. Proceeding along the bottom of the boot the next area thereof to make contact with the ground will be the sole in the vicinity of the ball of the foot.
The protective footwear of this invention provides a high level of protection against the impulse load (blast effect) generated by a land mine while not affecting the normal functional qualities of such footwear. The design of the outsole so as to minimize the area thereof coming intocontactwith a mir e, reduces the gross impulse delivered to the boot with ut substantially affecting stability or wearing qualities of the boot. By employing a wedgeshaped deflector in the lower section of the boot, we have replaced the normal flat reflecting surface which would be subjected to a maxmum reflected pressure, with an oblique plane surface which permits the oblique reflection of particles and allows an escape path for the gasses of combustion thereby further reducing the gross impulse. The peak transmitted pressure of a few mic rose :onds duration is reduced by a layered system of im dance mismatched materials. The honeycomb wedge serves to spread the impulsive loadover as long a time period as possible and to distribute the load cver as argc an area as is practical.
Damage to a human f explosion is relatedto the ciated with the irnpu sive of our invention des btast effects of an urderi the total impulse 1" mi the peak pressure transmitted tion provides the r m m de without significan ly affe :ting the boot.
The foregoing descri ation is illustrative or ly, and be understood that various changes in the retails, rials, and arrangement. of pats vhich have been described and illustrated, may be made by those in the art within the principle and scope of be im as expressed in the app ended claims.
We claim:
)Ot resulting from an underfoot peak pressure and impulse assoload The prctect ve ic twear effe:tive pro tn 3 r t the cot explc sion 'ty rd ingboth ted to the foot aid reducing to the foct. invengree of pro nossible the functi l iies of Y Th it will mateherein skilled ention from an underfoot explosion of an antipersonnel land of comprising an upper section and a lower section to form the heel, shank and sole portions of said footwear, said lower section embodying an elongated blast-resistant deflector, wedge-shaped in transverse section, extending over substantially all of the heel and shank portions thereof, said deflector comprising sidewalls of high tensile strength, non-shatterable material formed to define a wedge open at the top and having the apex thereof directed downwardly, a sheet of high tensile strength, non-shatterable material extending across and covering the open top of said deflector and forming the top wall thereof, and the interior of said deflector being filled with non-elastic, shock-absorbing material.
2. Protective footwear according to claim 1 wherein the included angle in said downwardly directed apex is in the range of about 60 degrees to about degrees.
3. Protective footwear according to claim 2 wherein said non-elastic, shock-absorbing material is of honeycomb construction, having the longitudinal axis of the cells thereof oriented in the same direction as the apex of said deflector, and having a crushing strength of at least 2500 p.s.i.
4. Protective footwear according to claim 3 wherein the included angle of said downwardly directed apex is about 112 degrees.
5. Protective footwear according to claim 4 wherein said lower section has an outsole configuration beneath said deflector having alternate ridges and grooves which are perpendicular to the longitudinal axis of said lower section whereby the surface area of the outsole that comes into contact with the ground is reduced thereby reducing the gross impulse transmitted to the foot from an underfoot explosion.
6. Protective footwear according to claim 1 having a layer of non-elastic, shock-absorbing material of substantially uniform thickness extending over and covering said p Wall, and a thin sheet of non-shatterable material covst g i l yer.
1. Protective footwear to attenuate the'force of a blast 1 mine ontlie heel and arch of the footof the wearer there- 7. Protective footwear according to claim 6 wherein the included angle in said downwardly directed apex is in the range of about 60 degrees to about 140 degrees.
8. Protective footwear according to claim 7 wherein said non-elastic, shock-absorbing material is of honeycomb construction, having the longitudinal axis of the cells thereof oriented in the same direction as the apex of said deflector and having a crushing strength of at least 2500 p.s.i.
9. Protective footwear according to claim 8 wherein the included angle of said downwardly directed apex is about 112 degrees.
10. Protective footwear according to claim 9 wherein said sidewalls are formed of an integral sheet of high tensile strength, non-shatterable material.
11. Protective footwear according to claim 10 wherein said high tensile strength, non-shatterable material is steel having a thickness of from about to about A, wherein said honeycomb material has a crushing strength of from about 2500 p.s.i. to about 5000 p.s.i.
12. Protective footwear according to claim 9 wherein said lower section has an outsole configuration beneath said deflector having alternate ridges and grooves which are perpendicular to the longitudinal axis of said lower section whereby the surface area of the outsole that comes into contact with the ground is reduced thereby reducing the gross impulse transmitted to the foot from an underfoot explosion 13. Protective footwear according to claim 12 wherein said sidewalls are formed of an integral sheet of high tensile strength, non-shatterable material, wherein said high tensile strength, non-shatterable material is stainless steel having a thickness of from about to about A", and wherein said non-elastic shock-absorbing material is an aluminum honeycomb having a crushing strength of from about 2500 p.s.i. to about 5000 p.s.i.
References Cited by the Examiner UNITED STATES PATENTS References Cited by the Applicant UNITED STATES PATENTS 5/1962 Kennedy et a1. 11/1962 Barron.
PATRICK D. LAWSON, Primary Examiner.

