RU2113860C1 - Device for cleaning and sterilizing endoscopes - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: device has unit for fixing endoscope designed as trough, means for discharging wasted solutions as overflow pipe, unit for supplying solution to external surfaces of endoscope being electromechanical stirrer mounted on trough bottom opposite to overflow pipe end, unit for supplying detergent and sterilizing means to internal surfaces of the endoscope designed as adapter. EFFECT: enhanced effectiveness of endoscope maintenance; absence of toxic ingredients. 6 cl, 2 dwg

Description

 The invention relates to medical equipment, in particular to devices for cleaning and sterilizing endoscopes, and can be used in medical institutions using endoscopes in the process of diagnosis and / or treatment.

 Currently, in medical institutions, the issue of cleaning and sterilizing a medical instrument is acute, which, due to the complexity of the design and high cost, cannot be used once. First of all, such instruments include endoscopes, widely used in diagnosis and treatment. The problem is that, firstly, endoscopes are complex instruments structurally made of various materials, which imposes restrictions on the choice of sterilizing agents, since it is necessary to avoid the destruction of these materials, and secondly, it is necessary to ensure processing in the assembly as external and internal surfaces of endoscopes and component equipment.

 A device is known for sterilizing endoscopes using sterilizing solutions, comprising a frame with a bathtub and a hydraulic system for supplying working solutions to the bath, the bath being installed with the possibility of oscillating movements in the longitudinal direction when the working solution is passed through the endoscope [1].

 However, the known installation is complex, energy and material intensive, and in addition does not provide the necessary degree of sterilization.

 A known installation that implements a multi-stage cleaning method using various chemicals and compositions for cleaning and disinfection of endoscopes, such as, for example, sequentially treating endoscopes in a bath with running water with the addition of detergent, draining the washing liquid, supplying disinfection liquid, followed by purging the endoscope channels and neutralizing sterile water passing through a sterile filter [2], moreover, the installation is equipped with controls that give each stage of the program a corresponding All signals, including acoustic or visual signals, instrument readings in the form of instructions or instructions, according to which the disinfection process is carried out manually.

 A disadvantage of the known installation is the complexity of its maintenance, the use of chemicals that impose increased safety requirements and require additional wastewater treatment.

 A known installation in which directly during operation prepare solutions for processing an endoscope, containing an ozonizer, a contact column, the lower part of which is connected to the tank for washing and disinfection, and the preparation of a disinfectant solution, namely ozonized water, is carried out automatically [3]. However, the installation is complex and energy-intensive, and does not ensure the achievement of a consistently high result.

 The closest in technical essence and the achieved result is an installation for cleaning and disinfection of endoscopes with liquid washing and sterilizing solutions, containing at least one device for fixing the endoscope, equipped with devices for supplying washing and sterilizing liquid solutions to the external and internal surfaces of the endoscope and a drainage device spent solutions, a feed line for the initial solution, a unit for preparing washing and sterilizing solutions containing at least one diaphragm elec a trochemical cell, with the initial solution being supplied to the cell’s anode chamber, the anode and cathode chambers are connected by overflow in series along the solution being treated, the outlet from the cathode chamber is connected to means for supplying washing-sterilizing solutions to the internal and external surfaces of the endoscope of the device for fixing it. The installation also contains a current source and a control unit connecting the electrodes of the electrochemical cell with the poles of the current source, sensors and control equipment connected to the control unit [4]. This installation is selected as a prototype. During the operation of the installation, significantly fewer reagents are used; it is easier to automate.

