U.S. patent number RE29,785 [Application Number 05/804,119] was granted by the patent office on 1978-09-26 for replaceable element ultrasonic flowmeter transducer.
This patent grant is currently assigned to Westinghouse Electric Corp.. Invention is credited to Walter C. Leschek, James L. McShane.
United States Patent |
RE29,785 |
Leschek , et al. |
September 26, 1978 |
Replaceable element ultrasonic flowmeter transducer
Abstract
An electroacoustic ultrasonic transducer is described which is
usable under high pressure and high temperature operating
conditions, and is readily replaceable. A piezoelectric transducer
element is disposed within a metallic housing and coupled to a
metallic acoustic window which is exposed to the sensed acoustic
medium, with very efficient acoustic coupling between the
piezoelectric element, the acoustic window, and a damping block
disposed behind the piezoelectric element.
Inventors: |
Leschek; Walter C.
(Monroeville, PA), McShane; James L. (Pittsburgh, PA) |
Assignee: |
Westinghouse Electric Corp.
(Pittsburgh, PA)
|
Family
ID: |
23902490 |
Appl.
No.: |
05/804,119 |
Filed: |
June 6, 1977 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
|
Reissue of: |
479057 |
Jun 13, 1974 |
03925692 |
Dec 9, 1975 |
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Current U.S.
Class: |
310/327;
73/644 |
Current CPC
Class: |
B06B
1/0685 (20130101) |
Current International
Class: |
B06B
1/06 (20060101); H01L 041/10 () |
Field of
Search: |
;310/327,335,336,346,334
;73/67.5R,71.5US,194A ;340/8MM,8RT |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
Primary Examiner: Budd; Mark O.
Attorney, Agent or Firm: Sutcliff; W. G.
Claims
We claim:
1. An acoustic transducer assembly comprising:
an electrically conductive, generally tubular metal transducer
housing;
an acoustically transmissive metal window sealingly disposed at one
end of the transducer housing, with the .[.exterior and.]. interior
.[.surfaces.]. .Iadd.surface .Iaddend.of the metal window being
lapped optically flat for optimum acoustic coupling;
a thin disk, piezoelectric transducer element having opposed
surfaces lapped optically flat and one such surface in optical
contact with the interior surface of the metal window;
an insulating sleeve disposed within the generally tubular metal
transducer housing;
a generally cylindrical acoustic wave damping block disposed within
the insulating sleeve, which damping block is electrically
conductive and has one end surface lapped optically flat and in
optical contact with the transducer element disk, while the other
end of the damping block has a convex cone shaped terminus;
an electrical contact member disposed within the insulating sleeve
and having a concave conically shaped surface which mates with the
damping block convex cone shaped terminus, which contact member is
retained in physical and electrical contact with the damping block
by a coil spring means disposed within the insulating sleeve;
an insulating plate provided at one end of the insulating sleeve
contacting the coil spring and having an electrical lead-in
extending therethrough connected to the contact member, whereby
electrical connection is made to the interior surface of the
transducer element serially via the electrical contact member and
the conductive damping block, with the metal transducer housing
serving as another electrical lead to the other side of the
transducer element via the metal window;
a closure member closing the tubular transducer housing and
connectable thereto about the insulating plate and contacting the
insulating plate to thereby compress the coil spring to compress
together the contact member, the damping block, and the transducer
element to the metal window.
2. The acoustic transducer assembly specified in claim 1, wherein
the generally cylindrical damping block comprises an enlarged
diameter end portion which terminates with a convex cone shaped end
so that the length of travel of internally reflected acoustic waves
is extended.
Description
BACKGROUND OF THE INVENTION
The present invention relates to acoustic or ultrasonic
transducers, and more particularly to a transducer assembly
designed for flowmeter applications. Such electroacoustic
transducers have found wide application in the non-destructive
testing of material as well as in flowmeter applications.
For flowmeter applications, a pair of such transducers are
typically used with each transducer alternately serving as a
transmitter and receiver. It is also the common practice to shock
excite the transmitting transducer with a voltage pulse and to
detect the first or second half cycle of the received ultrasonic
wavefront, such a technique being known as leading edge detection.
