US1481946A - Directional signal receiving - Google Patents

Directional signal receiving Download PDF

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US1481946A
US1481946A US245567A US24556718A US1481946A US 1481946 A US1481946 A US 1481946A US 245567 A US245567 A US 245567A US 24556718 A US24556718 A US 24556718A US 1481946 A US1481946 A US 1481946A
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sound
tubes
receiving
screen
conducting
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US245567A
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Robert L Williams
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Submarine Signal Co
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Submarine Signal Co
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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01SRADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
    • G01S1/00Beacons or beacon systems transmitting signals having a characteristic or characteristics capable of being detected by non-directional receivers and defining directions, positions, or position lines fixed relatively to the beacon transmitters; Receivers co-operating therewith
    • G01S1/72Beacons or beacon systems transmitting signals having a characteristic or characteristics capable of being detected by non-directional receivers and defining directions, positions, or position lines fixed relatively to the beacon transmitters; Receivers co-operating therewith using ultrasonic, sonic or infrasonic waves

Definitions

  • y present invention relates to the receipt and transmisw sion of such sounds acoustically to the observer, that is, by means of apparatus which is mechanical or rather acoustical in its nature, relying mainly upon the receipt and transmission of compressional waves by mechanical means.
  • Figure 1 shows a longitudinal section of a cylindrical screen' containing my invention
  • Fig. 2 a cross section on line 2-2 of Fi l. e ig. 3 shows diagrammaticall a way 1n which three of my devices may e mounted with relation to each other on board ship.
  • Fig. 4 is a form of overboard apparatus in whichvtwo sets of similar receivers are used, screened from each other.
  • Fig. 5 is a section 0n the line 5--5 of Fig. 4, and.
  • Fig.l 6 a section on line 6 6 of Fig. 5.. ln Figs. 1 and 2, A is the casing which 1s made of cylinders a of wood or metal spaced at the ends and at any other desired points by spacers a1 which serve not only to hold the cylinders in concentric positions but also to make, chambers az'lwhich shall be tight and, being lled with air or the hke, will serve with the cylinders a as a sound screen 1n a manner now well known.
  • the receiving mechanism which as shown comprises ⁇ four tubes C,C,1, C2 and C3 open at both ends and connected with tubes C4 and C5.
  • These tubes ,Cit and C5 are connected with a tube Ce which in turn is connected with the tube C7 leading to any convenient point and terminating in any convenient earpiece, of which there are many well known.
  • This tube C7 passes out through the side wall of the casing and is fastened in place by a spacing block c and nut c1 or in ⁇ any other convenient way.
  • each tube C, C1, C2 and C3 is closed b a watertight cap D, which may be of any esired shape and of any material so long as it is sensitive to compressional waves arriving through the water.
  • this closure comprises a cap of rubber or the like which is slipped over the end of the tube forming a membrane which is responsive to each sound wave" which strikes it and by its vibration excites compressional waves inthe tubular system of which it is a art.
  • tubes C, 1, C2, C3 in Fig. 1 are of the saine length, points of connection between them and the tubes C* and C5, it will be noted, are not similarly placed; for example, the connection between C and C is longer than the connection between C1 and C4. ln other tubes the arrangement is similar as can be seen from the drawings. Moreover, the tube C7 is not joined to C8 at its middle point. The purpose of this construction is to cause all the sounds received by the membranes of the service caps D to reac the observer at the same phase. Thus by making the path of the compressional wave between the observer and the cap D somewhat longer than the path between the observer and the cap D7 the distance between the caps D and D7 will be compensated for.
  • FIG. 3 A convenient way of using such a device on board ship is shown in Fig. 3 where E is 'the ship and F is a water tank therein in which three' of these devices A. are suspended below the Water line. ln this case, While the devices are stationary, sounds can be heard from three directions and by turning the ship according to the direction from which the sound seems to come the strongest, the direction of its source can easily be 'determined.
  • Figsl a, 5 and l6 l have shown another means ot mounting tubes.
  • the purpose is to receive sounds coming to the side of the device, no compensa-tion is provided for, the corresponding caps being all the saine distance from C7.
  • two sets of tubes are mounted one on each side of a sound screen J, constructed each outof tubes, bein lettered as in Figs. l and 2 C10, C, C12 an C13 and supported from tubes C, C, C and C", the ends of the tubes C1", C, C12 and C13 being closed as before by caps l), D1, etc.
  • these views G, G are what are called fairing pieces, which serve as the support for the various paths.
  • '.lhe airing pieces are located one on each side of the sound screen l and bolted together through theY sound screen by screws wLach airing piece has a recess H in which the tubes are located and suitable passages it through the tubes C lead to the pilot house or the point ot observation.