 A disadvantage of the known solution is its comparative complexity, the inability to ensure sterilization of the endoscope. In addition, the known solution provides for the circulation of the solution, which determines the sequence of passage of the solution of the electrode chambers, since it is necessary to subject the solution to a disinfection treatment, which leads to energy consumption and reduces the functionality of the installation. In addition, the prototype used membrane electrochemical cells with flat electrodes and turbulators placed near the surface of the electrodes, which also increases the energy consumption for the process by increasing the electrical and hydraulic resistance, as well as shielding the surface of the electrodes. Also, during sequential processing in the anode and then in the cathode chamber, the solutions have increased corrosion activity, which leads to the destruction of the metal parts of the endoscope. The known installation works with pre-prepared solutions, which requires the use of additional containers of significant volumes due to the high consumption of detergent-sterilizing solutions.

 The technical result of using the invention is to simplify the installation, enable sterilization of the endoscope, as well as enable full automation of the installation, eliminate destruction of the endoscope during processing, reduce the consumption of reagents and energy consumption for the cleaning and sterilization process.

 This result is achieved in that the installation for cleaning and sterilizing endoscopes with washing and sterilizing solutions contains a device for fixing the endoscope, made in the form of a tray, in which the device for draining the spent solutions is made in the form of an overflow nozzle, the device for supplying the solution to the external surfaces of the endoscope is made in in the form of an electromechanical mixer mounted on the bottom of the tray at the end opposite from the overflow pipe, a device for supplying washing and sterilizing solutions to the friction surface of the endoscope is designed as an adapter. The unit for preparing washing and sterilizing solutions from an initial solution of an oxidizing agent reagent containing sodium chloride includes at least one diaphragm electrochemical cell, which is made vertical, cylindrical with coaxial electrodes and a ceramic diaphragm that divides the interelectrode distance into the cathode and anode chambers with an entrance to the lower and the output in the upper parts, the device for supplying the initial solution is connected to the input of the cathode chamber of the cell, the overflow connects the output of the cathode cameras with anode input, and the output of the anode chamber is connected to the tray and the adapter. In this case, the installation contains a unit for preparing the initial solution, connected to the supply device and including a water supply line with a control filter, an electromagnetic valve, a fluid pressure regulator and a flow indicator, a vertical cylindrical coaxial electrolyzer with a ceramic coaxial diaphragm dividing the interelectrode space into the anode and cathode chamber with an entrance at the bottom and an exit at the top, a sealed flotator, fixture to saturate the water flow with air and a mixer connected to the vessel with the solution of the oxidant-forming reagent through a mechanical filter, a submersible type liquid pump, an adjustable choke and an indicator of the flow rate of the reagent solution, the tap water supply line connected to the entrance to the cathode chamber of the electrolyzer, the output of the cathode chamber connected to the input of the flotator and with the entrance to the anode chamber, the outlet of purified water from the flotator is connected to the mixer, and the output of the anode chamber of the electrolyzer and the output of the flotator sludge are connected with a drainage system for waste washing and sterilizing solutions, and a device for saturating the water flow with air is installed before entering the flotator. The vessel with the solution of the oxidant-forming reagent is equipped with a solution level sensor. The installation comprises a current source, a control unit connecting the electrodes of the electrochemical cell and the electrolyzer with the poles of the current source, sensors and control equipment, also connected to the control unit.

 The installation also additionally contains a container connected in series with a detergent solution and a mixer, the mixer being installed between the outlet of the cathode chamber of the cell of the washing-sterilizing solution preparation unit and the means for supplying this solution to the internal and external surfaces of the endoscope.

 In addition, the installation further comprises means for providing cathodic protection of the metal parts of the endoscope fixed in the tray, connected to the control unit and providing cathodic polarization of the metal parts of the endoscope. The counter electrode at their cathodic polarization is the axis of the electromechanical mixer, to which a positive potential is supplied.

 At the overflow connecting the cathode and anode chambers of the cell, a container with a catalyst can be installed with an entrance at the top and an exit at the bottom, with the entrance to the tank connected to the exit of the cathode chamber and the output of the vessel to the entrance of the anode chamber.

 The main units of the installation and auxiliary equipment can be mounted on a special trolley, and the installation is equipped with means to ensure the supply of tap water, electricity and the disposal of spent liquid funds.

