US2431846A - Wood core magnetostriction hydrophone - Google Patents

Wood core magnetostriction hydrophone Download PDF

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US2431846A
US2431846A US526789A US52678944A US2431846A US 2431846 A US2431846 A US 2431846A US 526789 A US526789 A US 526789A US 52678944 A US52678944 A US 52678944A US 2431846 A US2431846 A US 2431846A
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hydrophone
coil
wood core
tube
magnetostriction
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US526789A
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Albert L Thuras
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B06GENERATING OR TRANSMITTING MECHANICAL VIBRATIONS IN GENERAL
    • B06BMETHODS OR APPARATUS FOR GENERATING OR TRANSMITTING MECHANICAL VIBRATIONS OF INFRASONIC, SONIC, OR ULTRASONIC FREQUENCY, e.g. FOR PERFORMING MECHANICAL WORK IN GENERAL
    • B06B1/00Methods or apparatus for generating mechanical vibrations of infrasonic, sonic, or ultrasonic frequency
    • B06B1/02Methods or apparatus for generating mechanical vibrations of infrasonic, sonic, or ultrasonic frequency making use of electrical energy
    • B06B1/08Methods or apparatus for generating mechanical vibrations of infrasonic, sonic, or ultrasonic frequency making use of electrical energy operating with magnetostriction

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  • Hydrophones oiv this general nature are known and rely on magnetostrictive effect, as present for instance in nickel, to establish alternating changes in flux of the remnant magnetism of the magnetostrictive material when it is subjected to external alternating pressures.
  • the effect is produced by sound waves in water impinging on the hydrophone tube.
  • a coil is so placed with reference to the tube that an alternating E. M. F. will be generated in the coil as the fiux field of the tube is alternately changed as indicated above.
  • This E. M. F. may be amplified and reproduced as desired by the person who seeks to interpret the meaning 'of the sound waves causing the disturbance.
  • the object of the present invention has been to provide an improved hydrophone which will most efficiently pick up and transmit the impulse of the sound waves-which strike 'it.
  • Another object of the invention has been to Provide a hydrophone in which the turns of the coil winding are as close as possible to the inner wall of the tube.
  • a further object of the invention has been to provide a simple, compact andrugged hydrophone of the character described which will be easy to manufacture and service.
  • Fig. 1 is a brokenyiew, partly in section, of a.
  • Fig. 2 is a section through the hydrophone as indicated by lines 2! on Fig. 1, and;
  • Fig. 3 is a section through Fig, 1 as indicated by diameter of the hydrophone tube is a determin ing factor in the resonance of the device and this resonance varies inversely as the tube diameter. Diameters of two and three inches have given ood results.
  • transformer 1 and 3 extending from one side of the cylinder III to the other and in contact with both.
  • This core while preferably laminated, may be granular in composition. It may also be made of one piece 7 of transformer iron, although this construction positioned closely adjacent its inner surface.
  • the cores preferably are made of soft wood.
  • a series of spacing pegs l8 are provided at each end of the semlcylindrical pieces l4 (Figs. 1 and 2).
  • a series of turns 20 are first wound transversely of the ends of the core and lengthwise of the tube III as shown. The turns are so-placed that the exposed surfaces of the dielectric cores between two pairs of the pegs I! are covered.
  • a secondportion 22 of the coil is then wound on the wood cores, at its ends overlapping the first winding 20, as well as the ends of the iron core. This winding, as shown in Fig: 2, lies between two other sets 'of pegs It.
  • caps 2t and 28 are provided, each snugly fitting over'an end of the tube III as shown.
  • the cap 25 is provided with a central opening through which is passed a pair of leads 20 and 21 connected to the coil.
  • a piece of soft rubber containing the leads, and or considerably. greater diameter than the opening is stretched lengthwise and pulled through. It is thenrallowed to resume its original shape, at which time it over-. lies the edges of the cap opening as shown in Fi 1.
  • Instruments of this type have been built in various sizes, ranging for example from 5 inches to 8 and 4 feet in length, and in diameter 2 or 3 inches.
  • In winding the coils enameled wire was used.
  • the coils were wound in three layers in the units 5 inches long, while in the longest hydrophone a single layer was employed.
  • a magnetostrictive transducer for transforming the compressional waves in a fluid medium into corresponding electrical signals comprising, a casing of magnetic material capable of having its residual magnetic field vary proportionally to the force of the compressional waves acting on the casing, an iron core substantially the other section of the coil,- the side portions of the wires of the coil being parallel to each other and disposed adiacentthe inner walls of the easing to have induced therein a potential proportional to the varying magnetic field.
  • a magnetostrictive transducer for transforming the compressional waves in a fluid medium into corresponding electrical signals comcasing and extending laterally across the casing from wall to wall, a dielectric core to space and support-a coil, and a coil wound about the ends of the core in two sections.
  • the end portions of the wires in each section of the coil being parallel with each other, the said end Portions of one section of the coil forming an X with the said end portions of the other section or the coil, the side portions of the wires or the coil being parallel to each other and disposed adjacent the inner walls of the casing to have induced therein a potential proportional to the varying magnetic field.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Transducers For Ultrasonic Waves (AREA)