For such a mode of operation, the received wavefront should be
sharp and clean, and the ringing of the receiving transducer
following its use as a transmitter should decay quickly, so that
subsequent arriving wavefronts can be easily detected. It is thus
desirable to minimize the mechanical Q of both the plezoelectric
transducer element and the acoustic window. The transducer, and in
particular its acoustic window, should be structured to detect the
arriving ultrasonic signal while reflecting as little energy as
possible back into the medium. This is to avoid measurement errors
which may arise from sensing of reflected signals, as well as to
obtain maximum sensitivity.
When the transducer device is used in a high temperature corrosive
fluid medium under high pressure, it is desirable that the acoustic
window be made of a high temperature, high strength material which
is chemically resistant to attack by the medium.
It is desirable that the piezoelectric element be replaceable in
the transducer assembly and that such replacement be effected while
the assembly is in position in the fluid medium. It has been the
practice to adhesively bond a thin disk of piezoelectric material
to an acoustic window in most ultrasonic flowmeter transducer
constructions. The adhesive bonding holds the piezoelectric element
in place and provides relatively good acoustic coupling between the
window and the piezoelectric element, however, the adhesive bond
prevents ready replacement of the piezoelectric element. Also,
organic adhesive bonds may degrade at elevated temperatures, and
the technique of applying metallic adhesive bonds, such as brazing
or soldering, may degrade the sensitivity of piezoelectric elements
by depoling.
SUMMARY OF THE INVENTION
An acoustic transducer utilizing a readily replaceable
piezoelectric element is detailed comprising in part an
electrically conductive metal transducer housing, with an
acoustically transmissive window portion. A thin disk piezoelectric
transducer element is acoustically coupled to the window portion. A
tubular insulating sleeve is disposed within the transducer housing
adjacent to the tubular interior surface of the housing. An
acoustic energy damping block made of electrically conductive
material is disposed within the tubular insulating sleeve, which
damping block is in electrical contact with and acoustically
coupled to the thin disk piezoelectric transducer element. A metal
contact is disposed within the tubular insulating sleeve and held
in physical and electrical contact with the conductive damping
block by a coil spring means disposed within the tubular insulating
sleeve. An insulating plate is provided at the end of the tubular
insulating sleeve, and holds the coil spring in compression. The
insulating plate has an electrical lead-in extending therethrough,
with the electrical lead-in electrically connected to the metal
contact. A closure member is connectable to the transducer housing
to retain the insulating plate within the housing and thereby
compress the spring means to press together the metal contact, the
damping block, and the piezoelectric transducer element which is
pressed against the acoustic window. The interior surface of the
acoustic window portion, both surfaces of the piezoelectric disk
transducer element, and the end surface of the damping block which
contacts the piezoelectric disk transducer element are lapped
optically flat, and a liquid acoustic coupling film may be disposed
between these mating surfaces to provide effective acoustic
coupling therebetween.
The damping block is preferably a solid cylindrical body of
electrically conductive graphite which minimizes ringing of the
device.
BRIEF DESCRIPTION OF THE DRAWING
FIG. 1 is a sectional view of the replaceable element transducer
assembly of the present invention.
FIG. 2 is a sectional view of an alternate embodiment.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
The present invention can best be understood by reference to the
exemplary embodiment of FIG. 1. In FIG. 1 the replaceable element
transducer assembly 10 comprises an electrically conductive metal
transducer housing 12, which is preferably formed of stainless
steel. The transducer housing 12 comprises an elongated generally
tubular portion 14 with an enlarged diameter portion 16 containing
an annular recess at one end thereof. An electrically conductive
metal acoustic window 18 is disposed at the end of the tubular
portion 14 and sealed thereto preferably by welding. The exterior
surface 20 of the window 18 has a good machined finish, and a
slight conical taper, while the interior surface 22 is lapped to an
optical flatness, typically within .+-.2 microinches. The acoustic
window 18 has annularly stepped portions 19 and 21 which fit
respectively the tubular portion 14, to facilitate sealing
connection thereto, and the tubular insulating sleeve 24. The
acoustic window 18 is also preferably formed of stainless steel.
The generally tubular insulating sleeve 24 is disposed within the
tubular portion 14 of the transducer housing 12.
