The invention provides a light guide element (1300) comprising a light guide (300) and a layer element (30), wherein the light guide (300) comprises a light guide face (301) and wherein the layer element (30) comprises an optical layer (310), wherein said optical layer (310) is in contact with at least part of the light guide face (301), wherein the optical layer (310) has a first index of refraction (n1) smaller than 1.36 at 280 nm, wherein the light guide (300) comprises a UV radiation transmissive light guide material (305).

A method that uses a tool specifically designed for removing weeds, milfoil, invasive species, or any other foreign matter from boat, pontoon, personal water craft trailers, dock, boat lift and the like. The tool incorporated within this method of removing weeds and the like from watercraft trailers is able to cut weeds in half or scrape weeds that are hanging on trailer beams allowing them to fall to the ground. It can hook or grab weeds pulling them off trailer beams. The tool can slide on trailer beams capturing weeds in the tool head, which can then be removed when the tool head is taken off the trailer beam. A rotating handle is incorporated allowing ease of use from many different angles.

A method that uses a tool specifically designed for removing weeds, milfoil, invasive species, or any other foreign matter from boat, pontoon, personal water craft trailers, dock, boat lift and the like. The tool incorporated within this method of removing weeds and the like from watercraft trailers is able to cut weeds in half or scrape weeds that are hanging on trailer beams allowing them to fall to the ground. It can hook or grab weeds pulling them off trailer beams. The tool can slide on trailer beams capturing weeds in the tool head, which can then be removed when the tool head is taken off the trailer beam. A rotating handle is incorporated allowing ease of use from many different angles.

A scraping tool having a thick, durable scraping blade attached to a weighted main body is particularly useful in scraping encrusted marine growth from seawalls, dock and pier pilings, and bridge structures is disclosed. A scraping blade formed of 316 Stainless Steel having a thickness of approximately 3/16, with a front end that is preferably angled approximately 15-degrees from the longitudinal axis of the tool arranges the blade for maximum effectiveness. The blade has teeth with each tooth defining a beveled upper tip surface to aid in piercing encrusted barnacle growth. The blade is attached to a weighted main body which further includes an axially projecting adaptor for connection to an extension pole. The weighted main body is partially filled with lead shot for enhancing impact forces.

A scraping tool having a thick, durable scraping blade attached to a weighted main body is particularly useful in scraping encrusted marine growth from seawalls, dock and pier pilings, and bridge structures is disclosed. A scraping blade formed of 316 Stainless Steel having a thickness of approximately 3/16, with a front end that is preferably angled approximately 15-degrees from the longitudinal axis of the tool arranges the blade for maximum effectiveness. The blade has teeth with each tooth defining a beveled upper tip surface to aid in piercing encrusted barnacle growth. The blade is attached to a weighted main body which further includes an axially projecting adaptor for connection to an extension pole. The weighted main body is partially filled with lead shot for enhancing impact forces.

The invention provides a light guide element (1300) comprising a light guide (300), wherein the light guide (300) in comprises a first light guide face (301) and a second light guide face (302) with UV radiation transmissive light guide material (305) between the first light guide face (301) and the second light guide face (302), wherein the light guide element (1300) further comprises one or more of: (i) a first layer element (30) in contact with the first light guide face (301), wherein the first layer element (30) is transmissive for UV radiation; and (ii) a second layer element (130) in contact with the second light guide face (301), wherein the second layer element (130) has one or more functionalities selected from the group consisting of (a) reflective for UV radiation, (b) adhesive for adhering the light guide (300) to an object, (c) reinforcing the light guide element (1300), and (d) protective for the light guide (300).

A cleaning device that passively self-adjusts to improve biofoul removal across curved, non-uniform, or irregular underwater surfaces. The cleaning device includes a motor, one or more shafts coupled to the motor and coupled to one another via at least one universal joint, and a cleaning mechanism for removing biofoul from the target surface. The cleaning device includes an alignment mechanism that restricts the cleaning mechanism's movement to improve biofoul removal. The alignment mechanism can include bearings, spring components, dampening material, adhesion components, floatation objects, or a combination thereof.

A cleaning device that passively self-adjusts to improve biofoul removal across curved, non-uniform, or irregular underwater surfaces. The cleaning device includes a motor, one or more shafts coupled to the motor and coupled to one another via at least one universal joint, and a cleaning mechanism for removing biofoul from the target surface. The cleaning device includes an alignment mechanism that restricts the cleaning mechanism's movement to improve biofoul removal. The alignment mechanism can include bearings, spring components, dampening material, adhesion components, floatation objects, or a combination thereof.

A system for blast-cleaning a barge deck, sides, and fittings providing for safety and avoidance of damage to the barge and to persons, where a barge is blast-cleaned with moving blaster units suspended from and traveling along an overhead track beam. In one embodiment, the moving blaster units are each controlled by a person in a moving operator capsule moving in tandem with a moving blaster unit. In another embodiment, the moving blaster units are robotically controlled from a robotic controller which has access to a three-dimensional plan of the barge, communicating with the robotic blaster units via RF antennae, and receiving real-time data from sensors located on each blaster head. Optionally, the system for blast-cleaning a barge can provide blaster-head cameras for real-time remote monitoring of operations and for recording of the operations allowing review of any issue, such as damage, that might arise.

A system for blast-cleaning a barge deck, sides, and fittings providing for safety and avoidance of damage to the barge and to persons, where a barge is blast-cleaned with moving blaster units suspended from and traveling along an overhead track beam. In one embodiment, the moving blaster units are each controlled by a person in a moving operator capsule moving in tandem with a moving blaster unit. In another embodiment, the moving blaster units are robotically controlled from a robotic controller which has access to a three-dimensional plan of the barge, communicating with the robotic blaster units via RF antennae, and receiving real-time data from sensors located on each blaster head. Optionally, the system for blast-cleaning a barge can provide blaster-head cameras for real-time remote monitoring of operations and for recording of the operations allowing review of any issue, such as damage, that might arise.