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US3895635A - Electrosurgical grounding cable assembly - Google Patents

Electrosurgical grounding cable assembly
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US3895635A
US3895635AUS371773AUS37177373AUS3895635AUS 3895635 AUS3895635 AUS 3895635AUS 371773 AUS371773 AUS 371773AUS 37177373 AUS37177373 AUS 37177373AUS 3895635 AUS3895635 AUS 3895635A
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Prior art keywords
trackway
connector
cable
lever
conductor
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US371773A
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George Junior Justus
Lowell C Miller
Jr Charles T Patrick
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NDM Acquisition Corp
NDM Corp
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NDM Corp
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Assigned to AMERICAN HOSPITAL SUPPLY CORPORATION, EVANSTON, ILLINOIS, A CORP. OF ILLINOISreassignmentAMERICAN HOSPITAL SUPPLY CORPORATION, EVANSTON, ILLINOIS, A CORP. OF ILLINOISASSIGNMENT OF ASSIGNORS INTEREST.Assignors: NDM CORPORATION, A CORP. OF OHIO
Assigned to BAXTER TRAVENOL LABORATORIES, INC. A CORP. OF DEreassignmentBAXTER TRAVENOL LABORATORIES, INC. A CORP. OF DEMERGER (SEE DOCUMENT FOR DETAILS). EFFECTIVE ON 11/25/1985 ILLINOISAssignors: AMERICAN HOSPITAL SUPPLY CORPORATION INTO
Assigned to NDM ACQUISITION CORP.reassignmentNDM ACQUISITION CORP.ASSIGNMENT OF ASSIGNORS INTEREST.Assignors: BAXTER HEALTHCARE CORPORATION OF PUERTO RICO, BAXTER INTERNATIONAL INC.
Assigned to BANK ONE, DAYTON, NATIONAL ASSOCIATIONreassignmentBANK ONE, DAYTON, NATIONAL ASSOCIATIONSECURITY INTEREST (SEE DOCUMENT FOR DETAILS).Assignors: NDM ACQUISITION CORP.
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Assigned to NDM, INC.reassignmentNDM, INC.ASSIGNMENT OF ASSIGNORS INTEREST (SEE DOCUMENT FOR DETAILS).Assignors: NEW DIMENSIONS IN MEDICINE, INC.
Assigned to NEW DIMENSIONS IN MEDICINE, INC.reassignmentNEW DIMENSIONS IN MEDICINE, INC.RELEASE BY SECURED PARTY (SEE DOCUMENT FOR DETAILS).Assignors: BANK ONE, DAYTON, NATIONAL ASSOCIATION
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Abstract

A connector for the grounding cable of an electrosurgical generator (E.G.) has a non-conductive body carrying an electrical contact plate against which a stud of an indifferent electrode in an electrosurgical grounding pad is locked by a non-conductive cam lever pivotally mounted on the body portion. The body has one end of the grounding cable located therein in attachment to the contact plate with the other end of the grounding cable having a terminal plug for insertion in a socket of the electrosurgical generator. As an adjuvant feature, the body has a receptacle engaged with the contact plate and adapted to receive a pin jack on a grounding wire for interconnecting a monitoring patient cable ground circuit of an electrocardiograph machine (E.K.G.) and the electrosurgical patient grounding cable.

Description

United StatesPatent 1 1 Justus, et al.
[ July 22, 1975 ELECTROSURGICAL GROUNDINC CABLE ASSEMBLY [75] Inventors: George Junior Justus, York Haven.
' Pa.; Lowell C. Miller; Lewisburg Charles T. atrick, Jr., Centerville both of ()hio [73] Assignee: NDM Corporation, Dayton, Ohio [22] Filed: June 20, 1973 [21] Appl. No.: 371,773
[52] US. Cl l28/303.13; 128/206 E; 128/404; 128/D.4; 339/65; 339/274 [51] Int.Cl A6ln 1/04 [58] Field ofSearch 128/206 E, 2.1 B, 303.13, 128/303.14, 303.17, 303.18, 404, 416, 417,
[56] References Cited UNITED STATES PATENTS 2,556,491 6/1951 Dc Lorenzo 339/274 2,590,886 4/1952 Pedcrson 339/274 3,671,924 6/1972 Nagano 339/274 3,699,968 10/1972 Bolduc 128/416 Bolduc 128/416 Zenkich 128/206 E Primary E.raminerWilliam E. Kamm Attorney, Agent, or Firm-Irons & Sears [57] ABSTRACT A connector for the grounding cable of an electrosurgical generator (E.G.) has a nonconductive body carrying an electrical contact plate against which a stud of an indifferent electrode in an electrosurgical grounding pad is locked by a nonconductive cam lever pivotally mounted on the body portion. The body has one end of the grounding cable located therein in attachment to the contact plate with the other end of the grounding cable having a terminal plug for insertion in a socket of the electrosurgical generator.
