A ventilation drug reduction device includes a main housing, a first rectification assembly, a second rectification assembly, and a flow isolating assembly; the main housing is composed of a first segment, a second segment, a third segment, and a fourth segment; the first rectification assembly is composed of first rectification plates; the second rectification assembly is composed of at least one second rectification plate; the flow isolating assembly is arranged in a cavity of the third segment; the fourth segment is configured as an outlet end. On the premise that the total construction cost is not obviously increased, high-pressure gas is rectified in a cavity of the main housing, so that the turbulivity of the high-pressure gas is reduced, and a stable insulating gas layer is formed at the bottom of a hull; in addition, the present invention further discloses a marine ventilation drug reduction system.

A ventilation drug reduction device includes a main housing, a first rectification assembly, a second rectification assembly, and a flow isolating assembly; the main housing is composed of a first segment, a second segment, a third segment, and a fourth segment; the first rectification assembly is composed of first rectification plates; the second rectification assembly is composed of at least one second rectification plate; the flow isolating assembly is arranged in a cavity of the third segment; the fourth segment is configured as an outlet end. On the premise that the total construction cost is not obviously increased, high-pressure gas is rectified in a cavity of the main housing, so that the turbulivity of the high-pressure gas is reduced, and a stable insulating gas layer is formed at the bottom of a hull; in addition, the present invention further discloses a marine ventilation drug reduction system.

Disclosed is an air supply system for supplying air to an outside of a hull of a vessel holding a combustion engine. The air supply system comprises one or more air discharge units, ADUs, for releasing compressed air to an outside of the hull below a waterline of the vessel. The air supply system comprises a pump for generating a first flow of sea water. The airs supply system comprises an injector comprising a first inlet for receiving the first flow of sea water from the pump, a second inlet for receiving a second flow of gas from the combustion engine, an outlet for discharging a third flow of gas to the ARUs, and an expansion portion arranged downstream of the first inlet and the second inlet and upstream of the outlet. The injector is configured to mix the first flow of sea water and the second flow of gas into the third flow of gas and the expansion portion is configured to expand the third flow of gas to increase the pressure of the third flow of gas discharged from the injector through the outlet. The air supply system is configured to evaporate the first flow of sea water using thermal energy from the combustion engine so that the third flow of gas is enriched with steam from the first flow of sea water.

Disclosed is an air supply system for supplying air to an outside of a hull of a vessel holding a combustion engine. The air supply system comprises one or more air discharge units, ADUs, for releasing compressed air to an outside of the hull below a waterline of the vessel. The air supply system comprises a pump for generating a first flow of sea water. The airs supply system comprises an injector comprising a first inlet for receiving the first flow of sea water from the pump, a second inlet for receiving a second flow of gas from the combustion engine, an outlet for discharging a third flow of gas to the ARUs, and an expansion portion arranged downstream of the first inlet and the second inlet and upstream of the outlet. The injector is configured to mix the first flow of sea water and the second flow of gas into the third flow of gas and the expansion portion is configured to expand the third flow of gas to increase the pressure of the third flow of gas discharged from the injector through the outlet. The air supply system is configured to evaporate the first flow of sea water using thermal energy from the combustion engine so that the third flow of gas is enriched with steam from the first flow of sea water.

A ship resistance reduction apparatus using air is disclosed. The objective of the present invention is to spray air at the bottom side of a ship to cause generated bubbles to remain at the bottom side thereof, and thus reduce frictional resistance to water, so that an increase in sailing speed and an improvement in fuel efficiency are promoted. The present invention suctions the air generated during ship maneuvering without using a separate driving source while having a simple structure, to form, at the bottom side of the bottom of the ship, an air layer comprising air bubbles, and thus can be economically manufactured and increase operating efficiency.

A ship resistance reduction apparatus using air is disclosed. The objective of the present invention is to spray air at the bottom side of a ship to cause generated bubbles to remain at the bottom side thereof, and thus reduce frictional resistance to water, so that an increase in sailing speed and an improvement in fuel efficiency are promoted. The present invention suctions the air generated during ship maneuvering without using a separate driving source while having a simple structure, to form, at the bottom side of the bottom of the ship, an air layer comprising air bubbles, and thus can be economically manufactured and increase operating efficiency.

A low-cost viscous-drag-reducing cladding for a ship's hull comprising airbags whose outer surfaces are adapted to be water repelling. Each airbag comprises a plenum that comprises substantially open space, which does not obstruct the flow of air through it. The airbags are inflated with compressed air to a pressure higher than the adjoining hydrostatic pressure. The airbag material comprises a reinforcing fabric, which is adapted to withstand the forces encountered during operation, and is sealed with a sealant so as to be made substantially impermeable to air. The outer water-repelling surface of each airbag is connected to a plenum by means of restrictor holes. Air flows from the plenum through the restrictor holes into the water-repelling layer.

A low-cost viscous-drag-reducing cladding for a ship's hull comprising airbags whose outer surfaces are adapted to be water repelling. Each airbag comprises a plenum that comprises substantially open space, which does not obstruct the flow of air through it. The airbags are inflated with compressed air to a pressure higher than the adjoining hydrostatic pressure. The airbag material comprises a reinforcing fabric, which is adapted to withstand the forces encountered during operation, and is sealed with a sealant so as to be made substantially impermeable to air. The outer water-repelling surface of each airbag is connected to a plenum by means of restrictor holes. Air flows from the plenum through the restrictor holes into the water-repelling layer.

A number of different vehicle configurations are disclosed. An illustrative vehicle is disclosed to include a solid surfaced body having a front end, a propulsion unit that applies a propulsion force to the body and causes the front end to travel toward a traveling medium in a direction of travel, and at least one output port that is positioned on the body in such a way that fluid expelled from the at least one output port is expelled in a direction opposite to the propulsion force, wherein the fluid expelled from the at least one output port is expelled at a rate that is at least one order of magnitude less than a rate at which fluid is displaced by the propulsion unit.

A number of different vehicle configurations are disclosed. An illustrative vehicle is disclosed to include a solid surfaced body having a front end, a propulsion unit that applies a propulsion force to the body and causes the front end to travel toward a traveling medium in a direction of travel, and at least one output port that is positioned on the body in such a way that fluid expelled from the at least one output port is expelled in a direction opposite to the propulsion force, wherein the fluid expelled from the at least one output port is expelled at a rate that is at least one order of magnitude less than a rate at which fluid is displaced by the propulsion unit.