Description

ZABLQ A. L. THURA5 WOOD CORE MAGNETOSTRICTION HYDROPHONE Filed March 16, 1.944
INVENTOR fi/berf L. 77141748 BY 77/ 'ITORN Patented Dec. 2, 1947 WOOD CORE MAGNETOSTRICTION HYDROPHONE Albert L. Thuras, New London, Conn, assignor to United States of Ameri Secretary of the Navy ca, as represented by the I application March'ld, 1944, Serial No. 528,789 I 2 Claims. 177-386) This invention relates to underwater hydrophones of the tubular magnetostrictive type and as such represents an improvement on the disclosure set forth in application Serial No. 519,233, filed January 21, 1944.
Hydrophones oiv this general nature are known and rely on magnetostrictive effect, as present for instance in nickel, to establish alternating changes in flux of the remnant magnetism of the magnetostrictive material when it is subjected to external alternating pressures. The effect is produced by sound waves in water impinging on the hydrophone tube. To make practical use of this effect, a coil is so placed with reference to the tube that an alternating E. M. F. will be generated in the coil as the fiux field of the tube is alternately changed as indicated above. This E. M. F. may be amplified and reproduced as desired by the person who seeks to interpret the meaning 'of the sound waves causing the disturbance.
The object of the present invention has been to provide an improved hydrophone which will most efficiently pick up and transmit the impulse of the sound waves-which strike 'it. Another object of the invention has been to Provide a hydrophone in which the turns of the coil winding are as close as possible to the inner wall of the tube. .A further object of the invention has been to provide a simple, compact andrugged hydrophone of the character described which will be easy to manufacture and service. Other objects will be apparent from the following description and from the features which, believed to be novel, are hereafter set out. 1
In the annexed drawings:
Fig. 1 is a brokenyiew, partly in section, of a.
hydrophone built in accordance with the present invention; Y
Fig. 2 is a section through the hydrophone as indicated by lines 2! on Fig. 1, and;
Fig. 3 is a section through Fig, 1 as indicated by diameter of the hydrophone tube is a determin ing factor in the resonance of the device and this resonance varies inversely as the tube diameter. Diameters of two and three inches have given ood results.
In order to provide for maximum flux transmission inside the'tube, a series of transformer 1 and 3. extending from one side of the cylinder III to the other and in contact with both. This core while preferably laminated, may be granular in composition. It may also be made of one piece 7 of transformer iron, although this construction positioned closely adjacent its inner surface. To
position the turns a pair of semicylindrical dielectric cores are provided as shown at It in Fig. 3.
Although various insulating materials may be used, the cores preferably are made of soft wood.
It is necessary that the turns of the coil cut across the iron core I! in order that the flux field itself be cut. To permit the coil to be wound in this way, a series of spacing pegs l8 are provided at each end of the semlcylindrical pieces l4 (Figs. 1 and 2). In winding the coil a series of turns 20 are first wound transversely of the ends of the core and lengthwise of the tube III as shown. The turns are so-placed that the exposed surfaces of the dielectric cores between two pairs of the pegs I! are covered. A secondportion 22 of the coil is then wound on the wood cores, at its ends overlapping the first winding 20, as well as the ends of the iron core. This winding, as shown in Fig: 2, lies between two other sets 'of pegs It.
To eifectively seal the hydrophone at each end, caps 2t and 28 are provided, each snugly fitting over'an end of the tube III as shown. The cap 25 is provided with a central opening through which is passed a pair of leads 20 and 21 connected to the coil. To provide an effective seal where the leads pass through the cap a piece of soft rubber containing the leads, and or considerably. greater diameter than the opening, is stretched lengthwise and pulled through. It is thenrallowed to resume its original shape, at which time it over-. lies the edges of the cap opening as shown in Fi 1.
As examples of hydrophones which have been built in accord with this invention some have been designed to have an impedance of 6 or '7 millihenrles at a frequency of 5000 cycles per second. It may be noted here that in a device of this nature the impedanceof the system varies considerably with the particular frequency at which the hydrophone is used. erally desirable to listen over a considerable portion of the sound spectrum, the unit should be so iron laminations it are provided as shown in Figs. designed that the best response is obtained in the Although it is gen- 7 desired spectrum band In general, the greater the number of turns 01 wire in the winding, the higher will be the impedance at a given frequency.
Instruments of this type have been built in various sizes, ranging for example from 5 inches to 8 and 4 feet in length, and in diameter 2 or 3 inches. In winding the coils enameled wire was used. The coils were wound in three layers in the units 5 inches long, while in the longest hydrophone a single layer was employed.
Iclaim: 1. A magnetostrictive transducer for transforming the compressional waves in a fluid medium into corresponding electrical signals comprising, a casing of magnetic material capable of having its residual magnetic field vary proportionally to the force of the compressional waves acting on the casing, an iron core substantially the other section of the coil,- the side portions of the wires of the coil being parallel to each other and disposed adiacentthe inner walls of the easing to have induced therein a potential proportional to the varying magnetic field.
2. A magnetostrictive transducer for transforming the compressional waves in a fluid medium into corresponding electrical signals comcasing and extending laterally across the casing from wall to wall, a dielectric core to space and support-a coil, and a coil wound about the ends of the core in two sections. the end portions of the wires in each section of the coil being parallel with each other, the said end Portions of one section of the coil forming an X with the said end portions of the other section or the coil, the side portions of the wires or the coil being parallel to each other and disposed adjacent the inner walls of the casing to have induced therein a potential proportional to the varying magnetic field.
ALBERT L. THURAS.
REFERENCES crran .The following references are of record in the file of this patent:
UNITED STATES PATENTS 4 Number Name l Date 1,985,251 Hayes Dec.- 25, 1934 2,153,571 4 Ka11rneyer;.. a Apr. 11, 1939 2,249,835 Lakatos July 22, 1941 FOREIGN ram-rs Number Country Date 101,140 Sweden Mar, 18, 1941 394,994 Great Britain July 5, 1933 607,048 "Germany June 29, 1935
US526789A 1944-03-16 1944-03-16 Wood core magnetostriction hydrophone Expired - Lifetime US2431846A (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2708742A (en) * 1952-04-22 1955-05-17 Harris Transducer Corp Hydrophone cable