 Installation for cleaning and sterilizing endoscopes allows you to get the whole range of solutions used for cleaning and sterilizing endoscopes on one unit of preparation of washing and sterilizing solutions from one initial reagent solution, for example sodium chloride or a mixture of chloride and sodium bicarbonate, by changing the parameters of the electrochemical process, s minimal additional input of reagents, which reduces the number of reagents used and fully automates the process.

 The proposed design of the tray with an overflow nozzle and a stirrer is simple to perform and maintain; when the endoscope is immersed in the tray, it can effectively clean the external and internal surfaces of the endoscope.

 The order of connecting the electrode chambers along the flow during the synthesis of washing and sterilizing solutions is essential. Due to sequential treatment in the cathode and anode chambers, substances accumulate in the solution, providing both a washing and a sterilizing effect, which is not possible with a different sequence of passage of chambers, since the active complexes formed in the anode chamber will be destroyed in the cathode chamber.

 In addition, it should be noted that during the sequence of passage of the chambers according to the invention, microbubbles of electrolytic hydrogen formed in the cathode chamber enter the anode chamber together with the solution, which makes it possible to use hydrogen as a reagent to increase the biocidal activity of the solution and at the same time to reduce its corrosion activity .

 Also, in the preparation of solutions after treatment in the cathode chamber, the purified water is fed into the chamber with a catalyst, for example, carbon - manganese dioxide, which allows you to further influence the properties of the resulting solutions.

 The installation includes a unit for preparing the initial solution of an oxidant-forming reagent, which, through the use of a diaphragm electrolyzer, the procedure for connecting the electrode chambers, and the use of a flotator, makes it possible to prepare the initial solution in tap water purified from heavy metal ions, as well as partially from hardness salts, which initiate the decay of highly active biocidal complexes synthesized in solution during its electrochemical processing. The content of sodium chloride in the solution is maintained at a level not exceeding 1 g / L. When using solutions with a higher concentration, the corrosion activity of solutions significantly increases, at lower concentrations, the biocidal activity decreases and the energy consumption for the preparation of solutions increases.

The flotator is made in the form of a sealed cylindrical container of constant cross-section with a tangential supply of treated water, located at a distance of 2/3 of the height of the flotator from its bottom and installed horizontally. The tangential input can be installed at an angle of 4-5 ^o to the horizontal section of the flotator and is directed upward. The flotator is equipped with a device for removing the treated water, made in the form of a vertical pipe mounted along the axis of the flotator with an entrance at the bottom of its bottom. In the upper part of the flotator, a device for removing slurry is installed.

 The form of execution of the flotator can be different, the only thing that matters is that it has a cylindrical shape, which ensures swirling of the flow of treated water in the flotator when it is tangentially introduced. The flotator itself can be made cylindrical with a constant cross section along its entire length, or cylindrical with a conical bottom, or conical and is set upward.

 The location of the tangential input is determined depending on the shape and performance of the flotator.

 The specified embodiment of the flotator provides an effective and, which is essential, short-term removal of flotation sludge from the treated water.

 The supply of the required amount of oxidant-forming reagent to the solution is carried out using easily automated means, which allows you to reliably maintain the concentration in the solution at a given level.

 In some cases, it becomes necessary to introduce a detergent, for example, sodium stearate, which reduces the corrosiveness of solutions and ensures the most complete wetting of all surfaces of the endoscope with solutions and ensures both the removal of harmful and contaminants and the supply of active complexes for disinfection and sterilization surface treatment.

 For the preparation of washing and sterilizing solutions and for the purification of tap water from heavy metal ions and hardness salts, the same electrochemical cells are used - vertical, cylindrical with coaxial electrodes and a coaxial ceramic diaphragm that separates the electrode gap to the cathode and anode chambers with an entrance to the bottom and exit to the upper parts, which allows to ensure the stability of the obtained characteristics of the washing-sterilizing solutions with minimal energy consumption, as well as achieving s desired degree of purification of the minimum time. Processing in the cells is carried out due to a single flow of the processed medium through the cells of the cell. Using the same type of cells allows you to unify the connections, to ensure the coupling of the hydraulic modes of the installation, which facilitates both operation and repair of the installation.

