141 |
Torpedo-net. |
US16007917 |
1917-04-06 |
US1242611A |
1917-10-09 |
SMITH RICHARD JAMES |
|
142 |
Submarine-detector. |
US15436417 |
1917-03-12 |
US1242386A |
1917-10-09 |
STEWART WILLIAM A |
|
143 |
Torpedo-net. |
US1914877445 |
1914-12-15 |
US1240317A |
1917-09-18 |
CLARK EWEN A |
|
144 |
Ship protection against submarine explosions. |
US13567616 |
1916-12-07 |
US1237883A |
1917-08-21 |
ELIA GIOVANNI EMANUELE |
|
145 |
Guard device for vessels. |
US17320917 |
1917-06-06 |
US1235440A |
1917-07-31 |
COLEMAN WILLIAM J |
|
146 |
Torpedo-guard. |
US8447216 |
1916-03-15 |
US1204547A |
1916-11-14 |
CORRADO FRANK; DOYLE WILLIAM J |
|
147 |
Warship. |
US1910541185 |
1910-01-31 |
US956442A |
1910-04-26 |
SOLIANI NABOR |
|
148 |
cinamon |
US496598D |
|
US496598A |
1893-05-02 |
|
|
149 |
Ship-of-war |
US458340D |
|
US458340A |
1891-08-25 |
|
|
150 |
palmer |
US372761D |
|
US372761A |
1887-11-08 |
|
|
151 |
Torpedo-guard for vessels |
US247717D |
|
US247717A |
1881-09-27 |
|
|
152 |
Improved construction of war-vessels |
US41802D |
|
US41802A |
1864-03-01 |
|
|
153 |
photo-uthografhefl |
US38824D |
|
US38824A |
1863-06-09 |
|
|
154 |
Improvement in arming war-vessels |
US35193D |
|
US35193A |
1862-05-06 |
|
|
155 |
Underwater vehicle cutting apparatus |
US14528693 |
2014-10-30 |
US09550553B2 |
2017-01-24 |
James Wiggins; Chris Norkoski; Conrad Zeglin; Walter Allensworth |
The problem of penetrating through nets and other objects is solved by cutting the object using a linear cutting assembly having a linear cutter arm that moves in an arc and pivots about an attachment point. The object is cut by a severing action caused by a moveable blade of the linear cutting arm moving back and forth across a stationary blade of the linear cutter arm. An underwater vehicle modified to incorporate an embodiment of the linear cutting assembly can cut a sufficiently large opening in the object to allow the vehicle to pass through. |
156 |
APPARATUS AND METHOD FOR NEUTRALIZING UNDERWATER MINES |
US14990205 |
2016-01-07 |
US20160200409A1 |
2016-07-14 |
Scott W. FAIRFIELD; Kerry D. LAVIOLETTE; Donald J. ROBERTSON; Ronald D. ZAMOJSKI; Gary L. WIEDEMEIER; Joseph M. CUSCHIERI; Christopher E. MARCHANT |
A mine neutralizing device that includes a buoy. The buoy includes a mine neutralizing device capable of swimming to an undersea mine to neutralize it. A method for neutralizing undersea mines includes locating an undersea mine, placing a buoy containing a mine neutralizer near the mine, and swimming the mine neutralizer to the undersea mine. |
157 |
RIGID BALLISTIC COMPOSITES HAVING LARGE DENIER PER FILAMENT YARNS |
US14489082 |
2014-09-17 |
US20150000510A1 |
2015-01-01 |
Jason Aaron van Heerden |
A rigid ballistic-resistant composite includes large denier per filament (dpf) yarns. The yarns are held in place by a resin to form a rigid composite panel with improved ballistic performance. The large dpf yarns may be selected from aromatic heterocyclic co-polyamide fibers, polyester-polyarylate fibers, high modulus polypropylene (HMPP) fibers, ultra high molecular weight polyethylene (UHMWPE) fibers, poly(p-phenylene-2,6-benzobisoxazole) (PBO) fibers, poly-diimidazo pyridinylene (dihydroxy)phenylene (PIPD) fibers, carbon fibers, and polyolefin fibers. |
158 |
Method for Detecting Anomalies on a Submarine Object |
US13322085 |
2010-05-25 |
US20120103245A1 |
2012-05-03 |
Detlef Lambertus |
A method for detecting anomalies on a submarine object, in particular in the submarine region on a hull of a moored warcraft, which method carries out very reliable sensing of the submarine object by way of an unmanned small submarine vehicle that is equipped with simple sensor equipment, such as an acoustic sensor for measuring distances and a barometric cell for determining depth, and which method obtains a profile of the submarine object by navigating the small submarine vehicle with a constant transversal distance to the submarine object, in which profile an anomaly present on the submarine object becomes is apparent from the profile line. |
159 |
BALLISTIC COMPOSITES HAVING LARGE DENIER PER FILAMENT HIGH PERFORMANCE YARNS |
US12763678 |
2010-04-20 |
US20110023695A1 |
2011-02-03 |
Jason Aaron van Heerden |
According to some embodiments, there is provided a ballistic-resistant composite including a plurality of large denier per filament (dpf) yarns. The large dpf yarns may have a “Composite-Armor dpf factor” (CA•dpf) of greater than or equal to 6.9. |
160 |
DELIVERY SYSTEMS FOR PRESSURE PROTECTING AND DELIVERING A SUBMERGED PAYLOAD AND METHODS FOR USING THE SAME |
US12511676 |
2009-07-29 |
US20100107959A1 |
2010-05-06 |
Steven Craig Israel; Dominic Caza Germana; Craig A. Greiner; Frederick Vosburgh |
A payload delivery unit for protecting and delivering a payload submerged in a submersion medium comprises a container including a pressure resistant shell and a resilient seal device. The shell defines a containment chamber and includes first and second shell members having opposed first and second sealing faces, respectively. The seal device engages and is interposed between the first and second sealing faces. The container is configured and constructed such that: when the submersion medium applies an exterior pressure to the first and second shell members such that a shell pressure differential, defined as the exterior pressure less an interior pressure of the containment chamber, exceeds a prescribed pressure, the first and second shell members compressively load and deform the seal device to effect a seal between the first and second shell members that prevents ingress of the submersion medium into the containment chamber; and when the shell pressure differential is less than the prescribed pressure, the seal device elastically rebounds to separate the first and second shell members to permit ingress of the submersion medium into the containment chamber. |