US3736936A - Cryogenic heat transfer device - Google Patents

Abstract

Heat transfer devices especially suitable for cryosurgery are disclosed each including an elongated tubular housing of low thermal conductivity having an open end and a closed end. A conical probe member of high thermal conductivity is mounted at and extends from the closed end of the housing. A capillary wick lining the inner lateral surface of the housing is adapted to convey a volatile working fluid such as liquid nitrogen at a temperature of -196*C from the vicinity of the open end of the housing to the vicinity of the closed end. A working fluid reservoir is disposed about the open end of the housing in fluid communication with the capillary wick. An annular evacuated chamber is provided about the outer surface of the reservoir and a substantial portion of the outer lateral surface of the housing to afford thermal insulation.

Description

United States Patent 1 Basiulis et a1. [4 June 5, 1973 [54] CRYOGENIC HEAT TRANSFER 3,532,094 10/1970 Stahl "128/3031 DEVICE 3,568,464 3/1971 Drayson 3,618,610 11/1971 Hannant ..128/303.1 [75 lnventorsz Algerd Basluhs, Redondo Beach,

E1mer E. Reed, Jr., Downey, b Primary Examiner-Aldrich F. Medbery ofcahf- Attorney-W. H. MacAllister, Jr. and Allen A. Dicke, [73] Assignee: Hughes Aircraft Co., Culver City, v

' Calif. 22 Pl d D 13 1971 [57] ABSTRACT I 1 1e Heat transfer devices especially suitable for cryosur- [21] Appl. No.: 207,431 gery are disclosed each including an elongated tubular housing of low thermal conductivity having an open end and a closed end. A conical probe member of [52] US. Cl. ..l28/303.l, 128/400,6121/g/9l5 g thermal conductivity is mounted at and extends from the closed end of the housing. A capillary wick mm t e inner atera su ace 0 t e ousm 1s ntif|...s....A6h1b 17/36, F25d132/(8)03$0|lk4:)1l/())(0 g h l rf f h h g o are 1 62 adapted to convey a volatile working fluid such as I liquid nitrogen at a temperature of 196C from the vicinity of the open end of the housing to the vicinity [56] References cued of the closed end. A working fluid reservoir is UNITED STATES PATENTS disposedabout the open end of the housing in fluid communication with the capillary wick. An annular 3,190,081 6/1965 .Pytryga ..62/293 evacuated chamber is provided about the outer sur- 3,421,508 H 9 Nestrock ..l28/303.l face of the reservoir and a substantial portion of the 3,434,477 1969 Thomas, "123/3031 outer lateral surface of the housing to afford thermal 3,455,304 7/1969 Gans ..12s/303.1 insumiom 12/1969 Ziegler ..62/293 13 Claims, 3 Drawing Figures PAIENIEUJHH 519/6 SHEET 10F 2 Fig. 1.

PATENTEUJUN 5 I973 SHEET 2 [1F 2 CRYOGENIC HEAT TRANSFER DEVICE FIELD OF THE INVENTION This invention relates generally to heat transfer devices, and more particularly relates to a wholly selfcontained, handheld cryogenic surgery tool which is readily portable, easily and quickly activated and convenient to use.

DESCRlPTlON OF THE PRIOR ART Certain surgical operations, such as a hemorroidectomy, may be performed quickly and painlessly by freezing the cells of the affected tissue. As subfreezing temperatures are reached and ice formation occurs in the cell, cellular organization is irreversibly altered. As the frozen tissue thaws, water is removed from the interior of the cell, resulting in cellular dehydration and destruction. Cryosurgical techniques are also being used in the treatment of chronic cervicitis, endometrial carcinoma, Parkinsonism, cataracts, and other diseases.

The usual procedure in cryosurgery is to lower the temperature of the diseased tissue to at least about 20C. There are a variety of techniques for achieving such low tissue temperatures. One method is to dip an applicator such as a cotton swab or copper disk into liquid nitrogen (which is at l96C) and then apply it to the diseased tissue. However, the use of such an applicator usually requires repeated applications, and great care must be taken to insure that only the diseased tissue is destroyed and not the surrounding healthy tissue.