A thin disk piezoelectric transducer element 26 is disposed within
the insulating sleeve 24 adjacent the interior surface 22 of the
acoustic window 18. Both sides of the disk of piezoelectric
material are lapped to an optical flatness, typically within .+-.2
microinches. A lead-zirconate-titanate piezoceramic material has
been found to be a very effective piezoelectric material. A
rod-like electrically conductive damping block 28 is disposed
within the insulating sleeve 24 with an optically flat end portion
30 being in contact with the piezoelectric element 26. The damping
block is preferably made of graphite material. The other end 32 of
damping block 28 has a generally conically shaped end surface, the
shape serving to prevent a stong internal reflection from the end
surface. A metallic contact member 34 is disposed within the
insulating sleeve and has a cone receiving surface 36 on one side
thereof which mates with the conic end 32 of the damping block 28.
Electrical lead-in 38 extends from the other side of the contact
member 34 and serves as one of the electrical lead-ins for the
transducer assembly. A spring member 40 shown as a coil spring is
also disposed within the insulating sleeve 24 about the electric
lead-in 38 with one end of the coiled spring seating against the
contact member 34. An insulating plate member 42 fits over the open
end of the insulating sleeve 24 and engages the other end of the
coiled spring means 40 when in place. Insulating plate 42 has an
annular shoulder portion 43 on the exterior surface side, and a
closure plate 44 fits thereover and is connectable to the enlarged
diameter end portion 16 of the transducer housing. The closure
plate 44 is typically screw fastened in place. A screw 46 passes
through aperture 48 in the closure plate 44 and is threadedly
engaged in threaded aperture 50 in the end portion 16 of the
housing 12. Three such symmetrically spaced screws are
utilized.
The electrical lead-in 38 is brought through the insulating plate
member 42. The electrically conductive metal transducer housing 12
and window assembly 18 serves as the other electrical connection
point for the transducer assembly. A thin film of silicone oil is
disposed between the end surface 30 of damping block 28 and the
piezoelectric element 26 as well as between the piezoelectric
element 26 and the acoustic window 18. This thin film provides an
effective acoustic coupling between the mating surfaces. If
desired, the silicone oil can be eliminated, and greater mechanical
compressive force can be used alone to get good acoustic
coupling.
The exterior surface 20 of acoustic window 18 is machined to a
slight conical taper which, when two opposing transducers are used
in a sensing operation such as a flowmeter, will not substantially
reduce the direct received signal, yet will serve to aim acoustic
reflections into the fluid away from the other transducer to
prevent interference with the direct signal. The angle of the
conical surface depends on the distance between transducers, being
greater for shorter distances. A 2.degree. taper as shown is
suitable for a spacing distance of approximately 3 inches.
A variety of piezoelectric materials which can be used at high
temperatures such as lead metaniobate, bismuthstrontium-titanate,
or lithium niobate can be used as the piezoelectric material of the
piezoelectric element 26. Various other electrically conductive
materials can be used for the damping block 28 such as zinc,
cadmium, silver, gray iron, and sintered tungsten impregnated with
copper, which materials are effective in damping the acoustic
energy. The transducer housing may also be hermetically sealed and
evacuated or filled with inert gas to extend the range of
temperature usage by preventing oxidation at high operating
temperatures. Other high temperature liquid, plastic, or metallic
acoustic couplants can be used as substitutes for the silicone oil,
or dry coupling and high compressive force can be used exclusively.
The coiled spring means 40 applies an effective mechanical
compressive force to hold together the acoustically coupled
surfaces of the damping block, the piezoelectric element and the
acoustic window.
In another embodiment of the present invention seen in FIG. 2, the
transducer assembly 60 includes the metallic housing 62, formed of
a high temperature resistant and noncorrosive metal such as
stainless steel. The housing 62 can be substantially immersed in
the fluid and can be semipermanently affixed in place in the pipe
section through which the fluid flows. The housing 62 comprises
enlarged end 64, intermediate portion 66, and extending tubular end
portion 68. A thin disc-like acoustic window 70 is welded in place
to close the tubular end portion 68. The exposed face 72 of the
acoustic window 70 is preferably machined, after the window is
welded in place, to slope the exposed face at a slight angle or to
give it a slightly tapered conical surface. This sloping or conical
surface permits directive transmission of the acoustic signal while
reducing interfering reflections. The interiorly disposed surface
74 of window 70 is lapped before welding to an optical flatness of
about .+-.2 microinches.