As an adjuvant feature, the body has a receptacle engaged with the contact plate and adapted to receive a pin jack on a grounding wire for interconnecting a monitoring patient cable ground circuit of an electrocardiograph machine (E.K.G.) and the electrosurgical patient grounding cable.
21 Claims, 9 Drawing Figures Pmunzmmzz I975 3.895535SHEET 1MONITORING DEVICE PATENTEDJUL 22 ms SHEET PATENTEDJUL22 m5 3.895535SHEET 3 ELECTROSIURGICAL GROUNDING CABLE ASSEMBLY BACKGROUND OF THEINVENTION 1. Field of the Invention The present invention generally appertains to new and novel improvements in electrical connectors and is particularly directed to new and novel electrosurgical grounding cable arrangement whereby an indifferent electrode of an electrosurgical generator is connected to the ground terminal of such generator.
2. Description of the Prior Art In electrosurgical procedures, an electrosurgical generator (E.G.) generates high frequency electric current which is fed to an active electrode used to cut tissue and coagulate blood vessels. An indifferent electrode is disposed in contact with the patient to provide a return path of the short-wave current to the E6. which is in turn connected direct to ground or to an isolated ground unit.
The input current is applied to the tissue by means of the active electrode which is preferably of rather small cross-section so as to obtain high current densities at the surgical site. These high current densities provide the desired heating effect needed for the operating procedure. However, it is essential that the indifferent electrode be in such contact with the surface area of the tissue that the return current has a low density, thereby avoiding burning or scarring of the tissue in contact with the indifferent electrode. If the indifferent electrode or its connection to the current source is broken or faulty, the low current density is not achieved and the tissue at the point where a high current leaves will be burned or scarred.
Various factors can produce a faulty ground circuit. But one of the most common causes of faulty grounding is an improper connection of the ground wire.
In some instances, the grounding cable has a male terminal which fits into a socket on a sizeable lead plate used as the indifferent electrode and is fastened thereto by a thumbscrew. The danger in this form of contact is that the terminal of the cable may become detached from the terminal of the plate and the male end on the terminal of the cable, should it touch the patients skin, could concentrate the whole of the current. This would produce a thermoelectrical burn.
To avoid this, the lead plate terminal in some installations is a male contact which fits into an insulated socket on the cable terminal. If such cable becomes detached from the lead plate, there would be no current flow from the plate to ground. The difficulty with such terminal connections is obvious. If this faulty situation occurs and the electrosurgical unit (E.G.) continues to generate current, there is a high possibility of patient burns, since current will seek another path to ground.
In other installations, the ground cable is permanently affixed, as by welding, to the indifferent electrode plate. In such permanent type installation, wear damage to the cable at its point of attachment occurs, and repairing of the cable is very difficult.
In any event, in known installations interrupted ground circuits due to disconnection or improper structural association of the ground cable and the indifferent electrode can occur. And such can take place at crucial times in a given surgical procedure so as to expose the patient to tissue damage and pain. And even if the patient experiences no pain or damage, nonetheless valuable operating time may be lost in effecting a repair of the ground connection. Such lost time may be critical to the electrosurgery procedure, even to the point of affecting the outcome thereof and placing the life of the patient in jeopardy.
SUMMARY OF THE INVENTION It is a primary object of the present invention to provide an electrosurgical grounding cable arrangement which obviates the drawbacks attendant with known manners of attaching ground cables to conventional patient ground plates.
The electrosurgical grounding cable arrangement of the present invention has been designed to provide the utmost in patient safety during electrosurgical procedures and is utilized with an electrosurgical grounding pad of the type and nature disclosed in US. applications Ser. Nos. 223,107, filed Feb. 3, 1972, now abandoned, and 328,120, filed Jan. 30. I973, both of said applications being hereby incorporated herein by reference.
The electrosurgical grounding pad, as described in such applications, comprises an electrolyte/electrode assembly wherein the electrode and electrolyte are at tached by an electrically conductive snap fastener.
The snap fastener has a stud portion that terminates in an enlarged head portion on its projecting distal end at the outer surface of the pad. The terminal head portion provides an annular shoulder on its underside.
The connector of the present invention includes an electrically conductive contact plate which is mounted on one face of a non-conductive body portion, the latter being preferably transparent so as to allow visual inspection of the contact plate and the contact points for the wiring. The body portion and the contact plate are provided with coinciding elongated trackways which slidably receive the shank of the stud. The contact plate is provided with an integrally formed tab which is disposed perpendicularly within the confines of the trackway at the terminal inner end thereof and against which the stud abuts in its fully captive position within the trackway. The tab is inherently resilient, since the contact plate is formed from thin metallic sheet material or similar electrically conductive material.