Apparatus presently employed for performing cryosurgery consists of a control console with a liquid nitrogen supply and a cryoprobe. The console houses a Dewar container, having a capacity of 5 liters, and associated control and monitoring circuits. A heating system for thawing the cryoprobe is also included in the console. An input hose conveys liquid nitrogen from the Dew'ar' container to thecryoprobe, while an output hose returns the liquid nitrogen to the console where it is exhausted into the atmosphere. In operation, liquid nitrogen (at -l96 C) is placed in the Dewar container, and the container is sealed. Pressure within the container is increased, forcing the nitrogen through the input hose to the cryoprobe. The cryoprobe tip is cooled to about 1 80C by the flow of the liquid nitrogen past the cryoprobe. The liquid nitrogen is then returned to the supply console via the output hose to be exhausted to the atmosphere as a vapor.

Although the aforedescribed apparatus has been used successfully in performing cryosurgery, about one minute of operation time is required before stabilization at the desired low temperature is achieved, largely because of the inefficiency of cooling by liquid flow. Moreover, since the cryoprobe is connected to the console unit by bulky hoses, two hands are required to hold the cryoprobe apparatus during the surgery. Thus, the apparatus is rather cumbersome to use, and the surgeon must be assisted in all but the simplest of operations. In addition, the entire apparatus (including the control and supply console) is relatively bulky and weights about 100 pounds, and a relatively large supply of liquid nitrogen is required for the apparatus to operate properly. Thus, a constraint is imposed on use of the apparatus by the availability of manpower to move both the apparatus itself and an adequate supply of liquid nitrogen to the site where the operation is to be performed.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a simple, reliable and convenient heat transfer device especially suitable for operation at cryogenic temperatures.

It is a further object of the present invention to provide a heat transfer device for performing cryosurgery which reaches the desired operating temperature very quickly and maintains that temperature readily.

It is a still further object of the invention to provide a small, handheld cryosurgery tool which is completely self-contained and readily portable.

In accordance with the foregoing objects, a heat transfer device according to the invention includes an elongated housing of low thermal conductivity having an open end and a closed end. A probe member of high thermal conductivity is mounted at and extends outwardly from the closed end of the housing. A capillary wick is longitudinally disposed within the housing for conveying a volatile working fluid from the vicinity of the open end of the housing to the vicinity of the closed end. A working fluid reservoir is provided about the open end of the housing in fluid communication with the capillary wick. Thermal insulation is provided about the outer surface of the reservoir and a substantial portion of the outer lateral surface of the housing.

The foregoing and other objects and features of the present invention will become readily apparent from the following detailed description of preferred embodiments of the invention when considered in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS In the drawings:

FIG. 1 is a longitudinal sectional view illustrating a heat transfer device according to one embodiment of the present invention;

FIG. 2 is a perspective view illustrating a heat transfer device according to another embodiment of the invention; and

FIG. 3 is a longitudinal sectional view of a portion of the device of FIG. 2 as taken along line 3-3 of FIG. 2.

Referring more specifically to FIG. 1, a heat transfer device according to the invention may be seen to include a thin-walled elongatedtubular housing 10 having a closed end 11 and an openopposite end 12 which may be of reduced diameter as shown. The housing is preferably of a material of low thermal conductivity such as stainless steel, for example. The vicinity of the closed end 11 of thehousing 10 functions as an evaporation region where a working fluid contained within the housing is vaporized by applied heat; A taperedprobe 14, shown as having a generally conical configuration, is mounted withinextension 10a of thehousing 10 with its base contacting the housing end wall 11 alternatively, separate end wall member 11 may be eliminated with the base ofprobe 14 constituting an end wall for thehousing 10. Theprobe 14, which should be of a material of high thermal conductivity, absorbs heat from a source, such as living tissue for example, and transfers heat by conduction to the housing wall 11. The probe may be held in place by frictional force with the inner lateral surface ofhousing extension 10a or, alternatively, by threads provided onextension 10a andprobe 14. It is pointed out that while a particular probe shape has been illustrated, the shape ofprobe 14 is not critical and may vary depending upon the particular application of the heat transfer device.