 Cells described in RF patent N 2042639 can be used.

 Providing the installation with means for providing cathodic protection of the metal parts of the endoscope connected to the control unit allows to completely eliminate the destruction of the metal parts of the endoscope during processing, since aqueous solutions are corrosive. Since in almost all endoscip designs, the metal parts are connected to each other, they can be polarized when the potential is applied at one point. The effectiveness of cathodic protection is ensured by the fact that the sterilizing solution has a very high dissipative ability (due to low mineralization), which ensures high uniformity of current density over the surface of the protected metal parts of the endoscope.

 The main components of the installation and auxiliary equipment can be mounted on a special trolley and the installation is equipped with means for supplying tap water, electricity and the disposal of spent liquid means, which facilitates the operation of the installation and expands its functionality, as it allows mobile processing of endoscopes directly at the place of use . Since the processing period of the endoscope at the installation according to the invention is relatively short - up to 20 minutes, the number of endoscopes used in one place can be reduced.

 In FIG. 1 shows an apparatus for cleaning and sterilizing endoscopes; in FIG. 2 is a general view of a machine mounted on a trolley.

 The installation comprises a tray 1 for fixing an endoscope in it, equipped with an electromechanical mixer 2 for supplying washing and sterilizing solutions to the external surfaces of the endoscope and an adapter 3 for supplying these solutions to the internal surfaces of the endoscope. Tray 1 also contains an overflow pipe 4 for draining the treated solutions into the drainage system 5. The overflow is designed in such a way as to ensure that the endoscope is completely immersed in the solution. The installation also contains a supply line of tap water 6, on which a control filter 7, an electromagnetic valve 8, a fluid pressure regulator 9 and a solution flow indicator 10 are sequentially installed. The line is connected to the cathode chamber of the electrolyzer 11.

 The output of the cathode chamber of the electrolyzer 11 is connected to the flotator 12. On the line connecting the cathode chamber and the entrance to the flotator 12, a mixer 13 is installed, connected to the air pump 14, to saturate the stream of water treated in the cathode chamber with air. The flotation sludge outlet from the flotator 12 is connected to the drainage system 5, and the liquid outlet is connected to the mixer 15. The installation contains a tank 16 with an oxidant-forming reagent solution equipped with a solution level sensor 17. The tank 16 is connected to the mixer 15. A mechanical filter 18 is installed on the connection line, liquid submersible pump 19, an adjustable throttle 20 and a solution flow indicator 21. The mixer 15 is connected to the cathode chamber of the electrochemical cell 22, the output of which is connected by overflow to the anode chamber of this cell, and the output d of the anode chamber of the cell 22 is connected through the inductor 23 to the tray 1 and the adapter 3. The installation also contains unregulated inductors 24 and 25.

 Tray 1 is installed on a mobile stand 26, on which a container with a solution 17 and an electro-hydraulic unit 27 are also fixed, in which the installation units and control equipment are located. Tray 1 may be equipped with a bracket 28 for securing and processing non-immersible endoscopes.

 Installation works as follows.

 The endoscope to be cleaned and sterilized is installed in tray 1, in which it will be processed.

