1. Field of the Invention
WO2006/075167 and WO2009/122184 (both the Secretary of State for Defence and both incorporated herein by reference) describe, inter-alia, acoustic reflectors which can be used in a variety of ways to mark underwater structures, objects or geological features.
2. Discussion of Prior Art
These applications describe an acoustic reflector comprising a shell surrounding a core, said shell being capable of transmitting acoustic waves incident on the surface of the shell into the core to be focused and reflected from an area of the shell located opposite to the area of incidence so as to provide a reflected acoustic signal output from the reflector, having a core in which the shell is dimensioned relative to the core such that a portion of the acoustic waves incident on the shell wall are coupled into the shell and guided therein around the circumference of the shell and then re-radiated to combine constructively with the said reflected acoustic signal output so as to provide an enhanced reflected acoustic signal output in which the acoustic wave speed in the core is between 840 metres per second and 1500 metres per second. However, such reflectors are normally omni-directional, and can provide little information about the specific reflector concerned, its environment or the relative position of the source of acoustic waves with respect to the reflector.
According to this invention, an acoustic reflector comprises a shell around a core, portions at least of said shell being capable of transmitting acoustic waves incident on the shell into the core to be focused and reflected from an area of the shell located opposite to the area of incidence of the acoustic waves so as to provide a reflected acoustic signal output from the reflector, and in which incident acoustic radiation will be differentially reflected depending on the portion of the reflector on which the incident acoustic radiation impinges.
Preferably the acoustic reflector is in the form of an object of rotation about a central axis, so that it can be mounted and turned, or allowed to turn to provide a pulsed reflection at one or more different frequencies which are characteristic of the reflector or its environment. Suitable reflector shapes include spheres, right cylinders or tubes, right cones, or ovoids.
In one embodiment the acoustic reflector has a core material having a compressional wave speed of from 840 to 1500 ms−1 and a shell dimensioned relative to the core such that a portion of the acoustic waves incident on portions of the shell are coupled into the shell and guided therein around the circumference of the shell and then re-radiated to combine constructively with the said reflected acoustic signal output to provide an enhanced reflected acoustic signal output.
In another embodiment the shell is dimensioned relative to the core such that a portion of the acoustic waves incident on at least one portion of the shell are coupled into the shell wall and guided therein around the circumference of the shell and then re-radiated to combine constructively with the said reflected acoustic signal output to provide an enhanced reflected acoustic signal output.
In such an embodiment best results are obtained if velocity of the wave transmission in the core to the velocity of the wave transmission in the shell is in the range of about 2.5:1 to 3.4:1, inclusive, or a multiple thereof.
In still further embodiment an acoustic reflector comprises a shell surrounding a core, said shell being capable of transmitting acoustic waves incident on the surface of the shell into the core to be focused and reflected from an area of the shell located opposite to the area of incidence so as to provide a reflected acoustic signal output from the reflector, having a core in which the shell is dimensioned relative to the core such that a portion of the acoustic waves incident on the shell wall are coupled into the shell and guided therein around the circumference of the shell and then re-radiated to combine constructively with the said reflected acoustic signal output so as to provide an enhanced reflected acoustic signal output in which the ratio of the speed of the wave transmission in the core to the speed of the wave transmission in the shell is in the range of about 3:1 and 3.2:1, inclusive, or a multiple harmonic thereof.
The core of the acoustic reflector may be formed of one or more concentric layers of a solid material. In another embodiment the core has parallel layers of materials having different compressional wave speeds.
In a further embodiment part of the surface of the shell is covered by an acoustic absorbing material that will absorb incident acoustic at frequencies at which the reflector would otherwise be reflective.
If the acoustic reflector is a right cylinder, the acoustic absorbing material can be arranged in parallel strips on the surface of the cylinder parallel to the central axis of the cylinder. Rotation to the cylinder will provide a reflected acoustic wave characteristic of the width and separation of the strips and the speed of rotation.
If the acoustic reflector is a sphere, the acoustic absorbing material is arranged in segments on its surface.
The core can be formed from one or more elastomer materials, by having different elastomer materials in different layers of a core, the physical behaviour of the core in different areas will differ for different acoustic frequencies. Thus parts of the core can respond to and transport an acoustic wave at one frequency that will combine constructively with a portion of the same wave that has been transmitted around the shell, but other parts will transport the wave in a way that will recombine destructively at the same frequency with the portion that has been transmitted around the shell wall, and thus little or no reflection is obtained. It can be seen that by varying frequency of the acoustic signal and the direction between the source of the acoustic wave and the reflector, the reflected signal, and the frequency at which a reflected signal is obtained can provide information about the spatial relationship between the source of the signal and the reflector.