Acapillary wick 15 lines the inner lateral surface of thehousing 10. Thewick 15 may be made of any material through which fluid can travel by capillary forces, examples of suitable wick materials being felt cloth, stainless steel screen, and sintered metal fibers. It is pointed out that thecapillary wick 15 need not line the entire inner lateral surface ofhousing 10, and other wick arrangements such as a plurality of longitudinally extending wick strips circumferentially spaced along the inner surface ofhousing 10 may be employed in the alternative.

A workingfluid reservoir 16 is provided for thehousing 10 in the vicinity of itsopen end 12. Thereservoir 16 is defined by a tubular member 17 coaxially mounted abouthousing 10 at its open end region and anannular member 19 extending inwardly from the lower edge of member 17 to the outer surface ofhousing 10. Theannular member 19 is welded or otherwise attached to the member 17 and to thehousing 10 so as to form a fluid tight seal therewith. The reservoir members l7 and 19 are preferably of a material of low thermal conductivity such as stainless steel, for'example. In order to provide fluid communication between thereservoir 16 and thecapillary wick 15, a plurality of circumferentially spacedapertures 18 may be provided inhousing 10 just above where it is sealed toannular reservoir member 19.

In order to provide thermal insulation for the device, a tubular metal shell is coaxially disposed about thehousing 10 and thereservoir members 19 and 17 in a manner providing an annular space between theshell 20 and themembers 10, 17 and 19, the end regions of theshell 20 being in hermetically bonded relationship with the respective end regions of thehousing 10 and the reservoir member 17. The annular space between theshell 20 and thehousing 10 andreservoir members 17 and 19 is evacuated to provide the desired thermal insulation. A coating of fiberglass or plastic may be applied over the outer surface of theshell 20 to provide additional thermal insulation, if desired.

The open upper end ofreservoir 16, which affords a fluid inlet to thereservoir 16, may be covered by acap 21 during operation of the device. Thecap 21 consists of a flat circular member 22 having acentral exhaust port 23 axially aligned with the opening inend 12 ofhousing 10 and alip 24 projecting downwardly from the circumferential edge of member 22. Thermal insulation for thecap 21 may be afforded by an evacuated chamber defined bymembers 22, 24, and ametal shell 25 disposed about and spaced from themembers 22 and 24 and in a hermetically bonded relationship there with.

Thecap 21 may be attached to thereservoir 16 bymating threads 26 on the inner surface of anannular extension 27 of theshell 25 and on the outer surface of theshell 20 adjacent its upper end. A fluid tight seal may be provided between thecap 21 and thereservoir 16 by means of anO ring 28 disposed in an annular groove-definingmember 29 mounted between theshell 20 and the reservoir member 17 at the upper ends thereof, and anannular flange 30 projecting from thecap 21 into the groove ofmember 29 and adapted to compressO ring 28.

In operation of the heat transfer device of FIG. 1, a suitable lowtemperature working fluid 40 at a temperature below its boiling temperature is poured into thereservoir 16. Examples of particular working fluids which may be employed are liquid nitrogen at l96 C, oxygenat l83 C, or freon at -8l C.

The workingliquid 40 in thereservoir 16 flows into thehousing 10 throughapertures 18, wetting thecapillary wick 15. The liquid 40 moves into the wick l5 and is conveyed by capillary action along thewick 15 toward the end of thehousing 10 adjacent theprobe 14 as long aswick 15 is not saturated. However, once thewick 15 becomes saturated, additional liquid i'sprecluded from entering thehousing 10 viaapertures 18.

