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Claims  |
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The invention which is claimed is:
1. A clip for supporting an elongated electrode within a nozzle which
directs a flow of gas from an electrosurgical handpiece, comprising:
a central section having opposed and facing surfaces adapted to
frictionally engage and extend longitudinally along an electrode and
support the electrode in a predetermined position within the nozzle; and
a plurality of legs connected to the central section and extending
transversely outward from the central section, said legs adapted to
contact the nozzle and position the central section within the nozzle at a
location spaced from the nozzle.
2. A clip as defined in claim 1 wherein:
the legs define vanes adapted to direct the gas within the nozzle.
3. A clip as defined in claim 1 wherein:
the legs form part of at least one conduit adapted to extend longitudinally
along the nozzle.
4. A clip as defined in claim 3 wherein:
each conduit is resilient and each conduit is adapted to be resiliently
compressed against the nozzle to hold the clip in the nozzle.
5. A clip as defined in claim 1 wherein:
the legs are adapted to longitudinally contact the nozzle; and
the longitudinal extent of contact of the central section with the
electrode and the longitudinal extend of contact of the legs along the
nozzle are sufficient to prevent substantial angular deflection of the
electrode away from the predetermined position.
6. A clip as defined in claim 1 wherein:
the legs extend from the center section to an outer curved portion; and
the outer curved portion is adapted to contact the nozzle.
7. A clip as defined in claim 6 wherein:
two leg portions join a single outer curved portion; and
the two leg portions and the single outer curved portion form a
conduit-like configuration.
8. A clip as defined in claim 7 further comprising a plurality of
conduit-like configurations adapted to extend longitudinally along the
nozzle.
9. A clip as defined in claim 8 wherein:
each conduit-like configuration is tapered in a forward converging manner
toward a forward end of the clip; and
the extent of the taper allows the plurality of conduit-like configurations
to be inserted at the forward end of the clip into the nozzle.
10. A clip as defined in claim 9 wherein:
material; and
a maximum dimension between two opposing outer curved portions at a rear
end of the clip is greater than a maximum cross-sectional dimension of the
nozzle.
11. A clip as defined in claim 10 wherein:
the conduit-like configurations are adapted to apply frictional force
against the nozzle to retain said clip in position in the nozzle.
12. A clip as defined in claim 1 formed from a tube and having a
predetermined cross-sectional configuration defining three laterally
adjacent generally curved sections, one of the curved sections including
the central section, the two other curved sections including two lobes
extending on opposite sides of the central section and adapted to contact
opposing points on the nozzle, the lobes having a hollow cross-section to
allow gas to pass through the lobes along the length of the tube.
13. A clip for use in supporting an elongated electrode within a
cylindrical nozzle which directs a flow of gas from an electrosurgical
handpiece, comprising:
three laterally adjacent partially closed conduits having coplanar
centerlines, the conduits adapted to extend from one point on a
circumference of the cylindrical nozzle to a diametrically opposed point
on the circumference of the cylindrical nozzle, wherein the three
partially closed conduits include:
a central partial conduit having opposed and facing arcuate surfaces
adapted to engage the electrode; and
two lobe-shaped partial conduits extending from opposite sides of the
central partial conduit and adapted to contact the diametrically opposed
points on the circumference of the cylindrical nozzle, the lobe-shaped
partial conduits adapted to allow gas within the nozzle to pass both
around and through the lobe-shaped partial conduits.
14. A clip as defined in claim 13 wherein the lobe-shaped partial conduits
are formed from a resilient material which allows the lobe-shaped partial
conduits to compress and apply frictional force radially against the
circumference of the nozzle.
15. A clip as defined in claim 13 wherein a maximum cross-sectional
dimension of the clip is tapered along the length of the clip.
16. A clip as defined in claim 13 wherein the central partial conduit is
adapted to engage a cylindrical segment of the electrode having a reduced
diameter relative to adjacent cylindrical segments of the electrode.
17. A nozzle and electrode assembly to be used in conjunction with a
handpiece for supplying electrical energy and gas from an electrosurgical
apparatus to perform conductive gas electrocoagulation, comprising:
an elongated cylindrical nozzle adapted to apply the gas to a patient;
a clip which is separate from the nozzle and which is inserted into and
frictionally retained within a rear end of the nozzle, the clip including
a central partial conduit having opposed and facing arcuate surfaces and
two lobe-shaped partial conduits extending from opposite sides of the
central partial conduit to contact an interior circumference of the
cylindrical nozzle at diametrically opposing points; and
an elongated electrode retained between the arcuate surfaces of the central
partial conduit, the electrode extending within the nozzle along a
longitudinal axis of the cylindrical nozzle.
