Direct contact scanner and related method
First Claim
1. A method of imaging an object using a direct contact ultrasound scanner comprised of an ultrasound imaging mechanism that produces ultrasonic imaging waves, a radome adapted to directly contact the exterior surface of the object and permit passage of imaging waves between the scanner and the object, a waveguide having a transmission axis, a first end contacting the ultrasound imaging mechanism and a second end extending into a coupling medium that is contained by the radome and isolated from the ultrasound imaging mechanism, said method comprising:
- a. while holding the scanner in one hand, manipulating the scanner with the one hand to move the radome into direct contact with an external surface of the object;
b. generating ultrasonic imaging waves using the imaging mechanism;
c. conveying the ultrasonic imaging waves from the imaging mechanism to the object by passing the imaging waves through the waveguide into the coupling medium and out to the object through the radome;
d. conveying reflected ultrasonic imaging waves from the object to the ultrasound imaging mechanism using the radome, the coupling media and the waveguide; and
e. using the ultrasound imaging mechanism to generate an electronic image signal from the reflected ultrasonic imaging waves received from the object.
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Accused Products
Abstract
A direct contact scanner uses a fiber acoustic waveguide to convey ultrasound from an ultrasound transducer to a direct contact area. The waveguide extends from a main body of the scanner into an oblong nose, and terminates in a deflector. To minimize thickness of the nose, the waveguide and deflector are rotated about an ultrasound transmission axis of the waveguide, enabling the scanner to be used in a variety of situations where quarters are cramped. A coupling fluid conveys ultrasound between the deflector and a radome, which directly contacts the object to be scanned. Using the waveguide, an ultrasound transducer and supporting electronics may be distanced from the direct contact area and separated from the fluid, thereby insulating the fluid from possible electronic leakage currents and heat.
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Citations
21 Claims
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1. A method of imaging an object using a direct contact ultrasound scanner comprised of an ultrasound imaging mechanism that produces ultrasonic imaging waves, a radome adapted to directly contact the exterior surface of the object and permit passage of imaging waves between the scanner and the object, a waveguide having a transmission axis, a first end contacting the ultrasound imaging mechanism and a second end extending into a coupling medium that is contained by the radome and isolated from the ultrasound imaging mechanism, said method comprising:
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a. while holding the scanner in one hand, manipulating the scanner with the one hand to move the radome into direct contact with an external surface of the object;
b. generating ultrasonic imaging waves using the imaging mechanism;
c. conveying the ultrasonic imaging waves from the imaging mechanism to the object by passing the imaging waves through the waveguide into the coupling medium and out to the object through the radome;
d. conveying reflected ultrasonic imaging waves from the object to the ultrasound imaging mechanism using the radome, the coupling media and the waveguide; and
e. using the ultrasound imaging mechanism to generate an electronic image signal from the reflected ultrasonic imaging waves received from the object. - View Dependent Claims (2, 3, 4, 5, 6)
i. the direct contact ultrasound scanner further comprises a sweep mechanism coupled to the waveguide and isolated from the coupling medium and a deflector coupled to the second end of the waveguide;
ii. in step d, the deflector deflects the reflected ultrasonic imaging waves from the object into the waveguide along the transmission axis and the sweep mechanism rotates both the waveguide and the deflector, so that the reflected ultrasonic imaging waves directed into the waveguide encompass a sweep sector having an angular width; and
iii. in step e, the electrical image signal is isolated from the coupling medium.
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3. The method of claim 2, wherein the scanner further comprises an angle encoder that generates a synchronization signal for the electronic image signal in step e.
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4. The method of claim 2, wherein the scanner further comprises a sector control mechanism that varies the angular width of the sweep sector in step d.
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5. The method of claim 2, wherein in step d, the sweep mechanism rotates the waveguide in an oscillatory fashion and the waveguide is rotated less than 360°
- between two angular positions.