Upon reaching the evaporator wall 11, the liquid 40 becomes vaporized because the temperature of evaporator wall 11 is initially much higher than the boiling temperature of the liquid 40. It is well known that in the process of vaporization a liquid will absorb heat from its surroundings and thereby lower the temperature of the surroundings. Thus, as the liquid 40 reaching evaporator wall 11 continues to be vaporized, the temperature of evaporator wall 11 (and hence probe 14) is lowered to the boiling temperature of the liquid 40.

When theprobe 14 is placed in contact with a heat source, such as living tissue for example, heat is transferred from the heat source to theprobe 14 and con veyed by conduction to the evaporator 11, causing a slight rise in the temperature of evaporator 11. This in turn causes more liquid 40 to be vaporized which again lowers the temperature of evaporator 11 andprobe 14. Thus, theprobe 14 is maintained essentially at the boiling temperature of the workingfluid 40.

Since the vaporizing fluid causes a pressure increase in the region of thehousing 10 adjacent the evaporator 11', the vapor travels along the housing to the vicinity of theopen end 12. There some of the vapor condenses into liquid as it contacts the colder temperature of thecapillary wick 15. The remaining vapor passes through the opening atend 12 and is exhausted to the atmosphere throughport 23.

A heat transfer device according to another embodiment of the present invention is illustrated in FIGS. 2 and 3. Components in the embodiment of FIGS. 2 and 3 which are similar to respective components in the embodiment of FIG. 1 are designated by the same reference numerals as their corresponding components in FIG. 1 except for the addition ofa prefix numeral l The embodiment of FIGS. 2 and 3 differs from the embodiment of FIG. 1 in that housing is bent by about 45 in theregion 150 where housing 110 entersreservoir 116. Also,apertures 118 providing fluid communication between thereservoir 116 and the housing 110 are located closer to the open end 112 ofthe-housing 110. Thereservoir 116, includingtubular member 117 andend member 119, as well as thermally insulatingouter shell member 125, is detachable from the remainder of the device in order to facilitate filling thereservoir 116 with working fluid.Mating threads 126 are provided on the outer surface of shell near its end region and on the inner surface of enlargedtubular extension 152 of a funnel-like transition member 154 hermetically bonded to theshell 120 surrounding the portion of housing 110 outside ofreservoir 116. An essentially U-shaped vent tube 160, mounted within thereservoir 116 by means not shown, has one end extending into the housing 110 to the vicinity of bend and the other end extending to aregion 162 externally of the housing 110 in the vicinity of thetransition member 154. The vent tube 160 conveys vaporized working fluid through the contained liquid 140 in thereservoir 116 to theregion 162 from where it is vented to the atmosphere externally of the reservoir via an essentially L-shapedexhaust tube 164.

It should be apparent from the foregoing that the present invention provides a self-contained, simple, and readily portable heat transfer device which is especially suitable for performing cryosurgery. Moreover, the device reaches the desired low operating temperature very quickly and maintains that temperature readily. In fact, heat transfer devices according to FIG. 1 and FIGS. 2-3 have been constructed which weigh slightly over two pounds and reach an operating temperature of l96 C within 30 seconds after theirrespective reservoirs 16 and 116 have been filled with liquid nitrogen at a temperature ofl96 C.

Although the present invention has been shown and described with reference to particular embodiments, nevertheless, various changes and modifications obvious to one skilled in the art to which the invention pertains are deemed to lie within the purview of the invention.

What is claimed is:

1. A heat transfer device comprising:

an elongated housing of low thermal conductivity having an open end and a closed end;

a probe member of high thermal conductivity mounted at said closed end of said housing and extending therefrom;

capillary wick means longitudinally disposed within said housing for conveying a volatile working fluid from the vicinity of said open end to the vicinity of said closed end of said housing;

means defining a working fluid reservoir disposed about said open end of said housing in fluid communication with said capillary wick means; and

thermally insulating means disposed about the outer surface of said reservoir means and a substantial portion of the outer lateral surface of said housing.

