SU1102096A1 - Cryogenic surgical apparatus - Google Patents

Abstract

t. A CRYOSURGICAL DEVICE, containing a cryo-instrument, including a heat exchanger, an electric heater and a temperature sensor, a refrigerant source connected to a cryo-instrument of a flexible main line and including solenoid valves for liquid and gaseous refrigerant, an evaporator, a pressure regulating valve, and a unit and a unit. temperature gauge of a cryotool, with a temperature setter, with a time relay and via a push-button switch with a temperature meter It is equipped with a series-connected comparator, a control unit for the liquid and gaseous refrigerant solenoid valves, and a refrigerant pressure regulator, in order to ensure a stable temperature of the cryotool during surgery on an organ abundantly supplied with blood or on large areas of organs and tissues. the inputs of the comparator are connected to the output of the thermostat and the output of the temperature setpoint; the outputs of the control unit are connected to the corresponding solenoid valve, first One of the pressure regulator is connected to the output of the thermostat, a second input with a pressure sensor, and the outputs with an evaporator and a pressure regulating valve. 2. The cryosurgical apparatus of claim 1, wherein the refrigerant pressure regulator is implemented as a pressure setter, the outputs of which are connected to the first inputs of the first threshold element and the second threshold element, the second inputs of which are connected to the output of the pressure sensor, the output of the first threshold element is connected to the valve. adjusting the pressure, the output of the second threshold element is connected to the isp (the Client, and the setpoint input is connected to the outlet of the thermostat. 3. The cryosurgical apparatus according to claim 1, in which the control unit is made in the form of the first key and the inverter and the second key connected in series, the inputs of the first switch and the inverter are connected to the output of the comparator, the output of the first switch is connected to the solenoid valve of the gaseous refrigerant, the output of the second switch is connected to the solenoid valve of the liquid cool agent, and the control inputs of the keys are connected to the source of the reference voltage. 4. The cryosurgical apparatus according to claim 2, characterized in that the pressure setter is designed as a bridge circuit, one diagonal of which is connected to the output of the reference voltage source, and the second is short-circuited , with the two arms of the bridge forming Potentiometers, under

Description

The movable electrodes of which are connected to the first and second threshold elements, the third arm forms a constant resistor, and the fourth is the key element, the control input of which is connected to the temperature regulator.