A locking lever is pivotally carried by the body portion which has a depression or cavity of an outline approximating the geometrical shape and size of the lever formed in the face opposite to the contact plate. The locking lever is pivoted on a pin arranged transversely of the trackway at the outer end thereof. The lever carries on its underside a cam that engages the stud at a point radially opposed to the tab. In the fully depressed position of the locking lever wherein it is seated in the depression in the body portion and lockingly positioned therein, the stud is securely locked between the cam and the tab. In this manner, the connector is positively locked onto the terminal stud of the indifferent electrode.
The grounding cable is preferably a double lead wire encased within a transparent and flexible sheathing formed from thcrmosetting or thermoplastic polymers and copolymers including nylons, polystyrene, polyvinyl chloride, acrylic resins, polyethylene, polypropylene, polyvinylidenc, chloride, and other like insulating and/or engineering plastics.
According to one embodiment, the distal end of the grounding cable has a single pin jack plug provided with two spaced contact points. One of the wires is attached to one of the contact points and the other wire is attached to the other contact point. When the terminal plug is inserted in the proper receptacle of the electrosurgical generator unit or diathermy machine, one of the contacts will be connected to the ground terminal of the machine while the other contact will be connected to a conventional monitoring system build into the machine. Such monitoring system monitors the continuity of the cable and its attachment to the indifferent electrode. In the absence of good and proper contact or cable continuity the monitoring system will activate an alarm means and/or deactivate the electrosurgical unit.
Of course, the present invention encompasses the use of a single wire cable to ground and no monitoring system. According to a preferred embodiment, the contact plate is longitudinally split or spaced apart at its terminal end forming essentially two plates or longitudinal sections only one of which carries the aforedescribed integrally formed tab. Being spaced apart, the sections are in electrical continuity only when the stud portion of the snap fastener is interposed as aforedescribed. In this embodiment, one wire of a double wire cable is attached at its proximal end to one section and the other wire, also at its proximal end, to the other section. Thus, the fastener stud and head complete the circuit, one wire leading to ground and the other wire leading to the monitoring system. Again, in the absence of good and proper contact between the plate and the fastener, or in the absence of cable continuity, the monitoring system will activate an alarm means and/or deactivate the electrosurgical unit.
Alternatively, the inner end of the contact plate may be closed forming a single essentially U-shaped plate having a tab portion, which plate may be used with one or two wires attached thereto. When, as described above, two wires are separately attached to this plate, one to ground and one to the monitoring system, only a faulty cable wire would be monitored, since the inner end of the plate completes the circuit and separation of the fastener from the plate would not be monitored.
During electrosurgical procedures, it is common to have the patient monitored by a conventional electrocardiogram machine which records the nature of the rhythmic change of certain electrical characteristics of the body which are synchronous with the heartbeat. In this way, different aspects of the phenomenon of heart action and circulation of blood in the patient are continually observed.
As an adjuvant feature of the present invention, the connector has its body portion formed with a pin jack receptacle which is attached to the contact plate alongside and along with the ends of the Wires of the grounding cable. Such contact points are rearwardly of the inner end of the trackway. A terminal jack on a grounding wire is adapted to be socketed in the receptacle with the other end of the wire having a terminal jack that is inserted into the ground lead of the electrocardiogram cable.
In such fashion, the patient is hooked onto two grounds, one being the ground terminal of the diathermy machine or electrosurgical unit and the other being the ground circuit of the electrocardiogram machine. In this way, the safety of the patient is much enhanced during electrosurgical procedures. By utilizing the cable connector as a site for connecting the electrocardiogram ground lead, potential grounding hazards possible through the conventional EKG electrode should failure occur in the ground system of the electrosurgical unit are eliminated. Further, the use of the cable connector ground receptacle, instead of the typical EKG ground electrode connector, results in a reduction of monitor interference when the electrosurgical unit is in a stand-by position. The net result is a better recording of the heartbeat.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. I is a partly pictorial, partly schematic diagram illustrating the electrosurgical grounding cable assembly of the present invention in operative association with an electrosurgical grounding pad and depicting the same in use with a patient and in connective association with an electrosurgical unit and an electrocardiograph machine.
FIG. 2 is a perspective showing of the grounding cable assembly and the electrosurgical grounding pad is an unattached relation.
FIG. 3 is a perspective view of the grounding cable assembly in attachment to the grounding pad on the skin surface of a patient.
FIG. 4 is a longitudinal vertical sectional view of the connector attached to the electrode of the grounding pad and showing the locking mechanism in a full line down or locked position and in a dotted line open or unlocked position and is taken substantially on line 4-4 of FIG. 3.
FIG. 5 is a longitudinal horizontal sectional view taken substantially on line 5-5 of FIG. 4 and showing the connector in bottom plan.
FIG. 5A is a bottom plan view of a modified form of connector wherein the contact plate is longitudinally split into two separate longitudinal sections.
FIG. 6 is a transverse vertical sectional view, taken substantially on line 6-6 of FIG. 4.
FIGS. 7 and 8 are fragmentary sectional views showing the locking lever in its open and closed position with respect to the protruding stud on the electrosurgical grounding pad.