2. Aheat transfer device according to claim 1 and further including means for providing a vapor exhaust path from said reservoir.

3. A heat transfer device according to claim 2 wherein said means defining said reservoir includes a removable cap member having a vapor exhaust port therein.

4. A heat transfer device according to claim 1 wherein said means defining said reservoir includes first and second detachable members, and means for forming a hermetic seal between said first and second members when in attached relationship.

5. A heat transfer device according to claim 1 wherein said thermally insulating means includes a shell member disposed about and spaced from said housing and a portion of said reservoir means and hermetically bonded thereto, the space between said shell member and said housing and said reservoir portion being evacuated.

6. A heat transfer device for performing cryosurgery by freezing comprising:

an elongated tubular housing of low thermal conductivity having an open end and a closed end;

a tapered probe member of high thermal conductivity mounted at said closed end of said housing with its portion of greatest cross-section adjacent to said closed end;

capillary wick means longitudinally disposed along the inner lateral surface of said housing for conveying a volatile working fluid from the vicinity of said open end to the vicinity of said closed end of said housing;

means coaxially disposed about said housing in the vicinity of said open end for defining a working fluid reservoir, said housing defining a plurality of circumferentially spaced apertures in its lateral surface near said open end to provide fluid communication between said reservoir and said capillary wick means;

means for providing a vapor exhaust path from said reservoir; and

thermally insulating means disposed about the outer surface of said reservoir means and a substantial portion of the outer lateral surface of said housing.

7. A heat transfer device according to claim 6 wherein said means defining said reservoir includes a removable cap member having a vapor exhaust port therein.

8. A heat transfer device according to claim 6 wherein said housing is bent in the region where it enters said working fluid reservoir.

9. A heat transfer device according to claim 6 and further including an essentially U-shaped vent tube having one end extending into said housing via said open end, and an essentially L-shaped exhaust tube in vapor communication with the other end of said vent tube and extending externally of said means defining said reservoir.

10. A heat transfer device comprising:

an elongated housing having an open end and a closed end;

a probe member of high thermal conductivity mounted at said closed end of said housing and extending therefrom;

capillary means longitudinally disposed within said housing for conveying a volatile working fluid liquid from the vicinity of said open end to the vicinity of said closed end of said housing;

means defining a working fluid reservoir disposed about said open end of said housing in fluid communication with said capillary means for containing volatile working fluid liquid; and

thermal insulating means disposed about some of the outer surface of said reservoir means and some of the outer lateral surface of said housing for thermally insulating those surfaces.

11. A heat transfer device for performing cryosurgery by freezing comprising:

an elongated tubular housing having an open end and a closed end;

a tapered probe member of high thermal conductivity mounted at said "closed end of said housing with its portion of greatest cross-section adjacent to said closed end;

capillary means longitudinally disposed along said housing for conveying a volatile working fluid liq uid from the vicinity of said open end to the vicinity of said closed end of said housing;

means disposed about said housing in the vicinity of said open end for defining a working fluid liquid reservoir, said housing having a plurality of circumferentially spaced apertures in its lateral surface for receiving cryogenic liquid and transporting cryogenic liquid along said capillary means;

probe means connected to said capillary means to deliver heat to said cryogenic liquid working fluid to boil said fluid into a gas whereby said probe means is cooled; and

vapor conduit means for conducting cryogen gas away from said probe means.

13. The heat transfer device ofclaim 12 wherein said capillary means and said cryogen gas conduit means are housed in the same housing.

Claims (13)

1. A heat transfer device comprising: an elongated housing of low thermal conductivity having an open end and a closed end; a probe member of high thermal conductivity mounted at said closed end of said housing and extending therefrom; capillary wick means longitudinally disposed within said housing for conveying a volatile working fluid from the vicinity of said open end to the vicinity of said closed end of said housing; means defining a working fluid reservoir disposed about said open end of said housing in fluid communication with said capillary wick means; and thermally insulating means disposed about the outer surface of said reservoir means and a substantial portion of the outer lateral surface of said housing.

