RU46426U1 - Cryo Sprayer - Google Patents

Abstract

The proposed utility model relates to the field of medicine, namely to cryogenic technology and can be used for local cooling of biological tissue. The cryo-atomizer increases the efficiency of the device due to a more uniform and high-quality, the formation of fine aerosol refrigerant. For this, the Cryo-atomizer contains a container for a refrigerant with a sealing cap, in the inner cavity of which there is a heat exchange chamber made in the form of a thin-walled sleeve made of heat-conducting material, soldered to the walls of the sealing cap. The open end of the sleeve is made of non-conductive material and expanded with the possibility of tight connection with a cone-shaped plug and an elastic tube coaxially inserted into it with a source of pressure rise. The elastic tube is equipped with a branch pipe with a valve. A screw is placed in the cavity of the thin-walled sleeve, in the middle part of the sleeve, behind the screw there is an air supply tube directed inside the tank for the refrigerant. on the opposite part of the sleeve (it can be filled with a heat-consuming, heat-conducting metal) there is a L-shaped part of the refrigerant supply channel. The L-shaped part of the coolant supply channel is made of heat-conducting metal and has a longitudinal knurling forming the inner ribs of the L-shaped part of the channel. The open tip is attached to the L-shaped part of the feed channel by means of a hose equipped with an electrically conductive spiral wound on its outer surface and connected to a portable power source. The open tip is a cylindrical tube passing into the nozzle in its distal part, a screw is rigidly mounted in the nozzle, the nozzle is equipped with a removable nozzle made of non-conductive material in the form of a cylinder with windows. The open tip can be made L-shaped, telescopic or elastic and flexible.

Description

The proposed utility model relates to the field of medicine, namely to cryogenic technology and can be used for local cooling of biological tissue.

Currently, I have two methods of cryotherapy on biological tissue - cryoapplication and cryo-spraying. An effective method of cryoapplication is cryoapplication with adhesion. However, with the adhesion of the applicator to the chilled tissue, it is not possible to quickly separate the instrument from the tissue. As a result, it is impossible to quickly stop and accurately dose the freezing depth of the tissue. Cryo-spraying does not have this drawback.

Known cryo spray containing a thermally insulated container associated with the supply line of the refrigerant, on which the spray nozzle is mounted. The cryo-atomizer also contains an evaporation chamber (USSR A. S. No. 1572573, IPC A 61 B 17/36, publ. In Bul. 23.06.90, No. 23). The evaporation chamber is located on the spray nozzle and is made in the form of two cavities. One cavity is thermally insulated and covers the channel of the spray nozzle. The second cavity is not thermally insulated. The inner channel of the spray nozzle has a partition, on both sides of which, in the vertical wall of the channel, opposed holes are made connecting the inner channel with the evaporation chamber. In this case, the spray nozzle, together with the evaporation chamber, can rotate 180 ° around its axis. The position of the evaporation chamber relative to the longitudinal axis of the evaporation nozzle is dictated by the need to perform atomization with a liquid or gaseous refrigerant. If cryotherapy is necessary to carry out a gaseous refrigerant spray nozzle with an evaporation chamber, connect to the refrigerant supply line so that the insulated cavity of the evaporation chamber and the hole in the inner channel of the spray nozzle are located below the longitudinal axis of the spray nozzle. All this construction occupies a mirror position if work with a liquid refrigerant is ahead.

According to the authors of the utility model, the device is reliable.

However, the disadvantages of the known device include the fact that the evaporation chamber is bulky and inconvenient in operation. The device cannot be used for

cryodestruction on internal organs or cavities. As noted by the authors of another cryo-atomizer (AS No. 1694123) during gasification of a liquid refrigerant, especially during the start-up period, when there is a large temperature difference between the refrigerant and the material of the evaporation chamber, the jet of liquid refrigerant striking the bottom of the evaporation chamber is not completely gasified with drops liquid refrigerant leaves the spray nozzle, while increasing its flow rate and uneven cooling of the fabric. This disadvantage also occurs when working with a liquid refrigerant, when in the initial period of operation the liquid refrigerant is partially gasified due to contact with the walls of a non-heat-insulated vessel.