Referring now more particularly to the accompanying drawings and initially to FIGS. 2 and 4 for a general understanding of the electrosurgical grounding pad assembly, which is more fully disclosed in the aforementioned patent applications, thepad 10 is composed of a substantially rectangular flexible andresilient sheet 12 carrying a substantially centrally locatednonconductive cup member 14. The cup member has a flat base 16 superimposed on one side or face of the sheet. And the cup member has acavity 18 opening to the body surface of the patient. Within the cavity and resting on the interior surface of the base 16 is aflexible sheet 20 of conductive metal electrode. The diameter of thecup member 14 is substantially greater than its height, thus providing a low profile.
The flexible andresilient sheet 12, thecup member 14 and theflexible sheet 20 of conductive metal are held together by an electricallyconductive stud fastener 22. The fastener includes an innerannular plate 24 from the center of which ahollow shank 26 projects outwardly and anouter plate 28 having ahollow socket portion 30 receiving theshank 26.
The parts are assembled and held together by centrally locating and aligning thecup member 14 containing the likewise centrally located and aligned flexible sheet of conductive metal and theouter plate 28 with itshollow socket portion 30 on opposite sides of thesheet 12. Theshank 26 is inserted through aligned apertures in the centers of the flexibleconductive sheet 20, the base 16 and theresilient sheet 12 and is socketed in thesocket 30. By pressing together such portions of the stud. the upper part of thestud 22 is crimped inwardly and its side walls collapse outwardly whereupon the parts are tightly wedged together. In so doing, the stud, composed of thesheet portion 30 and theshank 26, is formed with an outer rounded and enlarged head ordistal end portion 32 that, due to its enlargement in relation to the shank port of the stud, has an annular groove 34 (cf. FIG. 7) formed below the distal end and defining anannular locking shoulder 33.
The electrolyte is preassembled with theelectrode 10 by soaking a disc-shaped sponge-likecellular matrix 35 of non-conductive, open-cell material with an electrode jelly. The sponge-like matrix 35 preferably has a diameter equal to the diameter of the base 16 of thecup member 14 and a thickness greater than the depth of thecup member 14, as can be appreciated from a consideration of FIG. 4. It is sufficiently heavily laden with electrode jelly that, when theelectrode 10 is pressed on the skin surface of the patient, the jelly fills the entire volume of the cavity between the skin surface and theconductive metal sheet 20 andplate portion 28 whereupon good electrical contact between the skin and the conductivemetal sheet electrode 20 and theconnective stud 22 is assured.
As diagrammatically and pictorially depicted in FIG. 1, theelectrosurgical grounding pad 10 is applied on the arm of the patient P and, because of the nature of the pad, it is easily contoured to the curved skin surface. Obviously, the pad can be applied to the patient in any area selected by the surgeon. But it is preferred that the area be a curved skin surface, such as a thigh or arm easily accessible for attachment of the electro surgicalgrounding cable assembly 36, as shown in FIG. 1. The pad is applied by pulling it taut just as in the manner of applying a bandage.
The electrosurgicalgrounding cable assembly 36 is generally composed of aconnector 38 which is lockingly attached to thehead portion 32 of thestud 22 by being slidably engaged within thegroove 34, as shown in FIG. 4. Theconnector 38 has one end of acable 40 attached thereto, as will be described, so as to be in electrically conductive relation with thestud 22 and thereby with theindifferent electrode 20. The groundingcable 40 is composed of twolead wires 42 and 44 that are housed in a transparent insulative sheathing or covering 46. The sheathing or covering 46 is flexible and preferably transparent so that a quick visual inspection can be made for any breakage or damage of thelead wires 42 and 44 housed therein. The sheathing is formed from non-conductive transparent materials,
such as thermosetting or thermoplastic polymers and 6 polymethacrylate; polymethylmethacrylate and polyacrylonitrile, copolymers thereof and other like acrylic resins; polyethylene; polypropylene; polyvinylidene chloride; polysulfones; polycarbonates; and other like insulating and engineering plastics.
The electrosurgical generator orunit 52 has anactive electrode 54 which is connected by a lead 56 provided with aswitch 58, preferably a foot switch, to the output circuit system of theelectrosurgical unit 52. Such a unit is conventional and, in general, comprises a high frequency current generating system including a RF. oscillator which drives a gain controlled power amplifier that is coupled via a step-up transformer and coupling capacitors to theactive electrode 54. The unit has asuitable receptacle 60 in which theterminal plug 48 is inserted.
The groundingcable 40 is a twin lead wire cable with thejack plug 48 being a common plug for both lead wires. The plug has two spaced apart electrodes or contact points 62 and 64. Thus, when theplug 48 is inserted in thereceptacle 60 in the electrosurgical unit ordiathermy machine 52, as shown schematically in FIG. 1, thelead wire 42 of the grounding cable is carried to theground terminal 66 while the other lead wire is carried to amonitoring device 68.