2. A heat transfer device according to claim 1 and further including means for providing a vapor exhaust path from said reservoir.

3. A heat transfer device according to claim 2 wherein said means defining said reservoir includes a removable cap member having a vapor exhaust port therein.

4. A heat transfer device according to claim 1 wherein said means defining said reservoir includes first and second detachable members, and means for forming a hermetic seal between said first and second members when in attached relationship.

5. A heat transfer device according to claim 1 wherein said thermally insulating means includes a shell member disposed about and spaced from said housing and a portion of said reservoir means and hermetically bonded thereto, the space between said shell member and said housing and said reservoir portion being evacuated.

6. A heat transfer device for performing cryosurgery by freezing comprising: an elongated tubular housing of low thermal conductivity having an open end and a closed end; a tapered probe member of high thermal conductivity mounted at said closed end of said housing with its portion of greatest cross-section adjacent to said closed end; capillary wick means longitudinally disposed along the inner lateral surface of said housing for conveying a volatile working fluid from the vicinity of said open end to the vicinity of said closed end of said housing; means coaxially disposed about said housing in the vicinity of said open end for defining a working fluid reservoir, said housing defining a plurality of circumferentially spaced apertures in its lateral surface near said open end to provide fluid communication between said reservoir and said capillary wick means; means for providing a vapor exhaust path from said reservoir; and thermally insulating means disposed about the outer surface of said reservoir means and a substantial portion of the outer lateral surface of said housing.

7. A heat transfer device according to claim 6 wherein said means defining said reservoir includes a removable cap member having a vapor exhaust port therein.

8. A heat transfer device according to claim 6 wherein said housing is bent in the region where it enters said working fluid reservoir.

9. A heat transfer device according to claim 6 and further including an essentially U-shaped vent tube having one end extending into said housing via said open end, and an essentially L-shaped exhaust tube in vapor communication with the other end of said vent tube and extending externally of said means defining saiD reservoir.

10. A heat transfer device comprising: an elongated housing having an open end and a closed end; a probe member of high thermal conductivity mounted at said closed end of said housing and extending therefrom; capillary means longitudinally disposed within said housing for conveying a volatile working fluid liquid from the vicinity of said open end to the vicinity of said closed end of said housing; means defining a working fluid reservoir disposed about said open end of said housing in fluid communication with said capillary means for containing volatile working fluid liquid; and thermal insulating means disposed about some of the outer surface of said reservoir means and some of the outer lateral surface of said housing for thermally insulating those surfaces.

11. A heat transfer device for performing cryosurgery by freezing comprising: an elongated tubular housing having an open end and a closed end; a tapered probe member of high thermal conductivity mounted at said closed end of said housing with its portion of greatest cross-section adjacent to said closed end; capillary means longitudinally disposed along said housing for conveying a volatile working fluid liquid from the vicinity of said open end to the vicinity of said closed end of said housing; means disposed about said housing in the vicinity of said open end for defining a working fluid liquid reservoir, said housing having a plurality of circumferentially spaced apertures in its lateral surface near said open end to provide liquid working fluid communication between said reservoir and said capillary means; means for providing a working fluid vapor exhaust path from the vicinity of said closed end of said housing; and thermal insulating means disposed about a portion of the outer surface of said reservoir means and a portion of the outer lateral surface of said housing.

12. A heat transfer device comprising: reservoir means for the containment of a cryogenic liquid working fluid; capillary means connected to said reservoir means for receiving cryogenic liquid and transporting cryogenic liquid along said capillary means; probe means connected to said capillary means to deliver heat to said cryogenic liquid working fluid to boil said fluid into a gas whereby said probe means is cooled; and vapor conduit means for conducting cryogen gas away from said probe means.

13. The heat transfer device of claim 12 wherein said capillary means and said cryogen gas conduit means are housed in the same housing.

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