18. A nozzle and electrode assembly as defined in claim 17, wherein the
clip is formed from a resilient material, each lobe-shaped partial conduit
includes an outer curved portion which conforms substantially to the
interior circumference of the cylindrical nozzle, and the electrode is
frictionally retained within the central partial conduit from resilient
engagement with the arcuate surfaces.
19. A nozzle and electrode assembly as defined in claim 17, wherein the
clip is formed from a resilient material, and a dimension of the clip
between the diametrically opposing points is reduced along the length of
the clip from a rear end thereof to a front end thereof, prior to
insertion of the clip in the nozzle.
20. A nozzle and electrode assembly as defined in claim 19, wherein the
length of the clip is less than one half of the length of the elongated
electrode.
21. A nozzle and electrode assembly as defined in claim 17, wherein the
portion of the electrode retained within the central partial conduit has a
reduced diameter relative to adjacent portions of the electrode.
22. A method of forming a clip used to retain and center an elongated
electrode within a cylindrical nozzle in a handpiece of a conductive gas
electrocoagulation device, said method comprising the steps of:
positioning a segment of a cylindrical tube in a die pressmold device; and
deforming the tube into said clip by forming a central partial conduit and
two lobe-shaped partial conduits attached to opposite sides of the central
partial conduit.
23. A method of forming the clip as defined in claim 22 further comprising
the step of:
reducing the greatest cross-sectional dimension of the clip from one end
along the length of the clip to the other end of the clip.
24. A method of forming an electrode and clip assembly used to retain and
center an elongated electrode within a cylindrical nozzle, said method
comprising the step of:
positioning a segment of a cylindrical tube in a die pressmold device;
deforming the tube into a clip by forming a central partial conduit and two
lobe-shaped partial conduits attached to opposite sides of the central
partial conduit; and
attaching an elongated electrode within the central partial conduit of the
clip.
25. A method as defined in claim 24, wherein attaching the electrode within
the central partial conduit further comprises the steps of:
positioning the electrode into the tube along a longitudinal axis of the
tube; and
deforming the tube into the clip around the electrode.
26. A method as defined in claim 25 further comprising the step of:
contacting the electrode substantially only by the central partial conduit
after deforming the tube into the clip around the electrode.
27. A method of forming an assembly of a cylindrical nozzle and an
elongated electrode and a clip to retain and center the elongated
electrode within the cylindrical nozzle, said method comprising the steps
of:
positioning a segment of a cylindrical tube in a die pressmold device;
deforming the tube into a clip by forming a central partial conduit and two
lobe-shaped partial conduits attached to opposite sides of the central
partial conduit;
attaching the electrode within the central partial conduit of the clip;
inserting the clip and the attached electrode into the nozzle; and
centering the electrode within the nozzle by positioning the clip within
the nozzle.
28. A method as defined in claim 27 further comprising the step of:
retaining the clip and electrode in the nozzle by friction resulting from
resiliently compressing the clip due to insertion in the nozzle.
29. A method as defined in claim 28 further comprising the steps of:
narrowing the greatest cross-sectional dimension of the clip from one end
along the length of the clip to the other end of the clip prior to
inserting the clip in the nozzle;
inserting the narrow end of the clip into a rear end of the nozzle; and
pushing the clip and the nozzle together after the narrow end is inserted
in the nozzle to insert the clip in the nozzle and to resiliently compress
the clip.
30. A method as defined in claim 29 further comprising the step of:
inserting the clip into the nozzle until a rear end of the clip is adjacent
to the rear end of the nozzle.
31. A method as defined in claim 29 further comprising the step of:
inserting the clip into the nozzle until a front end of the electrode is
adjacent to a front end of the nozzle.
32. A method as defined in claim 27 for use with a handpiece to perform
conductive gas electrocoagulation, further comprising the steps of:
attaching the nozzle and electrode and clip assembly to the handpiece;
connecting the handpiece to an electrosurgical apparatus;
delivering gas and electrical energy to the nozzle and the electrode,
respectively; and
performing conductive gas electrocoagulation using the handpiece and the
electrosurgical apparatus. |
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Claims |
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Description |
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FIELD OF THE INVENTION
This invention pertains to electrosurgery, and more particularly, to a new
and improved technique for incorporating an electrode within a nozzle of
an electrosurgical handpiece utilized during conductive gas
electrocoagulation.