  • l also prefer to rovide this device with a protecting tube mounted on its top through which the tubes C pass up and by which. the device may be suspended in open water.
  • 'llhe caps D may be made of any vibratory material, though preferably of rubber, and of any shape which will keep thc tubes free from Water and Aat the same time will transmit the vibrations received to the observer so that the observer may get the result.
  • a subaqueous sound receiving device comprising a tubular sound screen closed at one end by said sound screen and exposed at the other end to the sound conducting inedium, a plurality of receivers positioned at points within the said tubular sound screen, conducting tubes, a main tube, said conductmeinte ing tubes connecting said receivers with said main tube, said receivers, said conducting tubes, said inain tube. all containing a compressible fluid, said receivers being positioned so that the sound coming to the main tube from said receivers is in phase.
  • a subaqueous sound receiving device comprising a tubular sound screen closed at one end by said sound screen and exposed at the other end tothe sound conducting medium, a plurality of receiving tubes positioned at points Within the said tubular sound screen, said receiving tubes containing a compressible fluid,each tube having a vibratory closure at the outer end thereof, a plurality of conducting tubes, a main tube, said conducting tubes connecting the receivingA tubes to said main tube. said receiving tubes being positioned so that the sound coming to the main tube from the said receiving tubes is substantially in phase.
  • a subaqueous sound receiving device comprising a tubular sound screen closed at one end by said sound screen and exposed at the other end to the sound conducting medium, a plurality of receiving tubes positioned in a line parallel with the -aXis o't said sound screen Within said tubular sound screen, said receiving tubes containing a compressible fluid, each receiving .tube having a vibratory closure at the outer end thereof, 'a plurality of conducting tubes, a inain tube, said conducting tubes connecting the receiving tubes to said main tube, said receiving tube bein posi-tioned so that the sound coming to t e main tube from the said receiving tubes is substantialy in phase.
  • a subaqueous sound receiving device comprising a tubular sound screen closed at one end by said sound screen and exposed at the other end to the sound conducting medium, the inner Walls of said sound screen labutting against the subaqueous sound medium, a plurality of receiving tubes positioned in a line parallel with the axis oit said sound screen Within said tubular sound screen, said receiving tubes containing a coinpressible Huid other than the subaqueous sound medium, each reiving tube having a vibratory closurelat the outer end thereof, a plurality oit conducting tubes, a main tube, said conducting tubes connecting the receiving tubes -to said main tube, said main tube extending through the wall of the sound screen and supporting in a xed position said ssound screen whereby a rotation of the main tube Will change the direction of the sound screen.
  • a subaqueous sound receiving device comprising a tubular sound screen closed at one end by said lsound screen and exposed at the other end to the sound conducting medium, the inner Walls of said sound screen abutting against the subaqueous sound medium, a plurality of receiving tubes posi- Maaate tioned in a line parallel with the axis of said sound screen within said tubular sound screen, said receiving tubes containing a compressible duid other than the subaqueous sound medium, each of said receiving tubes having a vibratory closure at the outer end thereof, a plurality of conducting tubes, a main tube, said conducting tubes connecting the said receiving tubes to said main tube, said conducting tubes and main tube forming a rigid structure, said main tube extending through the wall of the sound screen and supporting said sound screen, said conducting tubes and main tube being in a fixed position with reference to the sound screen.
  • a tubular sound screen comprising concentric tubes sealed at one end and open to the sound conducting medium at the other end, said outer end having the space between the concentric tubes sealed from the sound conducting medium whereby the volume between the concentric tubes is entirely sea-led from the sound conducting medium.
  • a subaqueous sound directional receiving device comprising a tubular sound screen closed at one endby said sound screen and exposed at the other end to the sound conducting medium, the inner walls of said sound screen abutting against the subaqueous sound medium, a lurality of receiving tubes positioned in a iine parallel with the axis of said sound screen within said tubular sound screen, said receiving tubes containing ⁇ a compressible iiuid other than the subaqueous sound medium, each of said receiving tubes having a vibratory closure at the outer end thereof, a plurality of conducting tubes, a main tube, said conducting tubes connecting the said receiving tubes to said main tube, said conducting tubes and said main tube forming a rigid structure, said main tube extending through the wall of the sound screen and supporting said sound screen, said conducting tubes and main tube being in a fixed position with reference to the sound screen, said receiving tubes being positioned .whereby the sound wave front traveling perpendicular to the axis of the tube is transmitted by the said receiving tubes to the main tube in phase and where