The invention relates to medical technology and can be used in cryosurgical operations. A device for cryogenic surgery is known, comprising a cryogenic device, including an electric heater and a temperature sensor, a coolant source connected to a cryogenic tool with a flexible main line and including liquid-gas and refrigerant gas cryo-tools, a pressure regulating valve and a pressure sensor, a thermostat, and a thermostat, and a heat controller, a pressure regulator, an evaporator, a pressure regulating valve and a pressure sensor, and a thermostat. connected directly to the temperature gauge of the cryotool, to the temperature setter, to the time relay and via a button switch with a meter temperature control. The well-known technical solution does not provide for maintaining the temperature of cryosurgery with an increase in the heat load on the cryotool, which is the case with an operation on organs. abundantly supplied with blood, for example, of the liver, pancreas (-), as well as during the freezing of large areas of organ and tissue. Since during the cryosurgery the heat load on the cryoinstrument depends on many factors - the degree of blood supply to the organ, the area of contact of the instrument with the tissue, temperature differences between the instrument surface and the tissue surface, it is necessary for the MO to adjust the cooling capacity not only downwards (this makes the heater cryo-tools), but also upwards, using more efficient cooling of the working part. This can be achieved by adjusting the pressure in the vessel with the refrigerant and, accordingly, the flow rate of the refrigerant agent, and the refrigerant flow should be minimal in the mode of stabilization of the temperature of the cryotool and maximal in the cooling mode. The aim of the invention is to provide a stable temperature of the tool when operating on organs that are abundantly supplied with blood, or on large areas of organs and tissues. This aim is provided in that the cryosurgical apparatus comprising cryoinstrument, comprising a heat exchanger, an electric heater and a temperature sensor, the coolant source connected to the flexible cryoinstruments gidromagistralsh and vklyuchakedy SEB in solenoid valves of liquid and gaseous refrigerant evaporator Adjustment of the pressure sensor and the valve pressure, thermostat, directly connected to the temperature gauge of the cryotool, to the temperature setting device, to the time relay and through the push button switch-screw with temperature measurement, there are series-connected comparator electromagnetic control unit. liquid and gaseous refrigerant valves and a refrigerant pressure regulator, the comparator inputs are connected to the thermostat outlet and the temperature setpoint outlet, and the control unit outputs are connected to the corresponding solenoid valve, the first pressure regulator input is connected to the thermostat output, the second input is connected to the sensor pressure and the outlets with an evaporator and pressure control valve. In addition, in the apparatus, the refrigerant pressure regulator is implemented as a pressure setter, the outputs of which are connected to the first inputs of the first threshold element and the second threshold element, the second inputs of which are connected to the output of the pressure sensor, the output of the first threshold element is connected to the pressure control valve, the output of the second the threshold element is connected to the evaporator, and the setpoint input is connected to the output of the thermostat. Another difference in the apparatus is that the control unit is made in the form of a first key and successively connected inverter and second key, with the inputs of the first key and inverter connected to the output of the comparator, the output of the first key connected to the solenoid valve of the refrigerant gas, the output of the second key is connected to the liquid refrigerant solenoid valve, and the control of the key inputs is connected to the source of the reference voltage, the pressure gauge is made in the form of a bridge circuit, one diagonal of which is connected to the output of the source of the reference voltage, and the other is short-circuited, with the two arms of the bridge forming potentiometers, the movable electrodes of which are connected to the first and second threshold elements, the third shoulder forms a constant pe3HCTOpj and the fourth is the key element, the control input of which is connected to the temperature regulator . Fig i 1 shows the device of the cryosurgical apparatus; in fig. 2 is a pressure setting circuit. The cryosurgical apparatus includes a cryosurgical instrument 1, including a heat exchanger 2 p sensor 3 temperatures and an electric heater 4. The heat exchanger is connected through the refrigerant supply line 5 and the liquid solenoid valves 6 and the gaseous 7 refrigerant to the refrigerant source 8. The device has the same temperature range and the temperature control device also has a temperature range. connected to the cryoinstrument temperature sensor 3, cryo-temperature temperature setting device 10, time relay 11, and the outputs to the electric heating tool 4 cryo-tool, pressure regulator 12 refrigerant a, unit 13 for controlling liquid and gas refrigerant valves, comparator 14 In addition, the refrigerant source 8 contains an evaporator 15, a pressure control valve 16, a pressure sensor 17, a temperature meter 18 connected through a contact (button) Kn with an operating temperature sensor 3 mode or setpoint temperature 10, during the installation of the temperature meter 19 liquid refrigerant level, mechanical safety valve 20. The heat exchanger 2 turns on the line 21 of the exhaust refrigerant to the atmosphere. The pressure regulator 12 includes a pressure setting unit 22, the input of which is connected to the output of the thermostat 9, the first output of the pressure setting unit 22 is connected to the first input of the first threshold element 23, and the second output of the supply element 22 is connected to the first input of the second threshold element 24, while the second the inputs of the first and second noporoBbix elements are connected to the pressure sensor 17, and the output of the first threshold element is connected to the inlet of the pressure control valve 16, the output of the second threshold element is connected to the inlet of the refrigerant 1.5 evaporator. The control unit 13 for the refrigerant and gaseous refrigerant valves includes an inverter .25 and a first switch 26, the inputs of which are connected to the output of the comparator 14, as well as a second switch 27, the input of which is connected to the output of the inverter 25, and the output connected to the input of the valve 6 for supplying liquid refrigerant, the output of the first switch 26 is connected to the inlet of the valve 7 for the supply of chla gas, the cagent, while the first 26 and second 27 switches are connected to the terminal of the voltage source E. The pressure setter 22 is a bridge circuit in the form of adjustable dividers Mi transition voltage. variable pe3HCTOFBB 28, 29, connected to the reference voltage E in series with the constant resistor 30. Parallel to the resistor 30 is connected a third switch 31, which is controlled by the current drop coming from the output of the temperature regulator 9. The device works as follows. Before the cryo-action process, depending on the nature of the operation, set: on the time relay 11 - the cryo-action time required, pressure setting unit 22, the working pressure in the refrigerant source 8 and temperature setpoint 10 by the meter 18 while pressing the Cc button - work temperature. Then, the pressure regulator 12 is put into pressure stabilization mode (preparation mode). With this, the solenoid valve 16 and the mechanical valve 20 are closed, and the evaporator 15 is turned on, the liquid refrigerant evaporates and the pressure in the refrigerant source rises. The pressure is stabilized by switching the evaporator 15 and the valve 16. When the signal of the pressure sensor 17 is increased relative to the signals of the pressure setting device 22, the threshold element 23 is activated and the valve 16 is turned on, the evaporator 15 is turned off, and when the signal of the sensor 17 decreases relative to the signals of the setting device 22, the threshold element 24 operates and turns on the evaporator 15, the valve 16 is turned off. The temperature controller 9 can be transferred to the cooling mode and stabilize the temperature of the cryotool 1. only after the pressure in the refrigerant source 8 is increased to the operating value. Depending on the set temperature, the cooling of the cryotool 1 is carried out by a gaseous or liquid refrigerant, which flows through the corresponding solenoid valve 7 or 6 from the refrigerant source 8 via line 5 to the heat exchanger 2, and then takes off as exhaust gas via line 21 to the atmosphere . The use of refrigerant of different aggregate state at different temperature levels & nx. cryo-aevests of stui provides steady stabilization of temperature of the cryotool in the range from O to minus with an accuracy of + 3 ° C. The connection, in the mode of cooling and stabilizing the temperature of the valve 7 or 6, to the voltage source E ", is made respectively by the keys 26 and 27 of the control unit 13. The key 26 is opened by the voltage drop, which comes from the output of the comparator 14 at a signal of the setpoint temperature regulator 10 at the input of the comparator, corresponding to the set operating temperature from 0 to minus. The key is .27. opens with a voltage perpendicular from the output of comparator 14 through: inverter 25 at a temperature setpoint signal corresponding to the set temperature from minus 70 to minus. In the process of temperature stabilization of cryoinstance 1, the temperature controller 9 controls the heater 4 by the solenoid valve 7 or 6 and the pressure setting device 22. The signal of temperature sensor 3, monitored by meter 18, is compared at the input of temperature controller 9 with the setpoint signal 10. If the signal of sensor 3 decreases relative to the signal of setpoint 10, which corresponds to a decrease in temperature of the cryoinstrument, the heater 4 is turned on, if it goes up - valve 7 or 6 turns on. In addition, depending on the temperature of the cryotool 1, the magnitudes of the signals at the first and second outputs of the pressure setting unit 22 change, which leads to a change in pressure at the source 8 of the refrigerant. Thus, at different temperatures of the cryotool, the refrigerant enters the heat exchanger 2 at an optimum pressure, and thus provides the necessary cooling capacity at a given temperature level. The cryogenic time is counted by the M time relay. At the end of the cryo-action, a signal comes from the time relay output, which puts the temperature controller 9 into the heating mode of the cryoinstrument 1. At that, the valve 7 and the heater 4 are turned on. The cryoinstrument is heated to the temperature by the heated gaseous refrigerant, which comes from the source 8 line 5 through the heater 4 to the heat exchanger 2. The cryosurgical apparatus is made in the form of a 1-meter-large rack, in which the source 8 of the refrigerant (cryoblock) is located, connected to a replaceable cryosurgery with a cool tool 1 flexible heat-insulated hose, and a control unit. An example of a specific implementation of the cryosurgical unit. The source 8 of the refrigerant (cryoblock) is made of stainless steel high vacuum thermal insulation. The cryoblock contains: a capacitance meter for liquid refrigerant level 19, an evaporator 15, an electric wire heater, filled on a dielectric frame, designed to create an overpressure of vapor in the cryoblock by converting liquid refrigerant into a gaseous, solenoid valves 6, 7, 16 They are actuators in the form of a valve device controlled by an electromagnetic actuator. As these valves can be used, for example, valve for US patent No. 4119296, No. 4220312, operating at cryogenic temperatures. The hose is made of a flexible corrugated metal hose, inside of which there are coaxially arranged pipes of the forward and reverse flow of refrigerants. Directly in the handle of the hose is a heater 4, designed to heat the gaseous refrigerant by passing it through an electric heater with a developed surface in order to warm the cryosurgical instrument and to regulate its temperature during cryogenic action. The heat exchanger of 2 replaceable cryosurgical instruments is made by powder metallurgy, which greatly improves the heat transfer processes on the frontier biological tissue - metal - chl adagent. The operation of the installation is controlled by the control panel, on the front panel of which there is a temperature gauge 18 of the working surface of the cryo-tool, the time setting unit 10 of the cryo-action, as well as control and display elements of the modes. t)