BACKGROUND OF THE INVENTION
Electrocoagulation involves the coagulation of bleeding tissue by the
application of electrical energy to the tissue. Conductive gas
electrocoagulation involves conducting electrical energy to the tissue as
arcs in ionized conductive pathways in a flowing stream of inert gas. A
more complete description of conductive gas electrocoagulation is
available in U.S. Pat. Nos. 4,781,175, 4,901,719, and 4,901,720, all
assigned to the assignee of the present invention.
During conductive gas electrocoagulation, the conductive gas jet is
typically delivered to the tissue by a handpiece that the surgeon
manipulates. Gas and electrical energy are delivered from an
electrosurgical apparatus to a transfer electrode located within an
electrically insulated gas nozzle located within the handpiece. The gas
flows through the nozzle and over the electrode where it is ionized by the
electrical energy applied to the electrode. Electrical energy is
transferred from the electrode as arcs in conductive pathways in the gas
flowing to the tissue.
It is desirable that the transfer electrode be fixedly mounted and centered
within the gas nozzle, to achieve the best energy transfer and electrical
insulating characteristics. Furthermore, the energy transfer
characteristics are enhanced by exposing a maximum amount of the electrode
to the flow of gas within the nozzle. As a result of these and other
considerations, prior art handpieces have utilized complex structures to
center the electrode within the nozzle.
Prior art handpieces, as typified by U.S. Pat. Nos. 4,781,175 and
4,901,719, have required the construction of a one piece ceramic molded
nozzle and electrode assembly to retain and center the electrode within
the nozzle. The molded assembly is formed by centering the electrode
within a mold, inserting ceramic material into the mold, and allowing the
ceramic material to harden around the electrode. Once completed, the
nozzle and electrode assembly is secured to the remainder of the
electrosurgical handpiece. Although effective, these prior art nozzle and
electrode assemblies are somewhat costly to manufacture, due to the costs
of the insert molding used to form the assembly.
The nozzle and electrode assembly described in U.S. patent application Ser.
No. 592,810, also assigned to the assignee of the present invention, is a
unitary, molded assembly which is slip fit within a gas supply tubing at
the handpiece. This type of assembly reduces the cost of a conductive gas
electrocoagulation handpiece because of its convenient use of the gas
supply tubing to achieve some of the functionality of the handpiece.
However, the structure which creates the nozzle and supports the electrode
is still a single molded unit.
Alternatives to molding the nozzle and electrode supporting structure
around the electrode involve the use of centering devices to locate the
electrode within a length of prefabricated ceramic tubing which serves as
the nozzle. This type of support is generally located at a midpoint of the
electrode and is intended to function in conjunction with another support
at the rear of the electrode to maintain the electrode in the center of
the nozzle. U.S. Pat. No. 4,040,426 is an example of such an arrangement.
As described in this patent, the support member supports the electrode
only along a limited length of the electrode, and thus the rear end of the
electrode requires additional support within the handpiece body. One
difficulty with this type of arrangement is maintaining the electrode in
the centered position. Movement of either the middle or rear support can
shift the position of the electrode and adversely affect its operating
characteristics. Furthermore, although this support arrangement is simple
in concept, it can be difficult to employ practically because of
difficulty in assembling the nozzle, electrode and handpiece to obtain
support for the rear end of the electrode.
It is with regard to this background information that the improvements
available from the present invention have evolved.
SUMMARY OF THE INVENTION
One of the significant aspects of the present invention relates to a clip
for supporting an elongated electrode within a nozzle which directs a flow
of gas from an electrosurgical handpiece. The clip comprises a central
section having opposed and facing surfaces to frictionally engage and
extend longitudinally along an electrode and to support the electrode in a
predetermined manner in the nozzle. The clip also includes a plurality of
legs connected to the central section and extending transversely outward
from the central section to contract the nozzle and to position the center
section within the nozzle at a location spaced from the nozzle. Preferably
the legs preferably form part of conduits which extend longitudinally
along the nozzle. Each conduit is formed as a lobe which extends on
opposite sides of the center section and the lobes contact the nozzle. The
conduits are resilient and resiliently compress against the nozzle to hold
the clip in the nozzle. The longitudinal extent of contact of the central
section with an electrode and the longitudinal extent of contact of the
legs along the nozzle are sufficient to prevent substantial movement or
angular deflection of the electrode away from the predetermined position.