Suitable materials for the core can include silicone rubbers such as an RTV12 or RTV655 silicone rubbers. In this case the shell is may be formed from a rigid material. Steel is possible as is glass reinforced plastics (GRP) or glass filled polyamide or glass filled nylon. The core material may, alternatively, be metal with a metallic shell provided that the ratio of the speed of the wave transmission in the core to the speed of the wave transmission in the shell is in the range of about 2.5:1 to 3.4:1, inclusive, or a multiple thereof.
In one embodiment of the invention an acoustic reflector is shaped in such a way that incoming acoustic waves impinging on parts of the surface will be scattered and not reflected. A right cone an example of such a shape, acoustic waves directed at the point will be scattered, simply acoustic waves directed at the base will be scattered, the same will occur on the inclined sides of the cone nearest the point and base, however incoming acoustic waves impinging on the middle portion of the inclined sides will be reflected. An ovoid shape will work in a similar way.
Devices of this invention can be used as markers to indicate specific directions to approach underwater objects, to help in final navigation towards an object or to provide directional information. As an example an underwater valve may be marked with a reflector of this invention. The pipeline to which the valve is connected may be marked more generally with omni-directional reflectors to indicate to a submersible its position. The directional reflector attached to the valve can be used by the submersible to indicate the correct direction from which to approach the valve safely.
Another application of the devices of this invention would be to provide an underwater “lighthouse”. If a reflector capable of reflecting acoustic signals in one or more specific directions is rotatably mounted and powered or fitted with a fin to cause it to rotate in a marine current, it will reflect a pulsing signal when interrogated acoustically. The rate of rotation or the position of the absorbent materials will give the reflected acoustic signals a particular pulsed characteristic by which the reflector concerned can be identified. As in a “lighthouse” the characteristic can be used to give location information.
Another application of this invention would be to mark the sites of underwater channels or passages between fixed objects, say, wrecks or underwater cliff. The characteristics of the reflectors on one side of the channel can be different from those on the other side to act in a similar way as red and green lights on buoys marking sea channels.
The invention will now be described with reference to the accompanying drawings in which:
In
The shell 12 is formed from a rigid material such as a glass reinforced plastics (GRP) material or steel. The core 16 is formed from a solid material such as an elastomer. The frequency, or range of frequencies, at which the acoustic reflector is applicable is dependent on predetermined combinations of materials, used to form the shell and core, and the relative dimensions thereof.
However, as will be appreciated by the reader, other combinations of materials may be used provided the shell and core are dimensioned relative to each other in accordance with the wave propagating properties of the materials used.
Incident acoustic waves 18, transmitted from an acoustic source (not shown), are incident on the shell 12. Where the angle of incidence is high most of the acoustic waves 18 are transmitted through the shell wall 14, into the core 16. As the acoustic waves 18 travel through the core 16 they are refracted and thereby focused onto an opposing side 20 of the shell, from which the acoustic waves 18 are reflected back, along the same path, as a reflected acoustic signal output 22. However, where the angle of incidence is smaller, at a coupling region 24 of the shell, i.e. at a sufficiently shallow angle relative to the shell, a portion of the incident waves 18 is coupled into the wall 14 to provide shell waves 26 which are guided within the wall 14 around the circumference of the shell 12.
The materials which form the shell 12 and the core 16 and the relative dimensions of the shell and core are predetermined such that the transit time of the shell wave 26 is the same as the transit time of the internal geometrically focused returning wave (i.e. the reflected acoustic signal output 22). Therefore, the contributions of the shell wave, which is re-radiated, and the reflected acoustic signal output are in phase with each other and therefore combine constructively at a frequency of interest to provide an enhanced reflected acoustic signal output (i.e. high target strength). That is to say, for a spherical acoustic reflector the circumference of the shell is the path length and therefore must be dimensioned in accordance with the respective transmission speed properties of the shell and the core, such that resonant standing waves are formed in the shell which are in phase with the reflected acoustic signal output to combine constructively therewith.
Preferably, the core is formed from a single solid material having a wave speed between 840 ms−1 and 1300 ms−1. Alternatively, the core may comprise two or more layers of different materials where, for a particular selected frequency of the acoustic waves, these would provide either more effective focussing of the incoming waves and/or lower attenuation within the material so as to result, overall, in a stronger output signal. Naturally, however, the complexity and costs of manufacture in the case of a layered core would be expected to be greater. Where the core is formed of two or more layers of different materials, either or both of the materials may have a wave speed of up to 1500 ms−1.