Tap water from the source 6 enters through the control filter 7 into an electromagnetic valve 8, which turns off the water supply when the power is turned off, and then into the fluid pressure regulator 9, which ensures a constant flow rate when water pressure fluctuates from 2 to 6 kg / cm ² . Then, through the flow indicator 10, which turns off the power when the water supply is turned off, it enters the electrochemical treatment and passes through the cathode chamber of a cylindrical diaphragm electrolyzer 11 with coaxial electrodes and a coaxial ceramic diaphragm based on a mixture of zirconium aluminum and yttrium oxides into the flotator 12. Before entering in the flotator 12, the flow is additionally saturated with air in the mixer 13 using an air pump 14. In the flotator, bubbles of electrolysis hydrogen and air are separated and from clinging to them insoluble particulate impurities, which basically represent hydroxides of heavy metals and calcium and magnesium. Part of the water treated in the cathode chamber enters the anode chamber of the electrolyzer 11, and from there through the inductor 25 into the drainage. Flotation sludge from flotator 12 also enters drainage through throttle 24.

 The purified water from the flotator 12 enters the mixer 15, where also from the tank 16, equipped with a level sensor 17, is supplied with a pump 19 through a mechanical filter 18 the required amount of reagents, namely sodium chloride or a mixture of sodium chloride and sodium bicarbonate, providing a concentration of salts introduced no more than 1 g / l. The level sensor 17, an adjustable throttle 20 and a flow indicator 21 provide the receipt of the required amount of solution and shutdown the installation when the operation mode fails.

 The prepared stock solution enters the electrochemical cell 22, sequentially passing its cathode and then the anode chamber. Possible sequential passage of the cathode chamber of the tank with a catalyst (not shown) and the anode chamber. In all cases, the treatment regimes in the chambers are chosen so that, at the outlet of the cell, the treated solution has a pH of 4.5-5.5 and an active ingredient content of up to 300 mg / l of active chlorine, after which the resulting washing-sterilizing solution enters the adapter 3 and through the throttle 23 is fed into the tray 1. The mixer 2 provides forcible passage through the tray on the outer surface of the endoscope of a predetermined amount of washing-sterilizing solution, the excess of which is constantly removed through overflow pipe 4.

 After completion of the first stage, the treatment mode of the initial solution in the electrochemical cell 22 is changed so that the resulting washing-sterilizing solution has a pH of 6.5 - 7.0 and the content of active ingredients is up to 200 mg / l of active chlorine. The resulting solution is also fed to the processing of the external and internal surfaces of the endoscope.

 Upon completion of the second stage, the operating mode of the electrochemical cell 22 is again changed so that the resulting washing-sterilizing solution has a pH of 7.7 - 8.2 and the content of active ingredients up to 100 g / l of active chlorine. The solution also enters the processing of the external and internal surfaces of the endoscope.

 It is significant that during the passage of all three stages a fresh solution is constantly supplied to the surfaces to be treated, and the spent after a single passage is discharged into the drainage system 5. Processing at each stage lasts 4-6 minutes.

 During all three stages, either only in the first, or in the first and second and second parts, the metal parts of the endoscope are protected from corrosion by cathodic polarization.

 Compared with the known solution, the invention allows to completely destroy microorganisms of all types and forms, completely remove organic and inorganic foreign substances from all surfaces to be treated and from the depth of the structural materials of the endoscope, sterilization of endoscopes is achieved, which is impossible to obtain by a known solution. The operation of the installation is fully automated. In addition, during the operation of the installation, the mechanical properties of the polymer (cracking, elasticity) and metal (corrosion) materials of the endoscope, as well as the properties of the surfaces of the optical system (film, clouding), do not deteriorate, which indicates a higher result. After cleaning and sterilization, the surfaces of the endoscope are non-toxic, which eliminates the need for rinsing and speeds up the process. The washing and sterilizing solutions used in the installation do not need to be neutralized before draining into the sewer and are safe for personnel who are involved in the cleaning and sterilization procedure.