The monitoring device is of conventional construction and functions either to sound an alarm and/or deactivate the electrosurgical unit. Generally speaking, the monitoring device has a solenoid and thelead wire 44 in thegrounding cable 40 establishes a continuous circuit from theelectrosurgical unit 52 to the indifferent electrode and back again which holds open the solenoid. As soon as this circuit is broken, as above described, e.g., by theconnector 38 becoming somehow impaired or loosened from thestud 22 of theindifferent electrode 20, when using a split contact plate, the circuit is broken, the solenoid closes and themonitoring device 58 initiates its alarm and/or deactivating action.
However, it is obvious, as far as the present invention is concerned, and as previously pointed out, that thecable 36 can be a single wire cable which merely is a grounding wire. Theother wire 44 can be eliminated if themachine 56 does not possess the conventional monitoring device or system.
As shown in FIG. 1, the patient P is connected via unipolar limb leads 70 and 72 to the central terminal 74 of aconventional electrocardiograph machine 76. The machine is provided with the usual three-prong plug, one prong of which constitutes the ground.
As is well known, the conventional electrocardiograph machine, such as themachine 76 in FIG. 1, is provided with the usual central terminal connection 74 from which a series of electrical leads extend. Ordinarily, at least four such leads extend from the central terminal connection 74 to the arms and legs of the patient. There is also a second terminal, commonly referred to as the exploring terminal, from which an exploratory lead extends, this lead being designed for successive application by the operator of the machine to various portions of the chest.
However, for purposes of its use in electrosurgical procedures, it is common to use three EKG electrodes, one of which is used as a ground connection to the EKG monitor. In accordance with the present invention, an interconnectingwire 78 is connected between theEKG 76 and theconnector 38 so as to eliminate the need for the conventional EKG ground electrode. In this respect, as shown in FIG. 2, theend portion 50a of thebody 50 of theconnector 38 is provided with a female socket orreceptacle 80 in which thejack plug 82 of the interconnectingwire 78 is socketed. The wire has asimilar jack plug 83 provided on its opposing end and such jack plug fits in the central terminal connection 74 (FIG. 1). In this manner. the EKG and the electrosurgical unit are groundingly interconnected.
By virtue of the interconnectingwire 78, the patient is provided with two ground sources, one theEKG 76 and the other the diathermy machine orelectrosurgical unit 52. By utilizing the interconnectingcommon grounding wire 78, further advantages can be obtained. One advantage is a reduction of monitor interference when the electrical surgical unit is in a stand-by position. Another advantage is the elimination of potential grounding hazards possible through the conventional EKG. electrode should failure occur in the electrosurgical ground unit. Another advantage resides in the elimination of the conventional EKG ground electrode.
Theconnector 38, as shown more particularly in FIGS. 3-8, includes thebody portion 50, which is solid and which is molded or otherwise formed from the various plastics materials, as aforedelineated. Preferably, the body portion is formed from clear material as is theterminal plug 48 and the casing or sheathing 46 of thegrounding cable 36. Such transparency is desirable since it permits the operator, prior to use, to visually inspect the entire grounding cable assembly for any obvious breakage or damage.
Thebody portion 50 has arear end portion 50a in which one end of the cable with its enclosed lead wires is inserted.Such end portion 50a houses thejack receptacle 80 for the interconnectinggrounding wire 78. The body has afront end portion 84 and it has a top side orface 86 and a bottom side orface 88.
Acontact plate 90, formed of metal or other conductive thin sheet material, is securely superimposed on thebottom face 88 by rivets 92 or similar fastening means. Thecontact plate 90 has arear lip portion 94 which is bent upwardly and fits within agroove 97 formed in the underside of therear end portion 50a of thebody 50. Thelead wires 42 and 44 of thecable 40 are attached by solder or the like to thelip portion 94, as shown in FIG. 5. The receptacle orsocket 80 for the interconnectingwire jack 82 is soldered to the'rivet 92a of the contact plate, as shown in FIG. 5. In any event, the receptacle orsocket 80 and the lead wires are in good electrical contact with the contact plate. All of such contact points are visible through the upper face of the body portion.
Thebody 50 is formed with anelongate slot 96 that defines a trackway and that passes through thefront end portion 84, as shown in FIGS. 4, and 6. The trackway is rectangular and of a width just slightly greater than the diameter of thestud 22 at itsgrooved portion 34 so that the opposingstraight side edges 96a and 96b of the trackway slide in the groove, without undue lateral play and dispose the body portion beneath theshoulder 33. As the trackway opens through the forward end, the side edges diverge outwardly so that the open front end of the trackway is defined by adivergent throat portion 98 which serves to guide the trackway onto the stud. In this respect, the opposing side edges 100 and 102 of thebody portion 50 are formed with recessed finger gripping areas .104 and 106 whereby the body can be manually manipulated.