The authors of this criticism created their own version of a cryo-atomizer (see USSR, A.S. No. 1694123, IPC A 61 B 17/36, publ. In bulletin No. 44 dated November 30, 1991). In this embodiment, the non-insulated cavity of the evaporation chamber comprises a jetting vessel, hydraulically connected to both chamber cavities through openings in its bottoms and to the opening of the spray nozzle channel by means of a tube. A spool of heat-insulating material is located inside the vessel, provided with through vertical holes and a protrusion from the side of the insulated cavity and installed with the possibility of axial movement and overlapping of the hole in the bottom of the vessel. The authors of the well-known cryo-nebulizer note that, thanks to the spraying vessel and ribs additionally installed in the evaporation chamber, in the section of liquid nitrogen movement from the reservoir to the spray nozzle, the flow rate is successively reduced in the spraying vessel due to expansion of the refrigerant in it, and its highly efficient gasification during subsequent passage in the gap between the ribs, the location of which provides a complete gasification of the refrigerant entering the cryogenic object, which is smart creases its flow and ensures a uniform cooling of biological tissue.

However, according to the authors of the proposed device, the bulkiness and inconvenience in the work remained the negative sides of the known device.

Known cryo-atomizer containing a container for a refrigerant, an associated coolant supply channel and an open tip (USSR, AS No. 1602488, IPC A 61 B 17/36, publ. No. 40 from 10.30.90). The tool contains a housing rigidly interconnected, a heat exchanger and an open tip with windows located on its lateral surface. The cryo-atomizer also contains an air dispenser made in the form of a cylinder placed coaxially to the housing and mounted on

tip with the ability to change the cross section of the window. The refrigerant supply pipe is connected to a heat exchanger, at the outlet of which an ejector is installed. Separation plates made in the form of truncated asymmetric cones are fixed inside the tip. The known device is aimed at preventing trauma to biological tissue by obtaining a gas jet of a cryogen that does not contain drops.

However, the known cryo-atomizer has the following disadvantages. The operation of the heat exchanger and separation trays is only effective for a short time from the start of operation. During operation, the casing and the heat exchanger are quickly cooled with a coolant and the preliminary boiling of the refrigerant stops. Separation plates are also quickly cooled and coolant drops merge onto them into larger ones. The operation of the device is possible only portionwise for a very short time.

The objective of the proposed utility model is to increase the efficiency of the device due to a more uniform and high-quality, that is, fine-dispersed formation of a coolant aerosol.

The problem is solved in that in the known cryo-atomizer containing a refrigerant container, a refrigerant supply channel connected to it and an open tip, the refrigerant container has a sealing cap, in the inner cavity of which a heat exchange chamber is made rigidly made in the form of a thin-walled sleeve of heat-conducting material, the open end of the sleeve is made of a non-conductive material and expanded with the possibility of tight connection with a conical plug and an elastic tube coaxially inserted into it a cabin with a source of pressure rise, the elastic tube is equipped with a branch pipe with a valve, a screw is placed in the cavity of the thin-walled sleeve, rigidly connected to the walls of the sleeve, axial cut is made in the lower part of the screw, in the middle of the sleeve, there is an air supply tube directed inside the tank for refrigerant, in the opposite part of the sleeve there is a L-shaped part of the coolant supply channel, which is made of heat-conducting metal and has a longitudinal knurling forming the inner ribs of the L-shaped part of the channel, the L-shaped part of the feed channel at the points of its passage through the sleeve is soldered to the walls of the sleeve, the open tip is attached to the L-shaped part of the feed channel by means of a hose equipped with an electrically conductive spiral wound on its outer surface and connected to a portable power source, open the tip is a cylindrical tube passing into the nozzle in

its distal part, a screw is rigidly mounted in the nozzle, the nozzle is equipped with a removable nozzle made of non-heat-conducting material in the form of a cylinder with windows. The part of the sleeve in which the L-shaped part of the refrigerant supply channel is located is filled with heat-resistant heat-conducting material, for example, lead. The open tip is made L-shaped, telescopic or elastic ..

The proposed utility model meets the criteria of “novelty” and “industrial applicability”, since the conducted patent information research did not reveal the sources of scientific, technical and patent literature discrediting the novelty of the proposed device.