The conduit-like configurations are tapered in a forward converging manner
toward a forward end of the electrode, and upon insertion into the nozzle
the compression of the resilient material holds the clip in place.
In accordance with another of its aspects the present invention relates to
a method of forming the clip. The method includes positioning a segment of
a cylindrical tube in a press and molding device and deforming the tube
into the clip. The electrode may be attached to the clip by positioning
the electrode within the central partial conduit of the clip, or by
inserting the electrode into the tube and deforming the tube into the clip
around the electrode. In addition the clip and the attached electrode are
inserted into a nozzle by resiliently compressing the clip by inserting
the narrow end of the clip into a rear end of the nozzle and pushing the
clip and the nozzle together after the narrow end is inserted to
resiliently compress the wider portions of the clip as the clip slips into
the nozzle. The clip is retained in the nozzle by the resilient
compression against the nozzle.
By structuring and manufacturing the clip in the manner described, and by
supporting the electrode with the clip and by retaining the electrode and
the clip in the nozzle, substantial improvements in the cost and
efficiency in manufacturing and in the effectiveness and integrity of the
resulting clip and electrode and nozzle assemblies result.
A more complete appreciation of the present invention and its scope can be
obtained from understanding the accompanying drawings, which are briefly
summarized below, the following detailed description of a presently
preferred embodiment of the invention, and the appended claims.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective view of a nozzle and electrode assembly embodying
the present invention.
FIG. 2 is an exploded perspective view of the assembly illustrated in FIG.
1, showing an electrode clip, an electrode and a nozzle, and a tool for
inserting the electrode and clip into the nozzle.
FIG. 3 is an enlarged perspective view of the electrode clip illustrated in
FIG. 2, with a portion of the electrode shown in phantom.
FIG. 4 is an enlarged fragmentary perspective view of the electrode
illustrated in FIG. 2, showing an undercut portion of the electrode
contacted by the electrode clip.
FIG. 5 is an enlarged longitudinal section view of the nozzle and electrode
assembly taken substantially in the plane of line 5--5 of FIG. 1, with a
portion broken out.
FIG. 6 is an enlarged cross section view of the nozzle and electrode
assembly taken substantially in the plane of line 6--6 in FIGS. 1 and 5.
FIG. 7 is an enlarged section view taken substantially in the plane of line
7--7 of FIG. 3, showing a taper in one dimension of the electrode clip.
FIG. 8 is a generalized perspective view of a press mold and assembly
device used in the formation of the electrode clip illustrated in FIG. 2,
with a portion broken out to illustrate details of the mold.
FIG. 9 is a generalized horizontal sectional view of the device shown in
FIG. 8, with a blank tube shown within the device.
FIG. 10 is a horizontal sectional view of the device shown in FIG. 9,
showing deformation of the blank tube about the electrode to form the
electrode clip illustrated in FIG. 2.
FIG. 11 is a perspective view of the nozzle and electrode assembly
illustrated in FIG. 1, in conjunction with an electrosurgical handpiece
and an electrosurgical apparatus.
DETAILED DESCRIPTION
A nozzle and electrode assembly 20 which incorporates the present invention
is shown in FIG. 1. One aspect of the present invention relates to an
electrode clip 22 which is shown in FIGS. 2 and 3. The clip 22 retains and
centers an electrode 24 within a cylindrical nozzle 26 of the assembly 20.
The clip 22 grips the electrode 24 and is positioned within the nozzle 26
to center the electrode 24 along the longitudinal axis of the nozzle 26.
The clip 22 supports the electrode 24 in such a manner and along a
sufficient amount of the length of the electrode so as to maintain the
electrode in a coaxial position within the nozzle 26 with no additional
support.
The nozzle 26 is preferably a conventional tubular structure made from a
non-conductive ceramic material. The nozzle 26 has an inner cylindrical
surface 28 of a predetermined uniform diameter.