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Claims (4)

, 1. A CRYOSURGICAL APPARATUS containing a cryotool, including a heat exchanger, an electric heater, a temperature source, a refrigerant source connected to the cryotool with a flexible hydraulic line and including solenoid valves for liquid and gaseous refrigerant, an evaporator, a pressure control valve and a pressure sensor, a temperature sensor, directly with a cryotool temperature sensor, with a temperature setpoint, with a time relay and via a push-button switch with a temperature meter, about characterized in that, in order to ensure a stable temperature of the cryotool during surgery on an organ that is richly supplied with blood or in large areas of organs and tissues, it is equipped with serially connected comparator, a control unit for electromagnetic valves of liquid and gaseous refrigerant and a regulator of pressure of the refrigerant, and the inputs of the comparator are connected with the output of the thermostat and the output of the temperature setter, the outputs of the control unit are connected to the corresponding electromagnetic valve, the first input is the regulator PRESSURE Nia thermostat connected to the output, the second input to the pressure sensor, and outputs to the evaporator and the pressure control valve. 2. Cryosurgical apparatus according to p. 1, on the condition that the refrigerant pressure regulator is made in the form of a pressure regulator, the outputs of which are connected to the first inputs of the first threshold element and the second threshold element, the second inputs of which are connected to the sensor output pressure, the output of the first threshold element is connected to the valve. pressure control, the output of the second threshold element is connected to the evaporator, and the input of the setter is connected to the output of the thermostat, ¹ 3. Cryosurgical apparatus according to p. 1, characterized in that the control unit is made in the form of a first key and a series-connected inverter and second key, and the inputs of the first key and inverter are connected to the output of the comparator, the output of the first key is connected to the electromagnetic valve of the gaseous refrigerant, the output of the second key is connected to the electromagnetic liquid refrigerant valve, and the control inputs of the keys are connected to a voltage reference source. 4. The cryosurgical apparatus according to claim 2, characterized in that the pressure regulator is made in the form of a bridge circuit, one diagonal of which is connected to the output of the reference voltage source, and the second is short-circuited, with two bridge arms forming potentiometers, SU η. 1102096 whose mobile electrodes are connected to the first and second threshold element, the third arm forms a constant resistor, and the fourth is a key element whose control input is connected to the temperature controller.