The proposed utility model allows using the following positive effect. The presence of a screw in the heat exchange chamber, the execution of the L-shaped part of the coolant supply channel from heat-conducting material, the presence of fins on the inner walls of the L-shaped part of the coolant supply channel, the presence of a heat accumulator in the sleeve part, the presence of thermal contact between the L-shaped part of the supply channel, heat accumulator, with a sleeve and a sealing cap, it is possible to break the flow of the refrigerant into small drops. The presence of a screw in the nozzle allows you to turn small droplets of the refrigerant into a fine aerosol. Therefore, cryoirrigation is performed more efficiently and safely, which improves the quality of cryodestruction.

The proposed utility model is illustrated by graphic materials.

Figure 1 shows a General view of the cryo-atomizer.

Figure 2 shows the auger liner.

Figure 3 shows an open tip with a nozzle and auger.

Figure 4 shows an open tip with a nozzle.

5 shows the nozzle auger.

Figure 6 shows a hose with an electric spiral.

The proposed cryo-atomizer (figure 1) contains a container for a refrigerant 1 and a sealing cover 2. In the inner cavity of the sealing cover 2 there is a heat exchange chamber 3. The heat exchange chamber 3 is made in the form of a thin-walled sleeve of heat-conducting material and is soldered to the sealing cover. The open end 4 of the sleeve is made of non-conductive material and is expandable so that it can be sealed with a cone-shaped plug 5, in which the elastic tube 6 is coaxially placed. The open end of the sleeve 4, the cone-shaped tube 5 with the elastic tube 6 coaxially inserted into it, constitute a communication unit with a pressure lifting source 7. The elastic tube 6 is equipped with a nozzle

8 with a valve 9. In the cavity of the thin-walled sleeve 3 there is a screw 10, rigidly connected to the walls of the sleeve. In the lower part of the screw axial cut 11 is made (Fig.2). In the middle part of the sleeve (Fig. 1), behind the screw 10 there is an air supply tube 12 directed inside the tank for the refrigerant 1. On the opposite side of the sleeve there is a L-shaped part 13 of the refrigerant supply channel 14. The part of the sleeve in which the L-shaped part is placed the refrigerant supply channel may be filled with heat-sensitive heat-conducting material, for example, lead. The L-shaped part 13 is made of heat-conducting metal and has a longitudinal knurling 15 forming the inner ribs of the L-shaped part of the channel. In places of passage through the sleeve, the L-shaped part of the feed channel is soldered to its walls. The open tip 16 is attached to the L-shaped part 13 of the supply channel through a hose 17 (Fig.6), equipped with an electrically conductive spiral 18, wound on its outer surface and connected to a portable power source. The open tip 16 (FIG. 3) is a cylindrical tube 19, passing into the nozzle 20 in its distal part; the screw 21 is rigidly installed in the nozzle 20 (FIG. 4). The nozzle 20 (Fig. 5) is equipped with a removable nozzle 22 made of non-heat-conducting material in the form of a cylinder with windows 23. The open tip can be made L-shaped, for example, to perform cryotherapy on the laryngeal mucosa with indirect laryngoscopy, or telescopic, for example, for performing cryotherapy with direct broncho-esophagoscopy through the channel of the broncho-esophagoscope. The open tip can be made flexible and flexible, for example, for conducting through the natural channels of the body, or for passing through the channel of a flexible endoscope. The proposed device operates as follows. In the idle state, the pressure raising channel 7 is open to the atmosphere and there is no air pressure in the tank. Capacity 1 is filled into 2/3 with liquid nitrogen. At this point, the pressure in the tank rises due to cooling the walls of the tank for the refrigerant and liquid nitrogen boils and evaporates. Close the sealing cover 2 and snap locks. By cooling the non-conductive portion of the feed channel, liquid nitrogen boils again. The resulting refrigerant vapor exits through the heat exchange chamber 3, cooling it. The conical plug 5 hermetically seals the expanded part of the sleeve 4. The cone-shaped sealing plug acts as an emergency pressure relief valve: if it is excessively increased in the container, the plug slides in the expanded part of the sleeve along the axis of the pressure lifting channel, flies out of it and depressurizes the container, refrigerant supply to

