RU2338088C1 - Auxiliary hydraulic-jet device - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: device incorporates water duct arranged in the ship bow bulb housing appliance of converting mechanical energy in hydraulic-jet power representing a set of chambers arranged one above the other in the said water duct lengthwise section and in symmetry with the said duct lengthwise axis. Every chamber incorporates an inlet water-intake hole, the chamber walls forming the nozzles narrowing streamwise and furnished with outlet holes. The proposed device incorporates one central chamber, two external upper and lower chambers and, at least, two internal upper and lower chambers the water duct chamber side walls are formed by the bulb lateral walls. The water duct chamber upper and lower walls represent lengthwise-curvilinear and horizontal-section plates. The central chamber inlet accommodates two concave curvilinear plates arranged in symmetry with the water duct lengthwise axis. The inlet of every internal chamber houses a curvilinear plate concave relative to the water duct lengthwise axis.

EFFECT: conversion of ship heaving and pitching energy into hydraulic-jet power, ship stabilisation in storm.

1 dwg

Description

The invention relates to a device for converting wave energy, in particular for converting ship vibrational energy into hydroreactive energy, including under stormy conditions while reducing the pitch of the auxiliary hydroreactive device together with the device on which it is installed, for example a vessel.

A device is known to reduce the drift velocity of a vessel, comprising vertical input channels located in the bow bulb symmetrically with respect to the vessel’s diametrical plane, connected by rotary elbows with the corresponding horizontal output channels to create a traction force during keel rolling of the vessel, which reduces the vessel’s drift speed (see RU patent No. 2184047, 06/27/2002).

This device allows you to use the wave energy only when keel pitching, which narrows its capabilities.

The closest to the invention in technical essence and the achieved result is an auxiliary hydroreactive device located in the bow of the vessel and made in the form of a water jet, located symmetrically to the diametrical plane of the vessel and containing side fairings, while between the fairings there is a channel in which the working body of the propulsion device is installed and the channel itself is branched into two symmetrical waterways directed into the stern of the vessel and exiting between the sides and side fairings, The channel is made in the form of slots with vertical walls, and the working body consists of rotors with the possibility of rotation with reverse (see patent RU No. 2228874, 05.20.2004).

This device creates a hydroreactive force. However, to drive the device, it is required to use part of the energy of the ship's propulsion system, which reduces the efficiency of using this device.

The problem to which the present invention is directed, is the use of all wave energy, regardless of the angle of incidence of the flow on the device along its longitudinal axis.

The technical result achieved by the implementation of the invention is to increase the efficiency of its use when converting wave energy into hydroreactive energy.

This problem is solved, and the technical result is achieved due to the fact that the hydroreactive device contains a conduit made in the bow bulb of the vessel, in which there is a means for converting mechanical energy into hydroreactive, the latter made in the form of chambers located one above the other in a vertical longitudinal section plane and symmetrically relative to the longitudinal axis of the water conduit, each chamber is made with an inlet water inlet, and the walls of the chambers form nozzles tapering downstream of the outlet holes, the device contains one central chamber, two external chambers, the upper and lower chambers and at least two internal chambers, the upper and lower chambers, the side walls of the water conduit chambers are formed by the side walls of the bulb, and the upper and lower walls of the water conduit chambers are formed curved in the longitudinal direction and horizontal in the cross section of the plates, the inlet of the upper and lower outer chambers are respectively made one in the upper and the other in the lower walls of the bulb and opposite to each other, the inlet of the upper and lower inner chambers are inclined to the longitudinal axis of the conduit, and the inlet of the central chamber is vertically perpendicular to the longitudinal axis of the conduit, and the inlet of the inner and central chambers are made in front of the bulb, the upper and lower walls, respectively, of the upper and lower outer chambers are made concave relative to the longitudinal axis of the water conduit, the upper and lower curved walls, respectively, of the upper and lower inner chambers, common with the lower and upper wall of the upper and lower outer chambers, respectively, are made of smoothly curved plates with a section convex relative to the longitudinal axis of the water conduit from the inlet of each of the chambers, the lower and upper curved walls, respectively, of the upper and lower inner chambers form respectively the upper and lower walls of the central chamber and are made of smoothly curved plates with a portion convex relative to the longitudinal axis of the water conduit from the input two concave curvilinear plates symmetrically with respect to the longitudinal axis of the water conduit, and a curved curved plate with respect to the longitudinal axis of the water conduit is installed at the entrance to each inner chamber.

