RU108303U1 - GAS THERAPY UNIT, FOR example XENON - Google Patents

Abstract

 An inert gas therapy device, such as xenon, containing sources of compressed gases (xenon and oxygen) connected to a closed breathing circuit including a breathing gas chamber, an additional respiratory capacity, a column with a CO2 and H2O absorber, a gas analyzer with sensors for measuring the volume fractions of the gases used, an inhalation / exhalation line with a patient mask at its end and a shutter installed in front of the latter, characterized in that it is made in the form of a wheel stand with a height-adjustable table on which There is a breathing gas chamber in the form of a gas distribution unit with shut-off and control valves, a gas analyzer and a column with a CO2 and H2O absorber, moreover, the column is located between the additional gas tank and the gas distribution unit, and the gas distribution unit in size (in plan) corresponds to the dimensions of the gas analyzer and is located above it , and its shut-off and control valves are made in the form of spool and needle-type valves, connected to the outside of the gas analyzer sensors and located along it large sides, the table itself, height-adjustable with a collet clamp and a compression spring located inside the rack, contains, in turn, sockets for fixing the legs of the gas analyzer and a U-shaped rack with a device for quick removal and located on the edge along its smaller side installation of a gas distribution unit, made in the form of a trapezoidal plate rigidly mounted on a U-shaped rack, and its corresponding groove with shoulders on the rear side of the gas distribution unit; in addition, on the rack

Description

The xenon therapy device is intended for use in medicine and is a set of breathing equipment used during xenon anesthesia and therapy: for pain relief of surgical operations, painful manipulations and attacks (traumatic shock, myocardial infarction, angina attack, hepatic and renal colic, burn or skeletal trauma), for the treatment of acute and chronic pain syndromes, for the removal of pre-start fever in athletes, the treatment of insomnia, the improvement of performance, and same for the quick recovery of athletes after strenuous exercise.

Known xenon attachment for anesthesia apparatus, containing an adsorber connected to the gas mixture line from the respiratory circuit of the anesthesia apparatus, an gas analyzer and a cylinder with medical xenon and a gas reducer installed in series and connected by a pipeline, the xenon attachment is equipped with a xenon gas dosimeter, the input of which is connected to the xenon output from the gearbox, and the output is connected to the entry line of the binary narcotic gas mixture, consisting of xenon and oxygen, into the respiratory circuit arkoznogo apparatus dosimeter equipped with a measuring device, a metering valve mounted on the xenon entering the measuring device (Patent RU №36230 publ. 10.03.2004, the IPC A61M 16/01 ^7).

The main disadvantage of the above technical solution is the need for the presence of a complex anesthetic apparatus in the immediate vicinity of the xenon console, i.e. it is not autonomous, in addition, there are sufficient difficulties in transporting the entire anesthesia-therapeutic complex to the patient in the absence of anesthesia apparatus at the place of use, such as in clinics, during mountain rescue operations, in places of emergency and catastrophe.

The closest technical solution (prototype) is a device for inhalation with a gas mixture of xenon with oxygen, containing a gas supply unit connected to sources of compressed gases, a breathing circuit including a patient’s breathing mask, a gas analyzer, the breathing circuit being made closed in the form of a breathing gas chamber connected with a gas supply unit, with a patient’s breathing mask through the inspiratory / expiratory line, and with a gas analyzer, the sensor of which is located inside the respiratory gas chamber, in addition, the gas chamber contains inside itself a column with a CO ₂ and H ₂ O absorber and is equipped with at least one additional respiratory capacity, while the inspiratory / expiratory line is provided with a shutter for opening and closing the respiratory circuit (patent RU No. 59415 publ. 27.12. 2006 IPC A61M 15/02).