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  • Engineering & Computer Science (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Radar, Positioning & Navigation (AREA)
  • Remote Sensing (AREA)
  • Building Environments (AREA)

Description

Jan. 29; 1924.` 1,481,946-
R. L. WILLIAMS DRECTIONAL S IGNAL RECEIVING Maw y 1595/ figue/Veys:
Jan.' 29, 1924.
. R. L. WILLIAMS DIRECTIONAL SGNAL RECEIVING 2 Sheets-Sheet 2 Filed July 18, 1918 Patented dan. 29, i924.
narran rar ROBERT WILLIAMS, F NEWJVTON, MASSACHUSETTS, ASSIGNOR T0 SUBMARINE SIG- NAL COMPANY, 0F PRTLAND, MAINE, A CORPRATION 0F MAINE.
DIRECTIGNAL SIGNAL RECEIVING.
Application led July 18, 1918. Serial No. 245,567.
To all whom t may concern.'
Be it known that l, ROBERT L. 1Wittmann of Newton, in the county of Middlesex and State of Massachusetts, a citizen of the a United States, have invented a new and use ful Improvement in Directional Signal Receiving, of which the following is a specification.
While several devices are available for delo tecting the direction from whichsignals or other sounds are received, especially in submarine work, they are mainl based on the use of electricalapparatus. y present invention relates to the receipt and transmisw sion of such sounds acoustically to the observer, that is, by means of apparatus which is mechanical or rather acoustical in its nature, relying mainly upon the receipt and transmission of compressional waves by mechanical means. In an application for a United States patent filed by me April 25, 1918, Serial No. 230,802, have shown and described apparatus by which sounds 'from a given point strike various diaphragme located in the sides of a vessel at varying distances apart and are lcommunicated to a microphone by paths which are of dierent lengths, thus compensating for the dilierence apart of the diaphragms and hence'for S0 the length of travel of the sounds before reaching the microphone.
My invention will be understood by reference to the drawings in which it is shown.
in its preferred form.
Figure 1 shows a longitudinal section of a cylindrical screen' containing my invention, and Fig. 2 a cross section on line 2-2 of Fi l. e ig. 3 shows diagrammaticall a way 1n which three of my devices may e mounted with relation to each other on board ship.
Fig. 4 is a form of overboard apparatus in whichvtwo sets of similar receivers are used, screened from each other.
Fig. 5 is a section 0n the line 5--5 of Fig. 4, and.
Fig.l 6 a section on line 6 6 of Fig. 5.. ln Figs. 1 and 2, A is the casing which 1s made of cylinders a of wood or metal spaced at the ends and at any other desired points by spacers a1 which serve not only to hold the cylinders in concentric positions but also to make, chambers az'lwhich shall be tight and, being lled with air or the hke, will serve with the cylinders a as a sound screen 1n a manner now well known.
Une end of this casing is closed preferably with a conical closure B ofsimilar construction, b being conical partitions, b1 being the spacers therefor and 62 being the air spaces between them.
Within the casing is mounted the receiving mechanism which as shown comprises `four tubes C,C,1, C2 and C3 open at both ends and connected with tubes C4 and C5. These tubes ,Cit and C5 are connected with a tube Ce which in turn is connected with the tube C7 leading to any convenient point and terminating in any convenient earpiece, of which there are many well known. This tube C7 passes out through the side wall of the casing and is fastened in place by a spacing block c and nut c1 or in `any other convenient way.
The end of each tube C, C1, C2 and C3 is closed b a watertight cap D, which may be of any esired shape and of any material so long as it is sensitive to compressional waves arriving through the water. In its preferred form and as shown this closure comprises a cap of rubber or the like which is slipped over the end of the tube forming a membrane which is responsive to each sound wave" which strikes it and by its vibration excites compressional waves inthe tubular system of which it is a art.
While the tubes C, 1, C2, C3 in Fig. 1 are of the saine length, points of connection between them and the tubes C* and C5, it will be noted, are not similarly placed; for example, the connection between C and C is longer than the connection between C1 and C4. ln other tubes the arrangement is similar as can be seen from the drawings. Moreover, the tube C7 is not joined to C8 at its middle point. The purpose of this construction is to cause all the sounds received by the membranes of the service caps D to reac the observer at the same phase. Thus by making the path of the compressional wave between the observer and the cap D somewhat longer than the path between the observer and the cap D7 the distance between the caps D and D7 will be compensated for.