During the tests, it was found that the combination of water inlets made in the upper, lower and front walls, and inclined inlet water inlets located symmetrically relative to the longitudinal axis of the device’s water conduit between them in front of the nose bulb allows full use of wave energy and the incident to a flow device for converting them into hydroreactive energy. The device installed on the vessel below its waterline in the bow bulb allows the energy of the vertical and pitching of the vessel to be converted into hydro-reactive energy, which, in turn, makes it possible to stabilize the position of the vessel in stormy navigation conditions and also reduce the pitching of the vessel. In addition, the device, combined with the positive qualities of the bulb to reduce hydraulic resistance to the movement of the vessel, converts the wave energy into the hydro-reactive energy of the water jet, which, when the vessel is in forward motion, can compensate for part of the speed loss when the vessel moves in stormy conditions against the wave, without increasing screw speed, which allows you to reduce fuel consumption.

The drawing shows an axonometric image of a hydroreactive device with a conditionally transparent side wall of the bulb (the contour of the "transparent" side wall of the bulb and the contour of the bow of the vessel are shown in thin lines).

The hydroreactive device comprises a conduit 3 made in the bow bulb 1 of the vessel 2, in which the means for converting mechanical energy into hydroreactive is located. The latter is made in the form of chambers 4, 5, 6, 7 and 8, located one above the other in the vertical longitudinal plane of the cross section of the water conduit 3 and symmetrically with respect to its longitudinal axis. Each chamber 4, 5, 6, 7, and 8 is made with an inlet water inlet, respectively, 9, 10, 11, 12, and 13, and the walls of the chambers 4, 5, 6, 7, and 8 form nozzles tapering downstream with the outlet openings 14, 15, 16, 17 and 18, wherein the device comprises one central chamber 6, two outer upper 4 and lower 8 chambers, and at least two inner upper 5 and lower 7 chambers. The side walls of the chambers 4, 5, 6, 7 and 8 of the water conduit 3 are formed by the lateral 19 and 20 walls of the bulb 1, and the upper and lower walls of the chambers 4, 5, 6, 7 and 8 of the water conduit 3 are formed by curvilinear in the longitudinal direction and horizontal in the transverse section by plates. The inlet openings 9 and 13 of the upper 4 and lower 8 of the outer chambers are respectively made one in the upper 21, and the other in the lower 22 walls of the bulb 1 and are facing opposite to each other. The water inlet openings 10 and 12 of the upper 5 and lower 7 inner chambers are inclined to the longitudinal axis of the water conduit 3, and the water inlet 11 of the central chamber 6 is vertically perpendicular to the longitudinal axis of the water conduit 3, and the water inlet openings 10, 12 and 11 of the inner 5, 7 and the central 6 chambers are made in front of the bulb 1. The upper and lower walls, respectively, of the upper 4 and lower 8 of the outer chambers are concave relative to the longitudinal axis of the conduit 3, the upper and lower curved walls, respectively, of the upper 5 and the lower 7 inner chambers, common with the lower and upper wall of the upper 4 and lower 8 outer chambers, respectively, are made of smoothly curved plates with a section convex relative to the longitudinal axis of the water conduit 3 from the inlet port 10 and 12 of each of the chambers 5 and 7. The lower and the upper curved walls of the upper 5 and lower 7 of the inner chambers, respectively, form the upper and lower walls of the central chamber 6, respectively, and are made of smoothly curved plates with a section convex relative to the longitudinal axis of the water conduit 3 with a hundred ones of the input water intake opening 11, while in the central chamber 6 at the inlet portion thereof mounted symmetrically relative to the longitudinal axis of the conduit 3, two concave curved plate 23, and at the entrance to each inner chamber 5 and 7 is curved concave relative to the longitudinal axis of the conduit plate 24.

The hydroreactive device is located below the waterline in the bow bulb and is oriented in the forward direction of the vessel.

The hydroreactive device can be made of the same material from which the ship’s hull (steel, light alloy, fiberglass, etc.) is made using the same technologies, using the same equipment and the same staff of a shipbuilding or ship repair enterprise.

A hydroreactive device is able to realize its capabilities when the vessel oscillates in the direction of the vertical axis (floating) and angular oscillations around the transverse axis (pitching).

The conversion of the pumping energy into a reactive stop occurs as a result of filling the chambers 4, 5, 6, 7 and 8 of the device with water and pushing the water streams with the pressure of the incoming water through the nozzles formed by these chambers 4, 5, 6, 7 and 8, and the output of the flows through the weekend openings 14, 15, 16, 17 and 18 and further through the outlet openings of the water conduit 3 at a speed greater than when entering the chambers 4, 5, 6, 7 and 8, and in the direction opposite to the forward motion of the vessel, creating a hydrodynamic stop .