The disadvantage of the prototype is that the sensor of the gas analyzer is located inside the respiratory gas chamber, and the use of any other gas instead of xenon as the working gas will lead to the need to replace the respiratory gas chamber. This is due to the fact that the metering valve of the gas analyzer sensor when using gas of a different fluidity will have a different throughput, and since the sensor is located inside the gas chamber, it is impossible to replace the metering valve with another one without replacing the sensor, and therefore the respiratory gas chamber itself . Another disadvantage of the prototype is that the column with the CO ₂ and H ₂ O absorber is located inside the respiratory gas chamber, which, firstly, makes it difficult to control the saturation of the absorber with gases exhaled by the patient, and secondly, it makes it impossible to replace the column with the absorber without replacing the entire respiratory gas chamber; in addition, there is no specific design of the device - it is presented only schematically.

The task to which this technical solution is directed is to create the design of such a device, and when replacing the working gas (xenon) with any other gas, it would not require a complete replacement of the respiratory gas chamber.

To solve this problem, an inert gas therapy apparatus containing sources of compressed gases (xenon and oxygen) connected to a closed breathing circuit including a breathing gas chamber, an additional respiratory capacity, a gas analyzer with sensors for measuring the volume fractions of the gases used, an inhalation / exhalation line with a mask the patient at its end and the shutter installed in front of the latter is made in the form of a wheel stand with a height-adjustable table on which there is a breathing gas chamber in the form of a gas a distribution block with shut-off and control valves, a gas analyzer and a column with a CO ₂ and H ₂ O absorber, the column with a absorber located between the additional gas tank and the gas distribution block, and the gas distribution block in size (in plan) corresponds to the dimensions of the gas analyzer and is located above it, its shut-off and control valves are made in the form of spool and needle-type valves, which are connected to the outside of the gas analyzer sensors and are located along its large side ron.

The table for accommodating the gas chamber and the gas analyzer is height-adjustable with a collet clamp and a compression spring located inside the rack, and contains, in turn, slots for fixing the legs of the gas analyzer and, located on the edge along its smaller side, a U-shaped rack with a device for quick removal and installation of a gas distribution unit, made in the form of a trapezoidal plate rigidly mounted on a U-shaped rack, and its corresponding groove with shoulders on the rear side of the gas distribution unit.

In addition, on the rack there is a device for attaching small-capacity gas cylinders of the same or different capacity, made in the form of brackets with V-shaped lodgements - the upper one, rigidly mounted on the rack, and two lower ones, height-adjustable and fixed on it moreover, on the outer sides of the upper and lower brackets there are two-sided grooves for installing movable screw clamps in them with loop fasteners fastened to them, and on the adjacent sides of the lower brackets and in the center waiting for the upper lodgements, hook-and-loop fasteners are fastened to cover the lateral surfaces of gas cylinders, the free ends of which, together with hinged ribbons - hook and loop fasteners, are pressed to the side surfaces of the brackets; in addition, the apparatus contains a xenon capture cylinder (BEECH), the fastening of which is made in the form of a cup placed on the base of the apparatus stand, and an upper fixed bracket, in the two-sided grooves of which, with a screw clamp, a loop-fastened Velcro tape interacting with the hook tape is fixed Velcro, while the BUK is equipped with a device for cutting off the gas distribution unit from the external environment and the breathing circuit, made in the form of a cover with two one-way valves.

Figure 1 shows a General view of the apparatus for the treatment of inert gases.

Figure 2 shows the rack of the apparatus for inert gas therapy.

Figure 3 shows a diagram of a closed respiratory circuit of the apparatus.

The inert gas therapy apparatus contains sources of compressed gases 1 connected to a closed breathing circuit, including a breathing gas chamber in the form of a gas distribution unit 2 with shut-off and control valves made in the form of taps: needle 3 and slide 4, and the valve 3.1 is used for inlet of xenon and valve 3.2 is used for oxygen supply, valve 4.1 is used for emergency purging of the patient with oxygen (in case of emergency), and another 4.2 is used to let gas remaining after the end of the procedure into the BUK 5, except for t On the other hand, the BUK itself contains two one-way cranes, one of which works at the entrance, and the other at the exit, an additional breathing tank 6, a column 7 with a CO ₂ and H ₂ O absorber, a gas analyzer 8 with sensors for measuring the volume fractions of the used gases 9, an inhalation line / exhale 10 with the mask of the patient 11 and the shutter 12.