The electrode clip 22 is preferably a hollow tubular structure having a
cross-sectional shape shown in FIGS. 3 and 6. The cross-sectional shape
includes a rounded central section 30 with two adjacent lobes 32 on
opposite sides of the central section 30. The central section 30 includes
two opposed and facing arcuate surfaces 34 which contact and grip a
cylindrical segment 36 of the electrode 24. The cross-sectional shape of
the clip 22 is generally symmetrical about a longitudinal axis 38 as shown
in FIG. 6. The cross-sectional shape is also such that one-half is a
mirror image of the other half, with respect to both a horizontal and a
vertical plane extending through the axis 38. The central section 30 is
centered about the axis 38, and the two lobes 32 are positioned radially
opposite one another with respect to the axis. An outer cylindrical
surface of an outer curved portion 40 of each lobe 32 contacts the inner
cylindrical surface 28 of the nozzle 26. Leg portions 42 extend between
the outer curved portion 40 of the lobes 32 and the arcuate surfaces 34 of
the central section 30. Arranged in this manner, the clip has a
cross-sectional configuration somewhat similar to the shape of a figure
eight, a hour glass, a bow-tie or a butterfly, as shown in FIG. 6.
The electrode 24 is typically constructed from tungsten, and the
cylindrical segment 36 of the electrode is preferably undercut, as shown
in FIG. 4, to provide a more secure gripping area for the arcuate surfaces
34 of the clip 22. The length of the clip 22 extends a substantial
distance along the length of the electrode 24. This longitudinal distance
is sufficient to hold the electrode coaxially in the nozzle without
additional support for the electrode. The length of the clip 22 and its
contact at the cylindrical segment 36 is sufficient to prevent the
electrode from moving off of the longitudinal axis of the nozzle. As an
example in the preferred embodiment, the length of the clip 22 is
approximately 0.38 inches and the length of the nozzle 26 is approximately
0.90 inches.
The described cross-sectional configuration of the clip 22 creates three
generally tubular portions or areas. A center tubular area is generally
bounded by the opposing arcuate surfaces 34 of the central section 30. The
center tubular area receives the undercut area formed by the cylindrical
segment 36 of the electrode 24. The undercut area is cylindrical in
cross-section as shown in FIG. 6. Each lobe 32 also creates a tubular
portion formed generally by the legs 42 and the outer curved portion 40.
The tube portions formed by the lobes 32 allow gas to pass therethrough
and the gas thus maintains contact with the electrode 24 to further
enhance the opportunities for gas ionization. In addition, open areas 43
on opposite sides of the clip allow gas to pass through the nozzle 26.
Because the clip is preferably formed of electrically conductive metal
which contacts the electrode, the presence of electrical potential and
energy on the clip 22 also enhances the possibility of gas ionization.
Thus, due to the structure of the clip 22, there is little impediment to
the flow of gas through the nozzle 26 and the possibilities of ionization
are enhanced because of the full exposure of the electrode 24 to the gas
flowing in the nozzle.
The elevational height of the clip 22 tapers along the length of the clip,
narrowing from a proximal or rear end 44 of the clip 22 to a distal or
forward end 46 of the clip, as shown in FIG. 7. The magnitude of the taper
is small, accounting for approximately a two percent variance between the
heights of the proximal end 44 and the distal end 46 of the clip 22. The
degree of taper shown in FIG. 7 has been exaggerated for illustrative
purposes. The taper is such that the height of the clip at the distal end
46 is slightly less than the diameter of the inner cylindrical surface of
the nozzle. The height of the clip at the proximal end 44 is greater than
the diameter of the nozzle. Tapered in this manner, the distal end 46 of
the clip is easily inserted within the nozzle 26 during assembly of the
nozzle and electrode assembly 20. Forward movement during insertion
results in slight radial compression of the resilient clip 22 to hold the
clip and attached electrode 24 in place in the nozzle 26.
The clip 22 is preferably formed by pressing a predetermined length of
blank cylindrical tube 50 between opposing retainers 52 and formers 54 in
a press mold and assembly device 56, as shown in FIGS. 8-10. The device 56
includes a base plate 58 into which a vertical hole 60 is formed. The hole
60 is adapted to receive a proximal or rear end 62 of the electrode 24 and
thereby supports the electrode to extend vertically upward from the base
plate 58. A pointed forward or distal end 64 of the electrode 24 points
upward when the electrode is retained in this manner.
The retainers 52 and the formers 54 are movably attached to the base plate
58 to move toward and away from the electrode 24 from four perpendicular
directions. The retainers 52 and the formers 54 are attached to the base
plate by conventional guide rails and connection arrangements (not
specifically shown). Movement imparting or drive (also not shown),
apparatus such as hydraulic or pneumatic cylinders or mechanical lever
arrangements, move the retainers 52 and the formers 54 toward and away
from the electrode 24.