ln using one of these devices it is lowered overboard and turned about the tube C7 as an axis until it reaches a point at which the loudest sound is heard. ,llt will then be pointing to the source of sound, the Screening castitl ing A serving to lreep ott sounds from other directions. llt is desirable that the outside of the casing be made of a fairly heavy material to prevent damage to the device.
A convenient way of using such a device on board ship is shown in Fig. 3 where E is 'the ship and F is a water tank therein in which three' of these devices A. are suspended below the Water line. ln this case, While the devices are stationary, sounds can be heard from three directions and by turning the ship according to the direction from which the sound seems to come the strongest, the direction of its source can easily be 'determined.
ln Figsl a, 5 and l6 l have shown another means ot mounting tubes. As in this case the purpose is to receive sounds coming to the side of the device, no compensa-tion is provided for, the corresponding caps being all the saine distance from C7. ln this case two sets of tubes are mounted one on each side of a sound screen J, constructed each outof tubes, bein lettered as in Figs. l and 2 C10, C, C12 an C13 and supported from tubes C, C, C and C", the ends of the tubes C1", C, C12 and C13 being closed as before by caps l), D1, etc. ln these views G, G are what are called fairing pieces, which serve as the support for the various paths. '.lhe airing pieces are located one on each side of the sound screen l and bolted together through theY sound screen by screws wLach airing piece has a recess H in which the tubes are located and suitable passages it through the tubes C lead to the pilot house or the point ot observation. l also prefer to rovide this device with a protecting tube mounted on its top through which the tubes C pass up and by which. the device may be suspended in open water.
l do not mean to limit my invention to the precise construction shown, as other constructions may embody the principles of my invention. 'llhe caps D may be made of any vibratory material, though preferably of rubber, and of any shape which will keep thc tubes free from Water and Aat the same time will transmit the vibrations received to the observer so that the observer may get the result.
While the form of my invention shown in Figs. 4f and 5 is especially designed for reoeiving sounds coming in laterally, by substituting tubes like those shown in llig. l compensation for dead-ahead receiving will be had.
What l claim as my invention is l. A subaqueous sound receiving device comprising a tubular sound screen closed at one end by said sound screen and exposed at the other end to the sound conducting inedium, a plurality of receivers positioned at points within the said tubular sound screen, conducting tubes, a main tube, said conductmeinte ing tubes connecting said receivers with said main tube, said receivers, said conducting tubes, said inain tube. all containing a compressible fluid, said receivers being positioned so that the sound coming to the main tube from said receivers is in phase.
2. A subaqueous sound receiving device comprising a tubular sound screen closed at one end by said sound screen and exposed at the other end tothe sound conducting medium, a plurality of receiving tubes positioned at points Within the said tubular sound screen, said receiving tubes containing a compressible fluid,each tube having a vibratory closure at the outer end thereof, a plurality of conducting tubes, a main tube, said conducting tubes connecting the receivingA tubes to said main tube. said receiving tubes being positioned so that the sound coming to the main tube from the said receiving tubes is substantially in phase.
3. A subaqueous sound receiving device comprising a tubular sound screen closed at one end by said sound screen and exposed at the other end to the sound conducting medium, a plurality of receiving tubes positioned in a line parallel with the -aXis o't said sound screen Within said tubular sound screen, said receiving tubes containing a compressible fluid, each receiving .tube having a vibratory closure at the outer end thereof, 'a plurality of conducting tubes, a inain tube, said conducting tubes connecting the receiving tubes to said main tube, said receiving tube bein posi-tioned so that the sound coming to t e main tube from the said receiving tubes is substantialy in phase.