The contact plate is provided with atab 108 which extends upwardly therefrom and which is disposed perpendicularly wthin the trackway at the inner edge thereof so that it confronts the inner lateral end wall of the trackway. The tab is of a width commensurate with the width of the trackway and is positioned at the inner end thereof so that it will be engaged by the head of thestud 22 in the manner shown in FIG. 4. This will insure good electrical contact between the stud extending from theelectrode 20 and the ground cable.
FIG. 5A differs from FIG. 5 in that thecontact plate 90 is split longitudinally at its inner end providing separate longitudinal plate sections 91(a) and 91(b) and lip portions 94(0) 94(b) extending from said sections, the split providing opposed, parallel edge extensions of trackway straight side edges 96(0) and 96(1)).Cable lead wires 44 and 42 are attached to lip portions 94(a) and 94(b), respectively. Interposedfastener head portion 32 and shoulder 33 (FIG. 6) provide the electrical continuity between both sections. Obviously, removal of the fastener would interrupt the continuity.
In order to insure that such electrical contact is maintained and to lock the connector onto the stud, a locking means 110 is provided adjacent the outer or open end of thetrackway 96 and at thefront end portion 84 of theconnector body 50. Such locking means includes a pivotedlever 112 formed of non-conductive material and preferably formed of the same clear material as thebody 50 of the connector. The lever has aflat body portion 114 and thetop wall 86 of theconnector body 50 is formed with a cavity ordepression 116 of a size and shape approximating the geometrical shape and size of the body of the lever. The lever body is adapted to seat in such depression or cavity, as shown in FIGS. 3 and 4. The lever body has atail end portion 118 which is mounted on apivot pin 120 that is fixed transversely between the opposing side walls of the depression at theforward end portion 84 of the body. The pivot pin is positioned, as can be seen from FIG. 4, in a plane above the plane of the bottom wall of the depression so that thebody portion 112 of the lever seats on the bottom wall and is disposed below the pivot axis so as to be locked in its seated position.
The lever body, as can be seen in FIGS. 2 and 4, has anintegral cam bar 122 formed on its underside and providing acam surface 124 which is adapted to engage thehead 32 of thestud 22, as shown in FIG. 4 so as to clampingly hold the head tightly against thecontact tab 108. Thus, when the lever is in its down or seated position, the cam engages the head to lock the connector onto the stud. The bar is of a width to fit in the trackway behind thepin 22.
The lever has a free end which is provided with anangular lip 126 which extends upwardly and forwardly when the lever is in its seated position, as shown in FIG. 4. In such position, the lip projects above the top surface of the wall of theconnector body 50. The lip serves as a finger gripping means so as to move the lever upwardly and downwardly about its pivot axis.
For the purpose of locating thecable 36 and the interconnectinggrounding wire 78 so as to hold them out of any conflicting position, with respect to the patient, surgeon, and other operating room attendants, a clamping means 128 is provided, as shown in FIG. 2. The clamping means includes abar 130, having aguide arrangement 132 through which the cable and wire are passed. The bar terminates in analligator clip 134 that can be attached to a patient covering sheet or other holding means readily accessible to the operating table.
In use, the first step that must be taken is to visually inspect theconnector 38 by locking through the transparent body. 50 so as to inspect the contacts for the interconnectinggrounding wire 78. Thewires 42 and 44 should be visually inspected as should the contacts in theterminal plug 48. Since theterminal plug 48 and thebody portion 50 of the connector are formed from a clear material, such visual inspection can be readily carried out. Also, due to the transparency of thesheating 46 for the cable, the continuity of thewires 42 and 44 can be easily visually determined.
The next step requires the insertion of theplug 48 into theproper receptacle 60 in theelectrosurgical generator 52. Prior to this, the electrosurgical grounding pad has been wrapped around the arm of the patient P, as shown in FIG. I. The operator then grasps the body of theconnector 38 with the thumb and middle finger of one hand being disposed in the recessed orcutout areas 104 and 106 on the sides of the connector. The connector is held and slidably placed over thehead 32 of thestud 22 so that the trackway slides in thegroove 34. In this respect, it is to be noted from FIGS. 5 and 5A that thecontact plate 90 has atrackway 900 formed therein complemental to and underlying the trackway in the body portion. However, the side edges of the trackway 90a incontact plate 90 protrude inwardly of the sides of the trackway in thebody 50 of the connector. Thus, the stud will engage the side edges 96a of the trackway in the contact plate. This is easily determined by visual inspection.
The body is slid over the stud until thecontact tab 108 abuts thestud 22. At this point, the lockinglever 112 is pressed downwardly with the forefinger while holding the connector body between the thumb and middle finger. A positive snapping action takes place and the connector is locked onto the stud.
While theconnector 38 is especially designed for use in the disclosed electrosurgical environment, it can be appreciated that the same possesses utility for use in other akin or dissimilar environments.
