RU2670635C9 - Xenon concentration block and method of its operation - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine and can be used to concentrate spent medical xenon. Xenon concentrating unit contains vertical cylindrical body (1), upper housing cover (2), inlet (3) and outlet (4) nozzle. Inlet and outlet nozzles are located on the housing cover so that the inlet pipe is connected to tubular gas communication (5), which directs the flow of the incoming gas mixture to the bottom of the housing and distributes it evenly over the base. Outlet branch allows to exit the cleaned gas mixture through the housing cover. Internal volume of the shell is filled with granular and / or block-molded nanoporous carbon adsorbent by at least 80 % of the internal volume of xenon concentration block (6), with an average effective pore width from 0.6 nm to 1.2 nm, a nanopore volume of more than 0.4 cm³/g. Method of operation is that a safety valve is opened at the outlet pipe that is open during the gas discharge and closed during the idling time of the xenon concentration unit, spent breathing mixture containing not less than 10 % xenon is supplied to the xenon concentration unit. Gas line between the inhalation device and the xenon concentrating unit for gas discharge is made of materials that do not contain silicone, and comprises a non-reversible valve located near the outlet of the inhalation device for guiding the gas flow in the xenon concentration unit.

EFFECT: increase the efficiency of extraction of xenon from the spent respiratory mixture and simplify operation.

3 cl, 1 dwg

Description

The invention relates to medicine and can be used to concentrate spent medical xenon used in gas-narcotic mixtures used in anesthetic and inhalation therapeutic devices and released into the atmosphere after use.

The development of cryogenic and membrane technologies for producing inert gases and in particular xenon has largely determined the possibility of using this noble gas as an anesthetic and therapeutic agent. Xenon therapy can be used to treat pain and pain syndromes, stress therapy, treatment of depression, treatment of sleep disorders, treatment of addictions (drugs, alcohol), rehabilitation and recovery of the body after an illness, rehabilitation and recovery from debilitating mental and physical stress, to increase performance.

Xenon has a pronounced nootropic (improvement in mental activity), anxiolytic (anti-anxiety), antihypoxic, antidepressant and antioxidant effects, it is used in the treatment of chronic fatigue syndrome, stress and depression, neurosis, mild cognitive impairment; as part of complex therapy in patients with severe cardiovascular pathology (ischemic and hypertension, post-infarction condition, and so on), with neurological pathology (cerebrovascular disorders of atherosclerotic or ischemic nature); in intensive care; in complex therapy of various variants of withdrawal syndrome and post-withdrawal conditions in drug addicts; in rehabilitation medicine for rehabilitation after surgery, traumatic injuries. At the same time, xenon is non-toxic, devoid of side effects, does not cause carcinogenic, allergic and cardio-depressant effects, does not affect the composition and system of blood coagulation, immunity, is environmentally friendly and safe for the patient and surrounding personnel. At the same time, the most significant limitation for the use of xenon in medicine today is the small volume of its production, which is determined by the characteristics of its production. All this necessitates the search for new sources of raw materials for the production of medical xenon, as well as the search for ways to recover it for subsequent use. One of the most effective methods to increase the efficiency of xenon use in medicine is to concentrate it from the spent gas-narcotic mixture in special adsorbers for processing, purification and reuse. This method is called medical xenon recycling.

Several approaches are used in this area. One approach involves the cleaning of xenon "in place", that is, in medical institutions, and its reuse.

For example, RF patent 2049487 is known in which the used narcotic drug mixture is placed in pre-cooled and evacuated adsorbers. Then the impurities are removed by re-evacuating the adsorbers with simultaneous heating to xenon condensation temperature. Pure xenon is fed into a pre-chilled tank. To implement the method, a device is used that includes a regeneration line with tubular communications, a pressure sensor, means for changing the pressure, as well as a spent mixture tank, at least two adsorbers and a storage tank. Moreover, the latter are connected in parallel to the regeneration line by means of shut-off elements made in the form of vacuum valves. In this case, the storage tank is made in the form of a high pressure cylinder.

Also known is the patent of the Russian Federation 2149033, in which it is supposed to adsorb xenon from the collected spent gas-narcotic mixture of anesthetic devices, then carry out its desorption and fill the balloon. Xenon adsorption is carried out at a temperature from plus 25 to minus 80 ° C, and desorption is carried out at 180 ° C or more, after which regenerated xenon is disinfected. A stripper and a disinfection device are introduced into the installation containing a container for the exhaust gas mixture, adsorbers are installed with the ability to switch the supply of the exhaust gas mixture to them, the stripper is connected to the disinfection device and the cylinder through a cryopump, and the adsorbers and stripper are made in the form of heat-insulated cases with internal removable cartridges filled with sorbent. The method allows to obtain pure xenon for repeated use, provides milder conditions for the course of sorption processes, as well as the possibility of using desorption equipment for servicing several clinics.