open tip terminated. The source of pressure rise 7 is a foot pump. They begin to increase pressure and atmospheric air enters the cooled heat exchange chamber 3, passes through the screw 10 and is already cooled and enters the tank with the refrigerant 1 through the air supply tube 12. Since the sleeve has thermal contact with the sealing cap (it is soldered to it by highly heat-conducting metal) it acts as a radiator for supplying heat from the surrounding atmosphere and the supplied air from the source of pressure rise 7 to the L-shaped part 13 of the supply channel 14. Water vapor present in the atmospheric air settles on the walls Nek 10 in the form of dew or frost. The cleaned and cooled atmospheric air enters the tank for the refrigerant through the air supply pipe 12. Liquid nitrogen begins to flow into the L-shaped portion of the feed channel. This part of the channel is made of highly heat-resistant material, such as copper. In addition, this part of the sleeve is also filled with heat-sensitive and heat-transferring material, for example, lead, which serves as a heat accumulator. The implementation of the inner L-shaped part of the feed channel with the presence of longitudinal ribs 15 also improves heat transfer between the L-shaped part and the sleeve with a heat accumulator. Liquid nitrogen begins to boil with the formation of a vapor-liquid mixture of a refrigerant. As a result of this, there is a sharp increase in the volume and pressure of the refrigerant in this part of the channel. Further, from the L-shaped part of the refrigerant supply channel, the laminar flow of the resulting vapor-liquid mixture of the refrigerant under pressure is ejected at high speed into the lumen of the hose 17 or immediately open tip 16. The presence or absence of a hose depends on the cryogenic action. Flow runs along the entire length of the hose. Due to the fact that the refrigerant flow is laminar in nature and due to the large temperature gradient between the warm walls of the hose - tip and drops of the refrigerant, drops of the refrigerant do not stick to the inner walls of the hose. Drops and a vapor-liquid mixture of a refrigerant pass with high speed, slightly cooling the walls of the hose, as a result of which its plastic walls remain warm and elastic for a long time. For long and continuous operation while maintaining the elasticity of the hose, the hose is equipped with an external heating device, made in the form of an electrically conductive spiral 18 wound on the outer surface of the hose along its entire length (0.2 mm copper wire). The wire is connected to a low-voltage (up to 1.5 volts) autonomous power source. Next, the gas-liquid refrigerant reaches the open tip 16. The tip of the cryo-atomizer is made of plastic, made in the form of a thin cylindrical

tubes 19 from 5.0 to 30 cm long. and an outer diameter of 2 to 6 mm. with a narrowing in its distal part - nozzle 20 containing screw 21. The main function of this screw is to grind the existing drops of refrigerant and mix them with the vapor-liquid component of the mixture. Cooling of the inner wall of the tip occurs only in its distal part, in the area of the nozzle with a mixing screw. In order to avoid adhesion with subsequent possible traumatization and hypothermia of the tissues, the nozzle is equipped with an anti-adhesive nozzle 22 made in the form of a cylinder with windows 23, therefore freezing of the outer part of the open tip is excluded. The open tip is made of plastic and has several modifications: it can have a curved shape, for example, for cryotherapy on the mucous membrane or pathological tissues of the larynx, with indirect laryngoscopy, or other hard-to-reach areas. It can be made telescopic, for example, for cryotherapy with direct bronchoesophagoscopy through the channel of the bronchoesophagoscope. It can be made of more eoastic materials, for example, for conducting it through the natural channels of the body, or for conducting a flexible endoscope through the channel. During cryotherapy, steam or fog appears in the cavities, which interferes with the visualization of the cryotherapy zone. To eliminate this drawback and prevent possible trauma to biological tissue, the elastic tube of the pressure source is equipped with a pipe on which there is a valve. The valve is controlled by a button and opens the air channel into the hose with an open tip for blowing steam or mist from hollow organs.

An example of a specific performance is given in the form of an extract from a medical history

Example: A patient aged 3-63 complained on January 4, 2005 with complaints of a light colored spot appearing during the month on the mucous membrane of the inner surface of the left cheek. The diameter of the spot reaches 2.5 cm. A diagnosis of leukoplakia is suggested.

During the examination of the patient proposed immediate cryodestruction of the pathological focus. Consent for the operation is received. It was decided to carry out cryodestruction by the method of cryoirrigation.