Thus, in this respect and in regard to the other details of the inventive concept, as herein disclosed, it is to be understood that such specific disclosure is merely exemplary. And the inventive concept is only to be interpreted in accordance with the terms and scope of the appended claims.
What is claimed is:
1. For use with electrosurgical equipment including (a) an electrosurgical generator for generating high frequency electric current, (b) an active electrode electrically connected to said generator and used to cut tissue and coagulate blood, and (c) an indifferent electrode for attaching to a patient an electrical ground means, a grounding assembly suitable for said electrosurgical equipment and comprising, in combination, a connector and a cable, said connector, in turn, comprising a body provided with a slot defining an open trackway along a face of said body for receiving, on one end of the trackway, a conductor electrically coupled to said indifferent electrode, and means at the opposite end of the trackway for terminating the trackway while still retaining said conductor on said trackway, an electrically conductive contact means, carried by said body,
electrically coupled with said conductor on said trackway, while said conductor is in said trackway, and with one end of the cable, the opposite end of said cable being electrically coupled to ground, and locking means carried by said connector and positionable in said trackway to lock said conductor in electrical contact with said contact means.
2. The invention ofclaim 1, wherein said connector has a non-conductive solid body.
3. The invention ofclaim 2, wherein said conductor electrically coupled to said indifferent electrode is a projecting stud over which the trackway slides and said stud is formed with a groove in which the trackway moves.
4. The invention ofclaim 3 wherein said contact means includes a resilient tab of conductive material arranged generally perpendicularly of the trackway and providing said means at one end of the trackway to terminate travel of the latter along the conductor.
5. The invention of claim 4, wherein said locking means includes a lever formed from non-conductive material, a pivot pin arranged transversely of the trackway adjacent the open end thereof, said lever having one end mounted on the pivot pin for swinging movement about an axis normal to the trackway and said lever having an opposing free end portion having a cam surface releasably engaging the stud in clamping relation with the tab.
6. The invention ofclaim 5, wherein said connector body has opposing top and bottom faces, said opening of said trackway being in said bottom face of said body, said contact means including a plate portion fixed on the bottom face and from which the tab upstands in the trackway, said connector body having opposing ends and the trackway being elongated and passing through one end of the body and said pivot pin being disposed and passing through one end of the body and said pivot being disposed at said end.
7. The invention ofclaim 6, wherein said plate portion is longitudinally split to effect two plate sections and the resilient contact tab upstands in the trackway from one of said sections and arrests the inward movement of the stud along the trackway.
8. The invention of claim 7 wherein said top face of the connector body has a depression of a size and shape approximating the size and shape of the lever which is seated therein, said depression, in turn, having an opening in the bottom thereof in communication with said trackway having said stud upstanding therein, the opening being of a size and shape approximating the size and shape of the cam surface releasably engaging the stud in clamping relation with said tab, and said pivot pin is in a plane above the plane of the bottom of the depression with said lever being disposed below the pivot pin plane when it is seated in the depression so that it is below its pivot axis and is locked in place in the depression.
9. The invention of claim 8 wherein said locking lever has an angular lip on its free end, said lip projecting upwardly from the lever in its seated and locked position and defining a finger piece.
10. The invention of claim 9 wherein said connector body is transparent.
11. The invention of claim 9 wherein said cable whose proximal end is attached to said connector comprises lead wire encased in transparent plastic for visual inspection of the lead wire, and, at the distal end of the cable, a transparent terminal plug for visual inspection of the contact means by which the distal end of said lead wire is attached.
12. The invention ofclaim 1 wherein said electrosurgical equipment includes an electrocardiograph machine having a monitoring patient cable ground circuit and said connector is provided with a receptacle in contact with the contact means, a grounding wire having opposing jack plug ends, one of said jack plug ends being attached to the ground jack of the electrocardiograph machine and the other jack plug end being insertable in the receptacle in the connector body.
13. A cable grounding assembly for use with an electrosurgical grounding pad having a patient contacting inner surface and an outer surface from which a stud projects having an annular groove, said assembly comprising a connector having a solid non-conductive body portion having opposing top and bottom faces, and formed in the bottom of said faces is a slot-like, elongated trackway which slides over the stud and in the groove, said trackway having an outer end and an at least partially closed inner end, an electrically conductive contact plate fixed to the bottom face and having an integral inherently resilient tab projecting therefrom and disposed in the trackway at the inner end thereof and which bears against the stud, a locking lever of non-conductive material pivotally mounted on the connector body adjacent the outer end and means for locking the lever in clamping relation with the stud so as to lock the latter against the contact tab to prevent motions transverse to and parallel to said trackway and a grounding cable extending from the connector body in contact with the contact plate and having a distal end provided with a terminal plug adapted to be inserted in an electrosurgical unit.
14. The invention of claim 13 wherein said locking means includes said top face of the connector body being formed with a depression of a size and shape to receive the lever and a pivot pin for the lever arranged in the connector body transversely of the trackway at the open end thereof and disposed in a plane above the bottom of the depression so that the major part of the lever is below the pivot axis when seated in the depression.