The main drawback of such approaches is the complexity of such systems in operation and maintenance, which ordinary medical personnel cannot cope with, the need for special placement, since such systems, saturated in the number of units included in the device, must have relatively large dimensions, and the adsorber cooling systems and heating strippers must be equipped with specialized cryostats and thermostats that produce a large amount of heat, which makes them impossible to use in operating rooms x or therapy rooms.

In this regard, the most widespread are compact adsorbers, which can be located both in close proximity to anesthesia-respiratory or therapeutic equipment, and as part of therapeutic xenon complexes. Such adsorbers contain in a sealed enclosure a special adsorbent through which an exhaust gas mixture containing xenon is passed. After saturation of the adsorber, it is replaced with a new one, and the adsorber saturated with xenon is sent to a specialized xenon production, where it is isolated and purified. A description of such an adsorber is presented, for example, in RF patent 174585.

The closest in essence and the achieved result is the patent of the Russian Federation 2153638, in which the adsorber contains a cylindrical body, inlet and outlet pipes and a sleeve mounted coaxially in the inner cavity of the body with the formation of an annular space between the cylindrical walls of the sleeve and the body. The sleeve is equipped with a vertical partition dividing the inner cavity of the sleeve into two chambers. The use in the design of the adsorber of three sections sequentially arranged along the gas flow and filled with various types of adsorbent (annular space, first chamber and second chamber) allows for selective absorption ability with respect to various components of the gas mixture with high efficiency. The implementation of the inclined partitions allows you to evenly distribute the gas flow over the cross section of the chambers, which increases the efficiency of the adsorber. To increase the absorption capacity of the adsorbents used, an adsorber cooling system is provided. In addition, to increase the efficiency, the annular space can be filled with silica gel, the first chamber with NaX zeolite, and the second chamber with CaA or CaEX zeolite.

The main disadvantage of this invention is the difficulty of manufacturing this adsorber, its relatively high mass, which is determined not only by the housing, but also by an internal two-chamber sleeve, and the low efficiency of using the internal volume of the adsorber, since the volume decreases due to the presence of a large number of communications and partitions. available for backfill adsorbent.

Separately, the use of materials for capturing xenon should be noted. As a rule, the authors do not indicate any specific properties of adsorbents, noting only that they should have increased xenon sorption efficiency. However, this approach is not entirely correct.

In an adsorber, as a rule, a hyperoxic mixture of gases exhaled by a patient passes through a nanoporous adsorber. Therefore, the composition of the exhaled mixture, in addition to xenon, nitrogen and oxygen, contains a small amount of CO ₂ not absorbed by the carbon dioxide adsorber, and a significant amount of H ₂ O water vapor emitted by the patient and in the carbon dioxide collection unit CO ₂ . The presence of a significant amount of impurities, of course, reduces the adsorption of xenon, which in general, reduces the efficiency of the battery. Therefore, it is important that the adsorbent used is hydrophobic, and also does not contain specific adsorption centers, which primarily will have increased selectivity for carbon dioxide, nitrogen and oxygen, due to electrostatic interactions. Xenon, unlike carbon dioxide, nitrogen and oxygen does not have a dipole or quadrupole moment, making an additional contribution to the adsorption interaction. Therefore, the use, for example, of zeolites NaX, CaA or CaEX, will be ineffective, since these adsorbents have the property of hydrophilicity, and also have specific adsorption centers, on which carbon dioxide, rather than xenon, will predominantly be adsorbed. In addition, due to their structure, these adsorbents have a significant sorption of oxygen, and despite the fact that the sorption characteristics for xenon are significantly higher, due to concentration effects, oxygen will “wash out” xenon from the porous structure of these adsorbents, so that their use in therapeutic devices, where, as a rule, xenon concentration is carried out from a gas-narcotic mixture with oxygen XeO ₂ in concentrations of 15 to 85% by volume.

The problem to which the present invention is directed, is to increase the efficiency of the adsorber for the concentration of xenon.

The technical result of the claimed invention is to increase the efficiency of xenon extraction from spent respiratory mixtures, including from mixtures with a high oxygen content up to 90% after carrying out therapeutic procedures, as well as improving ease of use.

