SU1584919A1 - Cryogenic apparatus - Google Patents

Abstract

The invention relates to cryogenic medical technology and is intended for local cooling of biological objects. The aim of the invention is to simplify and improve ease of use. A second additional cavity 4 is connected to the cryosurgical apparatus, connected to the probe 14 by an additional coolant outlet channel 16 and connected to the atmosphere, while the first 3 and the second 4 contain additional cavities in the lower part of the aperture 5 and 6 with a valve 11, 13 for connection with the main cavity 2. The valve 11 is fixed on a pivotally mounted lever 9 with a float 12. The spool 18 is connected to the lever 9 and has the ability to open or close the refrigerant outlet ducts 15, 16 and the first communication channel 17 of the additional cavity 3 to the atmosphere. 2 Il.

Description

The invention relates to cryogenic medical technology and is intended for local cooling of biological objects.

The aim of the invention is to simplify and improve ease of use.

Fla FIG. 1 shows the scheme of the proposed cryosurgical apparatus using liquid refrigerant from the main cavity; in fig. 2 - the same, when using liquid refrigerant from the first vessel of the additional cavity.

The cryosurgical apparatus contains a thermally insulated refrigerant vessel 1 having a main 2 and a first additional 3 and a second additional 4 cavities. Additional cavities 3 and 4 contain openings 5 and 6 for the release of the refrigerant and a tube 7 for connecting the upper part of the first cavity 3 to the lower part of the main cavity 2. A support 8 is fixed to the bottom of the main cavity, to which the lever 9 is hingedly connected, containing valves 10 and 11 and the float 12. Hole 6 of the second extra cavity 4 is blocked by a valve 13. The upper parts of the additional cavities 3 and 4 are connected to the probe 14 by channels 15 and 16 of the coolant outlet, and to the atmosphere by the channel 17 of communication by means of a spool 18 connected to the lever 9. Intake tube 19, I have and a stop valve 20 through one of the channels 21 in the additional cavity 3, connects the lower part of the main cavity 2 to the probe 14. The second additional cavity 4 has a tube 22 permanently connected to the atmosphere. A charging valve is installed to charge the main container and then seal it. 23. To maintain a constant overpressure, a safety valve 24 serves.

Cryosurgical apparatus operates as follows.

After the main cavity 2 is filled with liquid refrigerant through the charging valve 23, the shut-off valve 20 is closed. When the charging valve 23 is closed, due to heat flow, the liquid refrigerant boils and the pressure in the main cavity 2 rises to the value regulated by the safety valve 24. Under the action of

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overpressure when opening the shut-off valve 20, the refrigerant flows from the main cavity 2 through the intake tube 19 to the probe 14, where it is partially evaporated due to the heat removed from the biopogical tissue. From the internal cavity of the probe 14, the refrigerant in the form of a vapor-liquid mixture enters through the outlet channel 15 through the opening in the spool 18 into the first additional cavity 3. Vapor separating from the liquid is discharged from the first additional cavity 3 through the channel 17 through the opening in the spool 18 to the atmosphere. As the first additional cavity 3 is filled with a non-evaporated liquid refrigerant, the level of the refrigerant in the main cavity decreases and when it becomes lower than the position of the float 12, it lowers and moves the lever 9 pivotally connected to the rack 8, which moves the spool 18 that overlaps the connection of the first additional cavity 3 the atmosphere and the probe 14. After the connection of the cavity 3 with the atmosphere and the coolant outlet channel 15 with the probe 14 overlap, further movement of the spool 18 together with the lowering float. 12 leads to the connection of the coolant outlet channel 16 with the second additional cavity 4 and to the simultaneous opening of the tube 7 and the opening 5 of the cavity 3, using valves 10 and 11 lowering with the float 12.

Thus, using a tube 7 in the upper first additional cavity 3, an overpressure equal to the excess pressure of the main cavity 2 is established and, due to the hydrostatic pressure of the fluid accumulated in cavity 3 through the open hole 5, it flows into the main cavity 2, thus ensuring a continuous process cryogenics (FIG. 2), i.e. the refrigerant continues to flow from the main cavity 2 through the intake pipe 19 to the probe 14, from where the vapor-liquid mixture of the refrigerant is discharged into the cavity 4 through the channel 16 and removed from the cavity 4 through the tube 22 to the atmosphere, and the liquid refrigerant fills the cavity 4. Float position 12 after the start of the expiration of the refrigerant from the additional cavity 3, it stabilizes, i.e. it does not fall and does not

rises as the amount of refrigerant coming from cavity 3 corresponds to the amount of refrigerant entering through the intake tube 19 into the cavity of probe 14. After the first additional cavity 3 is emptied, the cryoinfluence continues due to the refrigerant located in the main cavity below the float 12. At the same time, the coolant level, the float 12 descending to the bottom of the main cavity 2, using the lever 9 moves the valve 18, ensuring the connection of the additional cavity 3 and the main cavity 2 through the tubes 7 and the hole 5 with the atmosphere, cryostimulation is stopped, which is accompanied by an increase in the temperature of the probe 14 and the absence of outgoing vapors from the safety valve 24.

Due to the fact that the atmospheric pressure from the hydrostatic pressure of the liquid column in the cavity 4 opens in the main cavity 2 and in the second additional cavity 4, the valve 13 opens and the liquid refrigerant is discharged through the opening 6 into the lower part of the main cavity 2.

Claims (1)

To carry out a subsequent cryo-action, it is necessary to refill the main cavity of the instrument with a liquid refrigerant. Invention Formula A cryosurgical apparatus containing a thermally insulated vessel for 0 five 0 five 0 five refrigerant with charging and safety valves and divided into the main and first additional cavities, a probe with an inlet channel connected through a valve and a suction pipe to the main cavity, and with a discharge channel connected to the first additional cavity having an air channel , characterized in that, in order to simplify and improve ease of operation, a second additional cavity placed in the vessel, connected to the probe by an additional outlet channel and connected to the atmosphere, is introduced into it at the bottom As part of which a coolant outlet with a valve for connection with the main cavity is made, a tube connecting the lower part of the main cavity with the upper part of the first additional cavity, in which the coolant outlet hole is made into the main cavity, a hinged lever in the lower part of the main cavity a spool connected to the lever with the possibility of blocking the coolant outlet channels and the communication channel of the first additional cavity with the atmosphere, and valves fixed to the lever and having the possibility of contact ation to a lower end and an opening grubki refrigerant outlet of the first storage chamber. // 7 4L L L7 11 12 S3