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6. The method of claim 1, wherein:
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i. the ultrasound imaging mechanism is an ultrasound transducer and the scanner further comprises control electronics coupled to the ultrasound transducer; and
ii. the control electronics cause the transducer to produce ultrasound in discrete bursts, to detect the reflected imaging waves when ultrasound is not being produced by the transducer, and to responsively produce the electronic image signal.
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7. A direct contact ultrasound scanner for use in scanning an object through direct contact with the object'"'"'s exterior, comprising:
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a. an ultrasound transducer which is excited by electrical signals;
b. a coupling medium;
c. a direct contact area which is transparent to ultrasound and provides an interface between the coupling medium and the exterior of the object;
d. an ultrasound waveguide having a transmission axis, a first end that contacts the transducer and a second end that extends into the coupling medium; and
e. a sweep mechanism connected to the waveguide and capable of rotating the waveguide in a manner to sweep a section having an angular width that encompasses at least a portion of the object wherein;
the ultrasound transducer is isolated from the direct contact area and out of direct electrical contact with the coupling medium; and
wherein the scanner is adapted to be held in one hand while being operated by the one hand to bring the direct contact area into direct contact with an external surface of an object.- View Dependent Claims (8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21)
i. the entire waveguide and the deflector are rotationally moved about the transmission axis by the sweep mechanism; and
ii. the sweep mechanism and the ultrasound transducer are both insulated from the coupling medium.
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9. The direct contact ultrasound scanner of claim 8, wherein the deflector comprises an angular termination of the second end of the waveguide.
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10. The direct contact external ultrasound scanner of claim 7, wherein the waveguide is a cladded fiber acoustic waveguide having a core portion and a cladding portion.
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11. The direct contact ultrasound scanner of claim 10, wherein the cladding portion has a thickness such that the cladded fiber acoustic waveguide has a diameter at least four times the predetermined diameter.
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12. The direct contact ultrasound scanner of claim 10, wherein the core portion is made of doped fused quartz, and the cladding portion is made of fused quartz.
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13. The direct contact ultrasound scanner of claim 10, wherein the core portion and the cladding portion are each made of a silicate material.
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14. The direct contact ultrasound scanner of claim 10, wherein the core portion is made of a metal material.
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15. The direct contact ultrasound scanner of claim 10, wherein the core portion is made of a sapphire material.
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16. The direct contact ultrasound scanner of claim 7, further comprising a sector control mechanism that selectively varies the angular width of the sweep of the waveguide to define a sector being imaged within the section.
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17. The direct contact ultrasound scanner of claim 7, wherein:
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i. the coupling media is a liquid that transmits ultrasound;
ii. the waveguide is a solid material; and
iii. the direct contact area is a radome that is transparent to ultrasound and retains the liquid within the scanner.
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18. The direct contact ultrasound scanner of claim 17, wherein said scanner further comprises electronics that cause the ultrasound transducer to produce outgoing ultrasound imaging waves in discrete bursts, to detect reflected imaging waves returning from the object when the ultrasound transducer is not producing outgoing ultrasound imaging waves;
- and to produce an image output signal in response to the reflected incoming ultrasound imaging waves.
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19. The direct contact ultrasound scanner of claim 7, wherein the transducer produces ultrasound of frequencies greater than about 50 megahertz.
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20. The direct contact ultrasound scanner of claim 7, wherein the waveguide has a diameter of at least two millimeters.
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21. The direct contact ultrasound scanner of claim 7, the direct contact ultrasound scanner further comprising a main body and a nose extending outward from the main body, wherein:
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i. the main body contains the transducer and substantially all electronic signals;
ii. the nose is curved and mounted to the scanner surface on a convex side of the nose, defining a plane of contact with the object that is tangential to the curve of the nose and providing for the object to be scanned with substantially flat contact between the scanner surface and the object, notwithstanding that the main body is located above the plane of contact; and
iii. the waveguide is mounted substantially within the nose, permitting conveyance of ultrasound between the scanner surface and the transducer via the waveguide notwithstanding bending and rotation of the waveguide.
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Specification