Essentially, the device mounted on the hull of the vessel acts as an additional hydro-jet propulsion, utilizing the energy of the mass fluctuations of the vessel in the incident wave and giving the vessel an additional “emphasis” when driving forward against the wave.

As an example, a more detailed description of the operation of a hydroreactive device according to the version of the vessel’s oscillations around the transverse axis (pitching) is proposed.

When the bulb 1 and the bow of the vessel 2 move forward and upward in the water column, the hydroreactive device installed in the bulb 1 moves forward and upward. Water enters the upper (outer and inner) chambers 4 and 5 and the central chamber 6. Partially, water enters the lower (inner and outer) chambers 7 and 8.

At the entrance to the chambers 4, 5 and 6 through the inlet openings 9, 10 and 11, the water flows are under the pressure of the water running on the device from the inlet openings 9, 10 and 11. The spoilers formed by the convex inlet portions of the plates on the walls of the chambers 5 , 6 and 7 and forming the input transverse edge, holding the incoming water at the inlet of the Central chamber 6 and the inner chamber 5, contribute to the preservation of the pressure in the Central chamber 6 and the inner chamber 5.

The oncoming water pressure ensures the passage of flows through chambers 4, 5 and 6, which change the movement of water flows in a predetermined direction along the vessel, as well as creating conditions for the passage of water flows through the narrowing (confuser) nozzles to maintain a higher compression pressure than at the entrance, the speed of flow at the outlet of chambers 4, 5 and 6.

When water flows through chambers 4, 5 and 6, the pumping energy of the vessel 2 in combination with the incident wave energy ensures the advancement of flows and pressure maintenance, which allows the wave energy to be converted into a hydroreactive force directed horizontally along the vessel 2.

When the fore end of the vessel moves forward and down, the hydroreactive device installed on the fore end of the vessel moves forward and down. Water is intensively supplied to the central chamber 6, as well as to the lower (outer and inner) chambers 7 and 8. Partially, water enters the upper (inner and outer) chambers 4 and 5. Otherwise, the same processes of converting wave energy into hydro-reactive energy occur at the outlet of chambers 6, 7 and 8 of the device and, accordingly, at the outlet of conduit 3, as described above regarding cameras 4, 5 and 6.

In addition, the hydroreactive device, damping disturbing forces swinging the vessel, helps to stabilize the position of the vessel and reduce the pitching of the vessel, especially in stormy conditions.

The present invention can be used wherever there is a need to convert wave energy into hydroreactive energy, primarily in the shipbuilding industry.

Claims (1)

A hydroreactive device containing a conduit made in the bow of the vessel, in which there is a means for converting mechanical energy into hydroreactive, characterized in that the means for converting mechanical energy into hydroreactive is made in the form of chambers located one above the other in the vertical longitudinal plane of the cross section of the conduit and symmetrically with respect to it the longitudinal axis, each chamber is made with an inlet water inlet, and the walls of the chambers form nozzles tapering in the direction of flow with the outlet holes, the device contains one central chamber, two outer chambers, the upper and lower chambers, and at least two inner chambers, the upper and lower chambers, the side walls of the water conduit chambers are formed by the side walls of the bulb, and the upper and lower walls of the water conduit chambers are formed by curved in the longitudinal direction and with horizontal plates in the cross section, the inlet openings of the upper and lower outer chambers are made respectively one in the upper and the other in the lower walls of the bulb and facing opposite to each other, the inlet of the upper and lower inner chambers are inclined to the longitudinal axis of the conduit, and the inlet of the central chamber is vertically perpendicular to the longitudinal axis of the conduit, and the inlet of the inner and central chambers are made in front of the bulb, the upper and lower walls, respectively, of the upper and lower the lower outer chambers are made concave relative to the longitudinal axis of the conduit, the upper and lower curved walls, respectively, of the upper and lower internal chambers, common with the lower and upper walls of the upper and lower outer chambers, respectively, are made of smoothly curved plates with a section convex relative to the longitudinal axis of the water conduit from the inlet of each of the chambers, the lower and upper curved walls, respectively, of the upper and lower inner chambers the upper and lower walls of the central chamber and are made of smoothly curved plates with a section convex relative to the longitudinal axis of the water conduit on the inlet water side orifice, while in the central chamber at its inlet section two concave curvilinear plates are installed symmetrically with respect to the longitudinal axis of the water conduit, and a curved curved plate with respect to the longitudinal axis of the water conduit is installed at the entrance to each inner chamber.