To solve the tasks in this utility model, a xenon concentration unit is used, comprising a vertical cylindrical body (1), a top housing cover (2), an inlet (3) and an outlet (4) nozzle, while the inlet and outlet nozzles are located on the housing cover so so that the inlet pipe is connected to the tubular gas communication (5), directing the flow of the incoming gas mixture to the bottom of the housing and distributing it evenly along the base, the outlet pipe allows the cleaned gas mixture to exit through the roofs cu, and the casing volume is not less than 80% filled with granular and / or block-formed nanoporous carbon adsorbent (6) with an average effective pore width of 0.6 nm to 1.2 nm and a nanopore volume of more than 0.4 cm ³ / g. The adsorbent is held by retaining rings containing holes for distributing the gas stream along the front of the adsorbent.

In FIG. 1 shows a xenon concentration unit. 1 - housing; 2 - top cover; 3 - inlet pipe; 4 - outlet pipe; 5 - tubular gas communication; 6 - adsorbent; 7 - retaining rings holding the adsorbent with holes for flow distribution.

This design of the adsorber has sufficient simplicity in manufacturing and operation, and in addition allows you to maximize the use of the internal volume of the adsorber, almost completely using it to fill the adsorbent.

The choice of a nanoporous carbon adsorbent as an adsorbent for xenon capture is caused, on the one hand, by their hydrophobicity, which allows one to avoid the displacement of xenon by adsorbed water vapor, and, on the other hand, by the absence of specific adsorption centers, which makes xenon sorption in nanopores significantly more energy-efficient compared to with sorption of nitrogen, oxygen and carbon dioxide, which determines the increased selectivity of such an adsorbent for xenon. At the same time, the parameters of the porous structure of the adsorbent for trapping xenon are important. In adsorbents with an average effective pore width from 0.6 nm to 1.2 nm, xenon will be sorbed most efficiently. The use of adsorbents with wider pores is not advantageous, since the xenon adsorption energy in them becomes sufficiently small so that xenon begins to be intensively displaced, for example, by oxygen from nanopores of the adsorbent. This will be especially noticeable when using the xenon concentration unit in therapeutic inhalation devices, where the oxygen concentration in the gas mixture is much higher than the xenon concentration. On the other hand, when using adsorbents with narrower pores, less than 0.6 nm, xenon adsorption will be difficult due to size factors (the diameter of the molecule becomes comparable in size to the pore width, and the adsorption of nitrogen and oxygen becomes the most energetically beneficial for the adsorbent.

An important parameter is the volume of nanopores of the adsorbent. When the nanopore volume is less than 0.4 cm ³ / g, the amount of concentrated xenon will be relatively small, so it is necessary to use adsorbents with a large volume. Moreover, the larger the volume of nanopores, the higher the xenon efficiency. The restriction on the maximum pore volume is determined only by the physical process of formation of the porous structure during the synthesis of the adsorbent. Since the pore width obtained in the synthesis of the adsorbent is usually inversely proportional to the volume of nanopores of the adsorbent. In this regard, when choosing an adsorbent for a block, it is necessary to select an adsorbent with optimal parameters of the effective width and volume of nanopores.

The adsorbent used in the xenon recovery unit must be granular and / or molded into blocks, and have a sufficiently high resistance to abrasion, i.e., reduced dust formation. The use of powdered or non-rigid granular adsorbents can lead to the formation of dust in the capture unit, which, when interacting with oxygen from the incoming gas mixture, can lead to an undesirable oxidation of the adsorbent, which may be externally manifested by additional heating of the capture unit or, in the extreme case, its ignition.

It is allowed to use the adsorbent in the form of molded monoblocks, for example, of cylindrical shape with a diameter equal to the diameter of the block casing, arranged in layers along the height of the casing. This form of adsorbent granules can significantly reduce the friction process of adjacent monoblocks and thereby reduce dust formation. Moreover, in order to reduce the effect of increased hydraulic resistance of such a system, it is necessary to ensure the presence of randomly located through holes in diameter of 0.5 mm or less in each of the blocks. In this case, the laying of blocks should not allow the formation of through channels along the height of the housing.

To increase the efficiency of xenon accumulation between the nanoporous carbon adsorbent and the outlet pipe of the xenon concentration unit, a layer of selective material can be located, which is a gas membrane or molecular sieve, usually a carbon adsorbent, an organometallic frame structure or zeolite, which due to the molecular sieve separation effect pass nitrogen and oxygen molecules and retain xenon molecules.

Since the xenon capture unit can also be used as part of inhaled therapeutic devices, its shape may be decisive in the layout of the elements of such inhalation devices. Since the main technological requirement for the capture units is their tightness, and there is no need to withstand high pressures, it is allowed to carry out this unit in any convenient form, subject to the tightness of the unit, for example, in the form of a parallelepiped.