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB394994A (en) * 1932-01-05 1933-07-05 Charles Vickery Drysdale Improvements in and relating to magneto-striction transmitters and receivers for the transmission and reception of sound
US1985251A (en) * 1928-11-21 1934-12-25 Harvey C Hayes Method and means for determining the velocity of a moving body
DE607048C (en) * 1934-06-03 1935-06-29 Atlas Werke Akt Ges Ring-shaped oscillation structure excited by magnetostrictive forces to radial oscillations in its natural frequency
US2153571A (en) * 1935-04-13 1939-04-11 Atlas Werke Ag Vibratory system for the transmission and reception of sound waves
US2249835A (en) * 1937-11-11 1941-07-22 Bell Telephone Labor Inc Magnetostrictive vibrator

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1985251A (en) * 1928-11-21 1934-12-25 Harvey C Hayes Method and means for determining the velocity of a moving body
GB394994A (en) * 1932-01-05 1933-07-05 Charles Vickery Drysdale Improvements in and relating to magneto-striction transmitters and receivers for the transmission and reception of sound
DE607048C (en) * 1934-06-03 1935-06-29 Atlas Werke Akt Ges Ring-shaped oscillation structure excited by magnetostrictive forces to radial oscillations in its natural frequency
US2153571A (en) * 1935-04-13 1939-04-11 Atlas Werke Ag Vibratory system for the transmission and reception of sound waves
US2249835A (en) * 1937-11-11 1941-07-22 Bell Telephone Labor Inc Magnetostrictive vibrator

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2708742A (en) * 1952-04-22 1955-05-17 Harris Transducer Corp Hydrophone cable

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