The retainers 52 have partial cylindrical surfaces 66 which contact the
outer surface of the tube 50. The radius of curvature of each of the
surfaces 66 is approximately the same as the radius of curvature of the
inner cylindrical surface 28 of the nozzle 26 (FIG. 6). The surfaces 66
longitudinally converge or taper toward one another and toward the
electrode in a direction toward the front tip end 64 of the electrode 24.
This converging taper is responsible for tapering the clip 22 in the
manner shown in FIG. 7, when the tube 50 is transformed into the clip 22
by the device 56.
The formers 54 have die faces 68 which each have a partial cylindrical
configuration generally similar to the exterior surface of the central
section 30 of the clip 22 (FIG. 6). The die faces 68 contact the tube 50
and press or swage it around the undercut segment 36 of the electrode 24
(FIGS. 3-6) to form the central section 30 and to retain the clip 22 to
the electrode 24.
To transform the tube 50 into the clip 22 attached to the electrode 24, the
retainers 52 and the formers 54 are moved laterally inward toward the
electrode 24. The retainers 52 first contact and hold the tube while
deforming it to impart the longitudinal taper, and then the formers 54
move laterally inward to bend and deform the tube and complete the
formation of the clip. The space between the formers and the retainers
allows the tube 50 to bend into the cross-sectional shape shown as the
formers press the tube into the central section 30. The figure eight,
hour-glass, bow-tie or butterfly configuration assumed by the deformed
tube occurs naturally without any holding or support other than that from
the die faces 68 of the formers 54 and the surfaces 66 of the retainers
52.
A typical clip formation cycle begins with the retainers 52 and formers 54
of the device 56 in an open position as shown in FIG. 8. The electrode 24
is then positioned within the centering hole 60 so that the undercut
cylindrical segment 36 is above the base plate 58. The electrode 24 is
oriented so that the front tip end 64 extends out of the device 56. The
cylindrical blank tube 50 is then inserted down and around the electrode
24, as shown in FIG. 9, until the tube sits on the base plate 58. The
blank tube 50 is preferably made from stainless steel and is of a length
equal to the length of the undercut cylindrical segment 36. In this
position, the tube 50 is laterally aligned with the undercut segment 36.
Upon movement of the retainers 52 into contact with the tube 50, the tube
is first tapered in the manner shown in FIG. 7. Thereafter, with movement
of the formers 54, the tube 50 is then transformed into the clip 22 with
the central sections 30 swaged around the undercut segment 36 of the
electrode 24 as shown in FIG. 10.
The electrode 24 is neither deformed nor damaged as the clip 22 is molded
around the electrode. Since the central section 30 of the clip 22 is
formed about the undercut segment 36 of the electrode 24, the arcuate
surfaces 34 of the central section 30 generally conform to the
circumference of the undercut segment 36 to adequately retain the
electrode 24. Contact between the ends of the central section 30 of the
clip 22 and the larger diameter shoulders of the electrode adjacent to the
undercut segment 36 will prevent longitudinal movement of the clip 22
along the electrode 24.
After forming the clip 22 around the electrode 24, the retainers 52 and the
formers 54 are moved in the reverse direction to retract away from the
clip. In this position the nozzle and electrode assembly 20 is then
completed by inserting the nozzle 26 over the clip 22, while the clip and
the attached electrode are in the device 56. With the retainers and the
formers moved outward to a position separated from the clip 22, a rear end
70 of the ceramic nozzle 26 is positioned down on the front end 46 of the
tapered clip 22. Because of its taper, the front end 46 of the clip 22
extends slightly into the rear end 70 of the nozzle. Once the tapered end
forward end 46 has entered the rear end of the nozzle 26, the nozzle 26 is
pushed downward over the remainder of the clip 22 until the rear end 70 of
the nozzle is flush with the rear end 44 of the clip, both of which rest
on the base plate 58. With the rear end 44 of the clip against the base
plate 58, the clip is retained to allow the nozzle to be pressed down over
it. Due to the resilient nature of the preferably metal clip 22, the lobes
32 are resiliently compressed as the clip 22 is press fit into the nozzle.
The compression of the lobes 32 against the ceramic nozzle 26 during
insertion of the clip holds the electrode and clip in place in the nozzle.
