SU1437012A1 - Cryoinstrument - Google Patents

Abstract

The invention relates to a medical technique for freezing pathologically changed areas of biological tissue in various fields of medicine, in particular in dentistry for diseases of the parodontium and the oral mucosa. The purpose of the invention is to increase the rate of cryo-action due to the rational organization of heat exchange within the working part of the cryo-tool, which makes it possible to reduce the treatment time for a number of diseases. The cryotool contains a sleeve; located on the coolant supply pipe and connected to the heater, on the cylindrical surface of which radial through holes are made. The presence of the bushing on the coolant supply tube allows to obtain a stagnant zone along the tube, in which the heat transfer coefficients are lowered and which itself is a good insulator that absorbs the heat load from the spent refrigerant flow through the radial holes of the heater. 1 il.

Description

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The invention relates to medical technology and can be used for cryo-effects on pathological biological tissue in dentistry, dermatology and other areas of medicine where a cryogenic method of treatment can be used.

The purpose of the invention is to increase the rate of cryotherapy.

The drawing shows a cryogenic, longitudinal section.

In a particular embodiment, the cryoinstrument is included in the cryosurgical unit of a closed cycle and is connected to the compressor of the unit (not shown) by the supply pipe 1 and the discharge pipe 2 by the flexible pipes. The cryoinstrument contains a heat-insulated body 3, in which heat exchanger 4 is sequentially placed with cavities of high 5 and low 6 pressure, a throttle device of saddle 7 type - ball 8, whose inlet is connected to a high pressure cavity 5, coolant supply pipe 9, one end of which is connected to the output of the throttle device 7, 8, and the second end enters the cavity of the base working tip 10 connected by means of a thread with a heater 11 located on the coolant supply pipe 9, a temperature sensor 12 attached to the end face the working surface of the base of the tip 10, for example, brazing, sleeve 13, fixed by means of solder to the feed tube 9 and the refrigerant thread connected with the heater 11.

Temperature control can also be carried out by a control thermocouple connected to the interchangeable tip or by needle thermocouples inserted into the biological tissue.

On the cylindrical surface of the heater 11, at the junction with its tip 10, radial through holes 14 are made, the diameter and the number of which is determined by the conditions of permissible hydraulics along the reverse flow of the cryoinstrument.

In the described construction, the heater 1 1 is made in the form of a roller with a cylindrical surface on which oxide insulation 5 μm thick is applied, on top of which are wound coils of nichrome alloy that are thermally insulated with a layer of glue on top. Case 3 is made of thin-walled stainless steel shells. A vacuum of 10 mm Hg is used as the heat insulation of the body. Art. As the temperature sensor 12 used copper - constantan thermocouple. The installation also includes a control unit and a set of replaceable working tips (not shown).

Cryoinstrument works as follows.

In the preparatory. Period compressed gaseous refrigerant at a pressure of 1.2 -

1.5 MPa enters the supply line 1 from the compressor of the installation into the high-pressure cavity 5 of the heat exchanger 4, where the sub-hum; It is returned by a low-pressure gas stream, and then to the throttle device 7, 8, where throttling occurs, resulting in a vapor-liquid mixture with a temperature of (-165) - (- 170) ° C. Thereafter, the vapor-liquid mixture through the supply tube 9 enters the cavity of the basic working tip 10, where, partially evaporated, it returns along the short portion of the coolant supply tube, fills the dead-end annular cavity 15 formed by the sleeve 13 and the inner surface of the heater 11, and is directed through the channel formed by the through holes 14 of the heater 11 in the radial direction, and further between the outer surface of the heater 11 and 0, the inner surface of the housing 3 in the low pressure cavity b of the heat exchanger 4, where it cools the high pressure gas and, having evaporated, returns via the outlet pipe 2 to the installation compressor. After 5–20 min, the preparatory period ends and the tip temperature reaches the required value (the forward flow is indicated by arrows).

During the working period, the working basic tip 10 of the cryo-tool or the replaceable working tip connected with it is brought into contact with the surface of the pathological tissue, after which the cryoinfluence with an exposure of 32-42 s is determined, which is determined by the degree of pathology and its localization. If it is impossible to loose the tip from the biological tissue, it is warmed to 0 ° C, after which the tip is torn away from the surface of the biological tissue and removed from the operating area.

Claims (1)

The invention of Cryoinstrumeite, connected to the compressor by flexible supply and discharge pipes, contains a heat-insulated casing, inside of which a heat exchanger with high and low pressure cavities is placed, the throttle device, the inlet of which is connected to the high-pressure cavity, coolant tube , one end of which is connected to the outlet of the throttle device, and the other end enters the cavity of the working tip connected to the heater, has a cylindrical shape and is located on the pipes e supplying refrigerant, characterized in that, in order to increase kriovozdejstvie speed, it is provided with a sleeve mounted on the coolant supply pipe and its outer surface ccHrAiiiivKiCoii,: the inner surface of the heater, wherein the heater has radial through-holes. 0 five // J8 3 I II t 12 k / 4UVAVXJJ ITO; AND / TLA AC C ) : -L // J i, (:; - ij: /: X , nfTniTfXfxxTcat / X L / -, / 3 77 16 J5