15. The invention ofclaim 14, wherein said lever has a free end provided with an angular lip that upstands therefrom when the lever is seated in the depression and extends above the top face of the connector body.
16. The invention of claim 13, wherein said connector body, grounding cable and terminal plug are transparent.
17. The invention of claim 16 wherein the connector body. the cable and the terminal are formed from transparent polymeric materials.
18. A grounding assembly suitable for use with electrosurgical equipment and comprising, in combination, a connector and a cable, said connector, in turn, comprising a body provided with a slot defining an open trackway along a face of said body for receiving on one open end of the trackway, a conductor and means at the opposite end of the trackway for terminating the trackway while still retaining said conductor on said trackway, an electrically conductive contact means, carried by said body, electrically coupled with said conductor on said trackway, while said conductor is in said trackway, and with one end of the cable, the opposite end of said cable being electrically coupled to ground, and locking means carried by said connector and positionable in said trackway to lock said conductor in electrical contact with said contact means.
19. The invention ofclaim 18 wherein said conductor is a stud having an annular groove in which the trackway slides.
20. The invention ofclaim 18 wherein said connector body has a bottom face and a top face and said contact means further includes a thin plate fixedly superimposed on the bottom face and having a trackway complementing the body trackway but of slightly less width than the body trackway so that the bounding walls of the contact plate trackway engage the conductor.
21. The invention ofclaim 18 wherein said connector body has a top face formed with a surface cavity and said locking means includes a locking lever, a pivot pin mounted in the connector body adjacent the open end of the trackway and arranged transversely thereof, said lever having one end pivoted on said pin and having a cam means on its other end releasably engaging the conductor, with said lever being sealed in the cavity and bearing against the conductor.
UNITED STATES PATENT OFFICE CERTIFICATE OF CORRECTION PATENT N0. 3, 895, 635
DATED July 22, 1975 INVENTOR(S) :George Junior Justus tal.
It is certified that error appears in the above-identified patent and that said Letters Patent are hereby corrected as shown below:
Column 10,line 38, delete "being disposed".
Signed and Scaled this sixteenth D a y Of December 1 9 75 [SEAL] A ties t:
RUTH C MASON C. MARSHALL DANN Arresting Officer Commissioner of Patents and Trademarks

Claims (21)

1. For use with electrosurgical equipment including (a) an electrosurgical generator for generating high frequency electric current, (b) an active electrode electrically connected to said generator and used to cut tissue and coagulate blood, and (c) an indifferent electrode for attaching to a patient an electrical ground means, a grounding assembly suitable for said electrosurgical equipment and comprising, in combination, a connector and a cable, said connector, in turn, comprising a body provided with a slot defining an open trackway along a face of said body for receiving, on one end of the trackway, a conductor electrically coupled to said indifferent electrode, and means at the opposite end of the trackway for terminating the trackway while still retaining said conductor on said trackway, an electrically conductive contact means, carried by said body, electrically coupled with said conductor on said trackway, while said conductor is in said trackway, and with one end of the cable, the opposite end of said cable being electrically coupled to ground, and locking means carried by said connector and positionable in said trackway to lock said conductor in electrical contact with said contact means.
13. A cable grounding assembly for use with an electrosurgical grounding pad having a patient contacting inner surface and an outer surface from which a stud projects having an annular groove, said assembly comprising a connector having a solid non-conductive body portion having opposing top and bottom faces, and formed in the bottom of said faces is a slot-like, elongated trackway which slides over the stud and in the groove, said trackway having an outer end and an at least partially closed inner end, an electrically conductive contact plate fixed to the bottom face and having an integral inherently resilient tab projecting therefrom and disposed in the trackway at the inner end thereof and which bears against the stud, a locking lever of non-conductive material pivotally mounted on the connector body adjacent the outer end and means for locking the lever in clamping relation with the stud so as to lock the latter against the contact tab to prevent motions transverse to and parallel to said trackway and a grounding cable extending from the connector body in contact with the contact plate and having a distal end provided with a terminal plug adapted to be inserted in an electrosurgical unit.
18. A grounding assembly suitable for use with electrosurgical equipment and comprising, in combination, a connector and a cable, said connector, in turn, comprising a body provided with a slot defining an open trackway along a face of said body for receiving on one open end of the trackway, a conductor and means at the opposite end of the trackway for terminating the trackway while still retaining said conductor on said trackway, an electrically conductive contact means, carried by said body, electrically coupled with said conductor on said trackway, while said conductor is in said trackway, and with one end of the cable, the opposite end of said cable being electrically coupled to ground, and locking means carried by said connector and positionable in said trackway to lock said conductor in electrical contact with said contact means.
US371773A1973-06-201973-06-20Electrosurgical grounding cable assemblyExpired - LifetimeUS3895635A (en)

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