The rack 13 on the wheels 14 contains a table 15, height-adjustable with a collet clamp 16 and a compression spring (not shown), on which the gas analyzer 8 and the gas distribution unit 2 are located, which in size (in plan) corresponds to the dimensions of the gas analyzer 8 and is located above it, -regulating fittings are made in the form of valves: spool 4 and needle 3 types, which are connected together with the sensors of the gas analyzer 9 to it from the outside and are located along its large sides. The table 15 has a U-shaped rack 17, on which there is a device for quick removal and installation of the gas distribution unit - a trapezoid plate 18, rigidly mounted on the U-shaped rack 17, and on the back side of the gas distribution unit 2 there is a groove with shoulders corresponding to the trapezoid plate 18 ( not shown), in addition, the table 15 contains sockets 19 for fixing the legs of the gas analyzer.

In addition, on the rack 13 there is a device for mounting sources of compressed gases (gas cylinders), made in the form of brackets with V-shaped lodges 20 - upper 21, rigidly mounted on the rack 13 and lower 22, adjustable in height (depending on the length of the cylinders ) using a clamp with a screw 23. The upper bracket 21 and the lower brackets 22 on the outer sides 24 contain bilateral grooves 25 for mounting screw clamps 26 therein with hook and loop fasteners 27, and on the adjacent sides 28 of the lower brackets 22 and in the center 29 between lodgment The upper bracket 21 is secured with hook and loop fasteners 30 for covering the side surfaces of gas cylinders 1, the free ends of which, together with the loop fasteners, 27 of the screw clamps 26, are pressed against the side surfaces of the brackets 21 and 22.

In addition, the apparatus contains a xenon capture cylinder (BUC) 5, the fastening of which is made in the form of a cup 31, placed on the base of the rack 13 of the apparatus, and the upper fixed bracket 21, in the bilateral grooves 25 of which, with a screw clamp 26, a Velcro loop tape 27 is fixed interacting with the hook-and-loop fastener 30, while the BUK 5 is equipped with a shut-off device 32 of the gas distribution unit from the external environment and the breathing circuit, made in the form of a cover with two one-way valves - INPUT and EXIT.

The device operates as follows.

Open valves on cylinders 1 xenon and oxygen. The pressure regulators installed on the cylinders 1, set the lowest possible value of xenon pressure and oxygen. The closed gas circuit is filled with gas mixture with open taps 3 and closed ENTRANCE and EXIT taps on the BEECH cover 5 and shutter 12. The filling volume of the circuit is visually controlled by the degree of filling of the additional breathing tank 6. The composition of the mixture is monitored according to the readings of the gas analyzer 8.

The patient inhales deeply, then exhales air and holds his breath. At this moment, a mask 11 is applied to the patient, closing the nose and mouth, then the shutter 12 is opened next to the mask 11. The patient takes a deep breath with his nose and exhales with his mouth, after which he continues to breathe. Xenon and oxygen are consumed, which is displayed on the gas analyzer 8 and can be seen by the degree of filling of the additional respiratory capacity 6. At the end of the procedure, the duration of which is established by the medical method, the valves on cylinders 1 with xenon and oxygen are closed. The patient takes a deep breath and exhale completely, after which they close the shutter 12 next to the mask 11, remove the mask 11, the patient breathes air as usual.

Open the valve 4.2 on the gas distribution unit 2, the INPUT and EXIT valves on the BUK 5 in the shut-off device 32, the contents of the additional breathing tank 6 are manually squeezed into the gas distribution unit 2 and then into the BUK 5. The degree of release of the closed gas circuit 10 from the gas mixture is controlled by the sensors 9 of the gas analyzer 8.