The degree of compression is not sufficient to result in significant
separation of the arcuate surfaces 34 from the undercut portion 36 of the
electrode, so as to release or loosen the connection to the electrode.
An alternative to using the device 56 for assembling the clip and attached
electrode into the nozzle is shown in FIG. 2. A cylindrical insertion
sleeve 72 is utilized as a tool to push the clip 22 and attached electrode
24 into the nozzle 26 to the final retained position. The insertion sleeve
72 fits over the rear end 62 of the electrode 24 and presses against the
rear end 44 of the clip 22 during this alternative assembly process. The
assembled electrode 24 and clip 22 are inserted from the rear end of the
nozzle so that the narrower forward end 46 of the clip 22 is the first
portion of the clip to enter the nozzle. Once the tapered forward end 46
has entered the rear end 70 of the nozzle 26, the remainder of the clip 22
is pushed into the nozzle. By manipulating the insertion sleeve 72, the
clip 22 is inserted within the nozzle 26 so that the rear end 44 of the
clip is flush with the rear end 70 of the nozzle, as shown in FIG. 1.
The assembly of the clip and electrode into the nozzle allows the electrode
24 to be supported in a cantilever manner at its rear end so that the
electrode is exposed to the gas within the nozzle 26. The lengths of the
electrode 24 and nozzle 26, and the position of the undercut segment 36,
are predetermined so that the front end tip 64 of the electrode 24 is
positioned within the nozzle 26, preferably within 0.10 inches from
extending from a front end 74 of the nozzle.
After assembly, the nozzle and electrode assembly 20 may be connected in a
handpiece in a variety of different manners, including inserting the rear
end 70 of the nozzle into the end of a gas supply tube 76, as shown in
FIG. 11. The connection of the rear end 70 of the nozzle 26 to a gas
supply tube 76 is preferably accomplished within an electrosurgical
handpiece 78 as shown in FIG. 11. The gas supply tube 76 connects the
handpiece 78 to an electrosurgical apparatus 80 which contains a supply of
inert gas. Similarly, the rear end 62 of the electrode 24 is connected to
any suitable electrical source, although it is preferably connected within
the handpiece 78 to an electrical conductor 82 contained within the gas
supply tube 76. The electrical conductor 82, in turn, is connected to an
electrosurgical generator contained within the electrosurgical apparatus
80.
The electrical energy supplied by the electrosurgical generator in the
apparatus 80 to the electrode 24 is of a predetermined character
sufficient to ionize the inert gas flowing through the nozzle 26. In this
manner, ionized conductive pathways are created in the gas jet flowing
from the front end 74 of the nozzle 26. The electrical energy within the
ionized pathways travels with the gas jet to a body tissue where it
creates a predetermined electrosurgical effect on the tissue. The manner
in which the nozzle and electrode assembly 20 is used in an
electrosurgical handpiece will be apparent from the previously referenced
U.S. patents and application of the assignee as well as others.
Significant improvements are available from the clip 22 and the nozzle and
electrode assembly 20. Low cost prefabricated ceramic nozzles 26 may be
used with the clips 22 in place of more costly injection molded parts
where the nozzle is formed about the electrode. A substantial savings in
the manufacturing costs of the nozzle and electrode assemblies results.
The exposure of the electrode to the flow of gas through the nozzle is not
restricted. The shape of the central section 30 and the lobes 32 of the
clip 22 increase the surface area of the electrode 24 exposed to the gas
within the nozzle 26, as shown in FIG. 6. In effect, the gas within the
nozzle 26 flows through the tubular portions formed by the lobes 32 and
contacts the electrode 24 not gripped by the arcuate surfaces 34 of the
central section 30. Furthermore, forming the clip 22 from conductive
stainless steel may enhance the electrical field effect generated by the
electrode 24 to enhance gas ionization. Thus, the shape and the steel
construction of the clip 22 combine to enhance the initiation of the
electrical energy transfer. The clip and electrode are quickly and
conveniently joined as a single assembly by the die press molding
technique described. The electrode and clip are easily assembled into the
nozzle, and are held in the desired position without the need for other
supports. The assembly can be conveniently slip fit into the end of a gas
supply tubing.
A presently preferred embodiment of the present invention and many of its
improvements have been described with a degree of particularity. This
description has been made by way of preferred example and is based on a
present understanding of knowledge available regarding the invention. It
should be understood, however, that the scope of the present invention is
defined by following claims, and not necessarily by the detailed
description of the preferred embodiment.
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