The invention is illustrated by the following examples.

Example 1

A 10-liter hydraulic xenon recovery unit is equipped with 80% nanoporous carbon adsorbent from coconut coal, which consists of irregular-shaped granules with an average linear size of about 1 mm, with an average effective pore width of 1.2 nm and a nanopore volume of 0.61 cm ³ / g. The capture unit is used to capture xenon from the anesthesia apparatus, while the average concentration of xenon was 65% vol., Oxygen 25% vol., Nitrogen 10% vol. In this case, the amount of concentrated xenon after the block was fully worked out, which was recorded by the xenon slip sensor installed in the gas lines connected to the block outlet pipe, was 161.5 l (16 l Xe / l adsorbent).

Example 2

It differs from example 1 in that the xenon capture unit is equipped with 90% carbon adsorbent obtained by thermochemical synthesis of polymer decomposition. The adsorbent has the following structural and energy characteristics: the average effective nanopore width is 0.6 nm and the nanopore volume is 0.4 cm ³ / g. The capture unit is used to capture xenon from a therapeutic inhalation apparatus, while the average concentration of xenon was 10% vol., Oxygen 45% vol., Nitrogen 40% vol., With a slight content of 5% moisture and carbon dioxide. The amount of concentrated xenon was 97 L (9.7 L Xe / L adsorbent).

Example 3

Differs from example 1 in that the xenon capture unit between the nanoporous carbon adsorbent and the outlet of the unit contains a layer of carbon molecular sieve. The amount of concentrated xenon was 186 L (18.6 L Xe / L adsorbent).

The operation of the xenon capture units in the claimed examples was carried out in the following way. The inlet pipe is connected to the discharge pipe of an anesthetic or therapeutic inhalation device, the outlet pipe contains a safety valve open during gas discharge and closed during idle time of the xenon concentration unit, characterized in that the exhaust respiratory mixture with at least 10% content is supplied to the xenon concentration unit xenon, the gas line between the anesthetic or therapeutic inhalation device and the xenon concentration unit for gas discharge is made of materials containing silicone, and contains non-reversing valve is disposed near the outlet an inhalation anesthetic and the therapeutic apparatus.

The non-reversing valve ensures the direction of gas flows during operation of the xenon concentration unit, and prevents moisture and carbon dioxide from entering atmospheric air into the xenon concentration unit, and also prevents the desorption of xenon from the adsorbent.

The absence in the gas line between the anesthesia or therapeutic inhalation device and the xenon concentration unit of materials containing silicone, can significantly reduce xenon losses associated with the diffusion of xenon through the walls of the tubes and adapters of the gas line.

In some cases, the use of the xenon capture unit in therapeutic inhalation devices, the output pipe of the capture unit may contain an adjustable safety valve that can provide pressure increase in the unit by up to 60 mm water column, which, on the one hand, will not impede gas discharge from apparatus, and on the other hand, will increase the selectivity of xenon adsorption in comparison with other components of the gas mixture (oxygen and nitrogen).

Claims (3)

1. Block concentration of xenon from a gas-narcotic mixture of anesthesia and therapeutic inhalation apparatus, comprising a vertical cylindrical body, a top cover of the body and an inlet and outlet pipe, characterized in that the inlet and outlet pipes are located on the cover of the body so that the inlet pipe is connected to a tubular gas communication, directing the flow of the incoming gas mixture to the bottom of the housing and distributing it evenly along the base, the outlet pipe allows you to exit the cleaned gas cm If you are through the lid of the casing, and the internal volume of the casing is filled with a nanoporous carbon adsorbent granulated and / or molded into blocks with an average effective pore width of 0.6 nm to 1.2 nm, a nanopore volume of more than 0.4 cm ³ / g, the internal volume of the xenon concentration block is filled with nanoporous adsorbent not less than 80%. 2. The block according to claim 1, characterized in that between the nanoporous carbon adsorbent and the outlet pipe of the xenon concentration unit is a layer of selective material, which is a gas membrane or molecular sieve, which transmits nitrogen and oxygen molecules and traps xenon molecules. 3. The method of operation of the xenon concentration unit, in which the inlet pipe is connected to the discharge pipe of the anesthesia and therapeutic inhalation apparatus, the outlet pipe contains a safety valve open during gas discharge and closed during the shutdown of the xenon concentration unit, characterized in that in the xenon concentration unit the spent respiratory mixture with a content of not less than 10% xenon is supplied, the gas line between the anesthesia or therapeutic inhalation device and the conc The xenon center for venting gas is made of silicone-free materials and contains a non-reversing valve located near the outlet of the anesthetic and therapeutic inhalation apparatus.

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