Thus, the proposed technical solution due to the placement of gas metering taps outside the breathing gas chamber (gas distribution unit) makes it easy to reconfigure them if it is necessary to switch from one working gas to another, and placing the column with the CO ₂ and H ₂ O absorber also outside the breathing gas the camera makes it easy to control the degree of saturation of the absorber and, if necessary, replace it with a new one. The presence on the table for placement of the gas analyzer and the gas distribution unit of a U-shaped rack with a unit for quick removal and installation of the gas distribution unit in the form of a trapezoidal plate, and on the gas distribution unit the execution of the corresponding groove with shoulders allows you to easily and quickly remove and install the gas distribution unit, in addition, the presence in the table of nests for placing the gas analyzer also makes it easy and quick to remove and install the latter, and together both mechanisms allow safe to transport the machine. Attaching gas cylinders in the rack using fixed and movable brackets allows the use of cylinders of different capacities during therapy, and the use of hook and loop fastener tapes with screw clamps as a mechanism for fastening cylinders to the brackets allows you to securely and safely (unlike metal tapes) gas cylinders.

The inert gas therapy device is autonomous, easily transported, and indispensable for xenon anesthesia and therapy: for pain relief of surgical operations, painful manipulations and attacks (traumatic shock, myocardial infarction, angina attack, hepatic and renal colic, burn or skeletal injury), for treatment acute and chronic pain syndromes, to relieve pre-start fever in athletes, treat insomnia, improve performance, as well as to quickly restore athletes by le heavy physical exertion.

Claims (1)

An inert gas therapy device, such as xenon, containing sources of compressed gases (xenon and oxygen) connected to a closed breathing circuit including a breathing gas chamber, an additional breathing tank, a column with a CO ₂ and H ₂ O absorber, a gas analyzer with volume fraction measurement sensors the gases used, an inhalation / exhalation line with a patient mask at its end and a shutter installed in front of the latter, characterized in that it is made in the form of a wheel stand with a height-adjustable table on which the wife has a breathing gas chamber in the form of a gas distribution unit with shut-off and control valves, a gas analyzer and a column with a CO ₂ and H ₂ O absorber, the column being located between the additional gas tank and the gas distribution unit, and the gas distribution unit in size (in plan) corresponds to the dimensions of the gas analyzer and located above it, and its shut-off and control valves are made in the form of spool and needle-type valves, connected together with gas analyzer sensors to it outside and located along its large sides, the table itself, height-adjustable with a collet clamp and a compression spring located inside the rack, contains, in turn, slots for fixing the legs of the gas analyzer and a U-shaped rack with a device for quick removal located on the edge along its smaller side and installation of a gas distribution unit made in the form of a trapezoidal plate rigidly mounted on a U-shaped rack and its corresponding groove with shoulders on the rear side of the gas distribution unit; in addition, on the rack there is a device for attaching small-capacity gas cylinders of the same or different capacity, made in the form of brackets with V-shaped lodgements - the upper one, rigidly fixed to the rack, and two lower ones, height-adjustable and fixed on it moreover, on the outer sides of the upper and lower brackets there are two-sided grooves for installing movable screw clamps in them with loop fasteners fastened to them, and on the adjacent sides of the lower brackets and in the center Hook-and-loop Velcro tapes are fixed between the upper lodgements of the upper to cover the lateral surfaces of gas cylinders, the free ends of which, together with the loop-fastening Velcro tapes of screw clamps, are pressed to the lateral surfaces of the brackets; in addition, the apparatus contains a xenon capture cylinder (BEECH), the fastening of which is made in the form of a cup placed on the base of the apparatus stand, and an upper fixed bracket, in the two-sided grooves of which, with a screw clamp, a loop-and-loop fastener interacting with the hook tape is fixed Velcro, while the BUK is equipped with a device for shutting off the gas distribution unit from the external environment and the breathing circuit, made in the form of a cover with two one-way valves - inlet and outlet.