Operation

Local aerosol anesthesia of 10% lidocaine was performed. For the convenience of the operation, a flexible plastic hose with a nozzle tip is installed on the cryo-atomizer. Due to the fact that the operation is performed in the oral cavity, an anti-adhesive nozzle is put on the tip. An autonomous power supply unit and a foot pump acting as a pressure boosting unit are connected. Trial produced

testing the apparatus for two minutes, during the test, by changing the supply voltage, the temperature of the hose was selected at which its flexibility remains sufficient for free manipulation of the tip. The test is over.

For a better view, put the tongue away from the midline with a spatula. The distal end of the handpiece is brought to krioraspylitelya pathological focus at a distance of about 5 mm ^and. Cryogenic irrigation of the outbreak was carried out for 10 ^and seconds with the exit of the freezing zone by 3-5 mm. on the unchanged mucous membrane of the cheek beyond the pathological focus. During krioorosheniya avoid cooling the mucosa of the upper airways and the occurrence of colds, the patient was asked to breathe through the nose, to remove moisture vapor interfering review at step used portioned purging three times during the entire period krioorosheniya 1 ^th second. For this purpose, the tip of the vapor blowing hose was held in parallel with the cryo-spray tip. Blowing was started by an assistant by briefly pressing the valve button. After cryoirrigation, a change in the color of the surface of the pathological focus and the frozen part of the mucous membrane was observed — an intensely white color. In the first 30 seconds after cryoirrigation, in the frozen area, frost was observed from the moisture vapor of the exhaled air. Natural defrosting frozen section was continued for 55 seconds ^and. After that, the initial color of the pathological focus and the frozen part of the healthy mucous membrane was restored. After 15 minutes when examining the oral cavity, redness of the mucous membrane in the cryogenic zone and slight swelling were noted. The patient practically did not feel pain. The patient was sent home with recommendations;

1. Do not use lip and hot food.

2. Daily attendance for examination, and monitoring the healing of the cheek mucosa. 01/05/05, When examining the oral cavity, gray fibrinous plaque is observed in the projection of the cryotherapy zone. There are no painful sensations. January 11, 2005, in the cryogenic zone, fibrinous deposits disappeared, and mild hyperemia of the mucosa remains. Recovered recovery.

Claims (5)

1. A cryo-atomizer containing a refrigerant container, a refrigerant supply channel connected thereto and an open tip, characterized in that the refrigerant container has a sealing cover, in the inner cavity of which there is a heat exchange chamber made in the form of a thin-walled sleeve of heat-conducting material, soldered to the walls sealing cap, the open end of the sleeve is made of non-conductive material and expanded with the possibility of tight connection with a cone-shaped stopper and el coaxially inserted into it a flexible tube with a source of pressure rise, the elastic tube is equipped with a branch pipe with a valve, a screw is placed in the cavity of a thin-walled sleeve, rigidly connected to the walls of the sleeve, an axial cut is made in the lower part of the screw, in the middle of the sleeve, an air supply tube directed inside the tank is located behind the screw for the refrigerant, on the opposite part of the liner there is a L-shaped part of the coolant supply channel, which is made of heat-conducting metal and has a longitudinal knurling forming internal ribs -shaped part of the channel, the L-shaped part of the feed channel in the places of its passage through the sleeve is soldered to the walls of the sleeve, the open tip is attached to the L-shaped part of the feed channel by means of a hose equipped with an electrically conductive spiral wound on its outer surface and connected to a portable power source , the open tip is a cylindrical tube passing into the nozzle in its distal part, the screw is rigidly mounted in the nozzle, the nozzle is equipped with a removable nozzle made of a non-conductive material Methods and material in the form of a cylinder with windows. 2. The cryo-atomizer according to claim 1, characterized in that the portion of the sleeve in which the L-shaped portion of the refrigerant supply channel is located is filled with heat-sensitive heat-conducting material, for example, lead. 3. The cryo-sprayer according to claim 1, characterized in that the open tip is made L-shaped. 4. The cryo-sprayer according to claim 1, characterized in that the open tip is made telescopic. 5. Cryo spray according to claim 1, characterized in that the open tip is made elastic.