Claims (1)

1. PROTECTIVE FOOTWEAR TO ATTENUATE THE FORCE OF A BLAST FROM AN UNDERFOOT EXPLOSION OF AN ANTI-PERSONNEL LAND MINE ON THE HEEL AND ARCH OF THE FOOT OF THE WEARER THEREOF COMPRISING AN UPPER SECTION AND A LOWER SECTION TO FORM THE HEEL, SHANK AND SOLE PORTIONS OF SAID FOOTWEAR, SAID LOWER SECTION EMBODYING AN ELONGATED BLAST-RESISTANT DEFLECTOR, WEDGE-SHAPED IN TRANSVERSE SECTION, EXTENDING OVER SUBSTANTIALLY ALL OF THE HEEL AND SHANK PORTIONS THEREOF, SAID DEFLECTOR COMPRISING SIDEWALLS OF HIGH TENSILE STRENGTH, NON-SHATTERABLE MATERIAL FORMED TO DEFINE A WEDGE OPEN AT THE TOP AND HAVING THE APEX THEREOF DIRECTED DOWNWARDLY, A SHEET OF HIGH TENSILE STRENGTH, NON-SHATTERABLE MATERIAL EXTENDING ACROSS AND COVERING THE OPEN TOP OF SAID DEFLECTOR AND FORMING THE TOP WALL THEREOF, AND THE INTERIOR OF SAID DEFLECTOR BEING FILLED WITH NON-ELASTIC SHOCK, SHOCK-ABSORBING MATERIAL.
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Cited By (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3668792A (en) * 1971-01-08 1972-06-13 William A York Breakaway athletic safety shoe
WO1999004216A1 (en) 1997-07-18 1999-01-28 Med-Eng Systems Inc. Anti-personnel mine foot protection systems
US6006646A (en) * 1997-07-18 1999-12-28 Med-Eng Systems Inc. Anti-personnel mine foot protection systems
EP1016355A3 (en) * 1998-12-29 2000-09-20 Guy Andrew Vaz Protective boot and sole structure and method of making a metal matrix composite material
EP1216393A1 (en) * 1999-09-07 2002-06-26 The Commonwealth Of Australia Protective footwear against landmine
US6655051B1 (en) * 1999-02-22 2003-12-02 Anonymate Appliance for protecting against the effects of explosive devices
US6952990B1 (en) * 2002-09-16 2005-10-11 Niitek Inc. Land mine overpass tread design
US20060000117A1 (en) * 2002-05-31 2006-01-05 Joynt Vernon P Protective footwear
US20090037049A1 (en) * 2007-07-31 2009-02-05 Clodfelter James F Damage control system and method for a vehicle-based sensor
US20090090024A1 (en) * 2007-10-03 2009-04-09 Banpan Research Laboratory Co. Ltd. Boots for minimizing injury from explosives
US7683821B1 (en) 2006-10-25 2010-03-23 Niitek, Inc. Sensor sweeper for detecting surface and subsurface objects
US8047117B1 (en) * 2007-04-13 2011-11-01 Wright Materials Research Company Composite blast wave attenuators for boots
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US20140150293A1 (en) * 2011-06-17 2014-06-05 David J. Millar Mine resistant combat boot, blast mitigating
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Cited By (20)

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US3668792A (en) * 1971-01-08 1972-06-13 William A York Breakaway athletic safety shoe
WO1999004216A1 (en) 1997-07-18 1999-01-28 Med-Eng Systems Inc. Anti-personnel mine foot protection systems
US6006646A (en) * 1997-07-18 1999-12-28 Med-Eng Systems Inc. Anti-personnel mine foot protection systems
EP1405577A3 (en) * 1998-12-29 2005-06-01 BfR Holdings Limited Protective boot and sole structure and method of making a metal matrix composite material
EP1016355A3 (en) * 1998-12-29 2000-09-20 Guy Andrew Vaz Protective boot and sole structure and method of making a metal matrix composite material
US6655051B1 (en) * 1999-02-22 2003-12-02 Anonymate Appliance for protecting against the effects of explosive devices
EP1216393A4 (en) * 1999-09-07 2003-01-15 Commw Of Australia Protective footwear against landmine
EP1216393A1 (en) * 1999-09-07 2002-06-26 The Commonwealth Of Australia Protective footwear against landmine
US20060000117A1 (en) * 2002-05-31 2006-01-05 Joynt Vernon P Protective footwear
US7530181B2 (en) * 2002-05-31 2009-05-12 Csir Protective footwear
US6952990B1 (en) * 2002-09-16 2005-10-11 Niitek Inc. Land mine overpass tread design
US8374754B2 (en) 2005-12-05 2013-02-12 Niitek, Inc. Apparatus for detecting subsurface objects with a reach-in arm
US7683821B1 (en) 2006-10-25 2010-03-23 Niitek, Inc. Sensor sweeper for detecting surface and subsurface objects
US8047117B1 (en) * 2007-04-13 2011-11-01 Wright Materials Research Company Composite blast wave attenuators for boots
US20090037049A1 (en) * 2007-07-31 2009-02-05 Clodfelter James F Damage control system and method for a vehicle-based sensor
US8140217B2 (en) 2007-07-31 2012-03-20 Niitek, Inc. Damage control system and method for a vehicle-based sensor
US20090090024A1 (en) * 2007-10-03 2009-04-09 Banpan Research Laboratory Co. Ltd. Boots for minimizing injury from explosives
US20140150293A1 (en) * 2011-06-17 2014-06-05 David J. Millar Mine resistant combat boot, blast mitigating
US9127914B2 (en) * 2011-06-17 2015-09-08 David J. Millar Mine resistant combat boot, blast mitigating
USD776003S1 (en) 2014-11-07 2017-01-10 The United States Of America As Represented By The Secretary Of The Army Light tactical vehicle hull

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