d: A subaqueous sound receiving device comprising a tubular sound screen closed at one end by said sound screen and exposed at the other end to the sound conducting medium, the inner Walls of said sound screen labutting against the subaqueous sound medium, a plurality of receiving tubes positioned in a line parallel with the axis oit said sound screen Within said tubular sound screen, said receiving tubes containing a coinpressible Huid other than the subaqueous sound medium, each reiving tube having a vibratory closurelat the outer end thereof, a plurality oit conducting tubes, a main tube, said conducting tubes connecting the receiving tubes -to said main tube, said main tube extending through the wall of the sound screen and supporting in a xed position said ssound screen whereby a rotation of the main tube Will change the direction of the sound screen.
5. A subaqueous sound receiving device comprising a tubular sound screen closed at one end by said lsound screen and exposed at the other end to the sound conducting medium, the inner Walls of said sound screen abutting against the subaqueous sound medium, a plurality of receiving tubes posi- Maaate tioned in a line parallel with the axis of said sound screen within said tubular sound screen, said receiving tubes containing a compressible duid other than the subaqueous sound medium, each of said receiving tubes having a vibratory closure at the outer end thereof, a plurality of conducting tubes, a main tube, said conducting tubes connecting the said receiving tubes to said main tube, said conducting tubes and main tube forming a rigid structure, said main tube extending through the wall of the sound screen and supporting said sound screen, said conducting tubes and main tube being in a fixed position with reference to the sound screen.
6. A tubular sound screen comprising concentric tubes sealed at one end and open to the sound conducting medium at the other end, said outer end having the space between the concentric tubes sealed from the sound conducting medium whereby the volume between the concentric tubes is entirely sea-led from the sound conducting medium.
7. A tubular sound screen-comprising concentric tubes sealed at one end and open to the sound conducting medium at the other end, said outer end having the space between the concentric tubes sealed from the sound conducting medium whereby the volume between the concentric tubes is'entirely sealed from' the sound conducting medium, and spgcers positioned between the concentric tu es.
8. A subaqueous sound directional receiving device comprising a tubular sound screen closed at one endby said sound screen and exposed at the other end to the sound conducting medium, the inner walls of said sound screen abutting against the subaqueous sound medium, a lurality of receiving tubes positioned in a iine parallel with the axis of said sound screen within said tubular sound screen, said receiving tubes containing` a compressible iiuid other than the subaqueous sound medium, each of said receiving tubes having a vibratory closure at the outer end thereof, a plurality of conducting tubes, a main tube, said conducting tubes connecting the said receiving tubes to said main tube, said conducting tubes and said main tube forming a rigid structure, said main tube extending through the wall of the sound screen and supporting said sound screen, said conducting tubes and main tube being in a fixed position with reference to the sound screen, said receiving tubes being positioned .whereby the sound wave front traveling perpendicular to the axis of the tube is transmitted by the said receiving tubes to the main tube in phase and whereby the maximum sound energy is transmitted to the receiving tubes when the sound screen has its axis perpendicular to and facing the approaching sound wave.
RUERT L. WHJLAMS.
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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2447333A (en) * 1931-12-30 1948-08-17 Us Navy Ultra-audible sound reception

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2447333A (en) * 1931-12-30 1948-08-17 Us Navy Ultra-audible sound reception

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