A disk-like piezoelectric transducer element 76 fits within the
tubular end portion 68. The piezoelectric material is again
preferably lead-zirconate-titanate piezoceramic material. Such
transducer elements are generally supplied with metallic electrodes
deposited on the flat major surfaces of the disk. In lapping the
piezoelectric transducer element the electrodes are normally
removed; they are not needed because of the efficient electrical
coupling of the transducer element to the lapped optically flat
conductive surfaces of the window and the damping block 78. The
transducer electrodes could be left deposited on the major surfaces
of the disk if they were lapped optically flat for good acoustic
coupling.
The damping block 78 is formed of an electrically conductive
material which has high internal mechanical loss for attenuating or
damping acoustic energy. A typical damping block material is zinc
or graphite. The damping block 78 has a reduced diameter rod end
portion 80, which fits generally within tubular end portion 68. An
electrically insulating coating is provided about rod end portion
80 to maintain electrical isolation between rod end portion 80 and
the tubular end portion 68. A "Teflon" tape insulation material has
been found useful. The backing block has a central transition
portion 82, and enlarged diameter end portion 84. The terminal 86
of end portion 84 is generally conic, and a mating core receiving
electrical contact element 88 is abutted thereto. An insulating
sleeve 87 is disposed within the enlarged end 64 and intermediate
portion 66 of housing 62 to electrically isolate the housing from
the backing block 78. An electrical lead-in 90 extends from the
contact element 88. A compression spring 92, such as a coil spring,
is disposed within the housing 62, one end of the spring contacting
the electrical contact element 88, and the other end contacting the
electrically insulating plate 94 which acts as a closure member for
the insulating sleeve 87. A holding plate 96 fits over the
insulating plate 94 and is secured via retaining means, such as
screws, to the housing. The electrical lead-in 90 passes through an
aperture provided in insulating plate 94.
The end surface of the damping block 78 which abuts the transducer
element is lapped optically flat to provide a good acoustic
coupling therebetween, with a thin film of fluid couplant
therebetween.
The enlarging diameter of the damping block as it proceeds from the
acoustically coupled end to the cone shaped end, as well as the
provision of a cone shaped end facilitates the damping or
attenuating of internally contained acoustic waves by increasing
the path length traveled by the waves and by increasing the number
of reflections which they must undergo.
The exterior surface 97 of the intermediate housing portion 66 is
threaded to permit the assembly to be mounted in place. The
enlarged end portion 64 has an externally threaded portion 98, and
a generally tubular cover member not shown may be threaded thereon,
with an electrical connector provided on the cover member.
It is possible to further adapt the transducer assemblies shown in
FIGS. 1 and 2 for specific applications. The acoustic window need
not be a simple disk-like member disposed at the end of the
housing, but may be an extending rod-like member which provides
thermal insulation for the transducer element from a hot fluid. In
the same way the window may be joined to a thermal and/or
electrical insulator extension. The mating surfaces of these
acoustic transmissive members are all lapped optically flat for
good acoustic coupling.
It is also possible to dispose a second transducer element abutting
the other disk transducer to provide a device which is operable at
different frequencies. The mating surfaces between the two
transducers are lapped optically flat. The transducers would then
be serially electrically connected via the conductive window and
backing block. It is also possible to provide a conductive element
between two such abutting transducer disks to permit parallel
electrical connection.
In summary, the electroacoustic transducer assemblies detailed
employ lapped optically flat mating surfaces between the
piezoelectric transducer element and the acoustic window and
backing block. The liquid film couplant does not degrade the
uniform electric field because the film is negligibly thin. For
high temperature application, the liquid film couplant may be
dispensed with, and compressive dry coupling utilized.
The flatness to which the lapped mating surfaces must be processed
depends on the coupling force applied by the spring means and the
resonant frequency of the element. When a liquid couplant is used,
adequate flatness can be provided by grinding, while an optical
flatness is necessary for dry coupling for an element operating at
about 5 megahertz.
* * * * *