To be suitable for use in the reflector device of the invention, the core material must be such that it exhibits a wave speed in the required range without suffering from a high absorption of acoustic energy. The core may be formed from an elastomer material such as, for example, a silicone, particularly RTV12 or RTV655 silicone rubbers from Bayer or Alsil 14401 peroxide-cured silicone rubbers.
The shell may be formed of a rigid material, such as, for example, a glass reinforced plastics (GRP) material, particularly a glass filled nylon such as 50% glass filled Nylon 66, “Zytel” ®-33% glass reinforced nylon, or 40% glass filled semi-aromatic polyamide, or steel and may be dimensioned such that its thickness is approximately one-tenth of the radius of the core. However, the derivation of the appropriate relationship between these parameters in relation to the characteristics of the materials used for the core and shell will be readily understood by the skilled person.
It will be appreciated by the reader that different combinations of solid core and rigid shell materials may be used provided they are dimensioned to provide shell waves which are in phase with the reflected acoustic signal output such that they combine constructively therewith.
Referring to
Acoustic waves 18, transmitted from an acoustic source (not shown), are incident as shown on the shell 12. The properties of the shell are selected in the manner previously described such that it exhibits two regions disposed around lines of latitude of the shell which act as transmission “windows”, i.e. such that the incident acoustic waves are in these regions efficiently transmitted through the shell 12 and into the core 16. Consequently the incident acoustic waves then follow two paths (19, 19′) as they travel through the core 16 and are refracted and thereby focused onto an area 20 of the opposing side of the shell from the side on which the acoustic waves 18 are incident. The waves are then reflected back, along the same respective paths and combine together to provide an enhanced reflected acoustic signal output 22 of the reflector.
For regions of the shell where the angle of incidence of the incoming acoustic wave is low, a portion of the incident waves 18 is coupled into the shell 12 and generates elastic waves 26 which are guided within the shell 12 around the circumference of the shell 12. Where the materials which form the shell 12 and the core 16 and the relative dimensions of the shell and core are predetermined such that the transit time of the shell wave 26 is the same as the transit time of the internal geometrically focused returning waves (19, 19′), the elastic wave travelling through the shell wall and the reflected acoustic signal output are in phase with each other and therefore combine constructively at a frequency of interest to provide a further enhanced reflected acoustic signal output 22 (i.e. a strong target response).
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In all the examples given, advantage may be taken of more recent developments described in UK Patent Applications GB Patent Applications 0913203.6, 0913388.5 and 0917714.8 published in WO2011/012877 by the present inventors to use a metal core and metal shell or other combinations of materials enabling the reflectors to operate at greater depths than is possible with the reflectors of WO 2006/075167 and WO2009/122184.
Number | Date | Country | Kind |
---|---|---|---|
0900668.5 | Jan 2009 | GB | national |
0913203.6 | Jul 2009 | GB | national |
0913388.5 | Jul 2009 | GB | national |
0917714.8 | Oct 2009 | GB | national |
1107588.4 | May 2011 | GB | national |
This application is a Continuation-in-Part of: (1) International Application No. PCT/GB2010/050058 filed in English on 15 Jan. 2010 claiming priority to GB Application No. 0900668.5 filed 16 Jan. 2009;(2) International Application No. PCT/GB2010/051161 filed in English on 16 Jul. 2010 claiming priority to GB Application No. 0913203.6 filed 29 Jul. 2009, GB Application No. 0913388.5 filed 31 Jul. 2009 and GB Application No. 0917714.8 filed 12 Oct. 2009; and(3) GB Application No. 1107588.4 filed 9 May 2011. The entire contents of these applications are incorporated herein by reference.
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Entry |
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International Preliminary Report on Patentability and Written Opinion of the International Searching Authority dated Jul. 19, 2011 for PCT/GB2010/050058. |
International Search Report for PCT/GB2010/050058, mailed Jan. 24, 2011. |
International Search Report for PCT/GB2010/051161, mailed Feb. 14, 2011. |
Number | Date | Country | |
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20110266089 A1 | Nov 2011 | US |
Number | Date | Country | |
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Parent | PCT/GB2010/050058 | Jan 2010 | US |
Child | 13067996 | US | |
Parent | PCT/GB2010/051161 | Jul 2010 | US |
Child | PCT/GB2010/050058 | US |