Claims (6)

 1. Installation for cleaning and sterilizing endoscopes with liquid detergent-sterilizing solutions, containing a device for fixing the endoscope, equipped with devices for supplying external and internal surfaces of the endoscope with detergent-sterilizing solutions and a device for draining waste solutions, a unit for preparing detergent-sterilizing solutions from the initial solution an oxidant-forming reagent containing sodium chloride, and the node for the preparation of washing-sterilizing solutions contains at least one diaphragm an electrochemical cell, the electrode chambers of which are connected in series in the direction of the processed solution, and the entrance to the first electrode chamber of the cell is connected to the device for supplying the initial solution, the outlet from the second chamber along the channel is connected to the device for supplying washing and sterilizing solutions to the internal and external the surfaces of the endoscope device for fixing it, a current source, a control unit that connects the electrodes of the electrochemical cell with the poles of the current source, sensors and regulating aratura connected to the control unit, characterized in that the device for fixing the endoscope is made in the form of a tray, in which the device for draining the spent solutions is made in the form of an overflow pipe, the device for supplying the solution to the external surfaces of the endoscope is made in the form of an electrochemical mixer connected to the block control and installed on the bottom of the tray in the end opposite from the overflow pipe, a device for supplying washing and sterilizing solutions to the inner surfaces of the endoscope filled in the form of an adapter, the electrochemical cell is made vertical, cylindrical with coaxial electrodes and a ceramic diaphragm, dividing the interelectrode distance into the cathode and anode chambers with an entrance at the bottom and an exit at the top, the device for supplying the initial solution is connected to the input of the cathode chamber of the cell, the overflow connects the cathode output with the anode input, and the output of the anode chamber is connected to the tray and with the adapter, and the installation further comprises a container with a solution of an oxidant-forming reagent, equipped with a solution level sensor and an initial solution preparation unit connected to its supply device and including a tap water supply line, with a control filter, an electromagnetic valve, a liquid pressure regulator and a flow indicator installed in series, a vertical cylindrical coaxial electrolyzer with a ceramic coaxial diaphragm separating the interelectrode space on the anode and cathode chambers with an entrance at the bottom and an exit at the top, a sealed flotator, manual for saturating the water flow with air and a mixer connected to the vessel with the solution of the oxidant-forming reagent through a mechanical filter, a submersible type liquid pump, an adjustable choke and a flow indicator of the reagent solution, the tap water supply line being connected to the input to the cathode chamber of the electrolyzer, the output of the cathode chamber is connected with the input of the flotator and with the entrance to the anode chamber, the outlet of purified water from the flotator is connected to the mixer, and the output of the anode chamber of the electrolyzer and the output of the flotator sludge connected to the drainage system of waste detergent-sterilizing solutions, and a device for saturating the water flow with air is installed before entering the flotator. 2. Installation according to claim 1, characterized in that the flotator is made in the form of a sealed cylindrical container of constant cross-section with a tangential supply of treated water placed at a distance of 2/3 of the height of the flotator from its bottom and installed horizontally or at an angle of 4 - 5 ^o to the horizontal cross-section of the flotator and pointing upwards, as well as a device for removing treated water from the flotator, made in the form of a vertical pipe mounted along the axis of the flotator with an inlet at the bottom of its bottom and the mouth of the flotator A device for removing sludge has been updated.  3. Installation according to any one of paragraphs. 1 and 2, characterized in that it further comprises a container connected in series with a detergent solution and a mixer, the mixer is installed on the line connecting the outlet of the anode chamber of the cell of the washing-sterilizing solution preparation unit with the tray and the adapter.  4. Installation according to any one of paragraphs. 1 to 3, characterized in that it further comprises means for providing cathodic protection of the metal parts of the endoscope, connected to the control unit and connecting the negative pole of the current source with the metal parts of the endoscope, and the positive pole with the axis of the electromechanical mixer.  5. Installation according to any one of paragraphs. 1 - 4, characterized in that at the overflow connecting the cathode and anode cells of the cell, a capacitance with a catalyst is installed with an entrance at the top and an exit at the bottom, the entrance of the chamber connected to the output of the cathode chamber and the output of the capacitance to the input of the anode chamber.  6. Installation according to any one of paragraphs. 1 to 5, characterized in that the installation is mounted on a trolley, equipped with means for supplying tap water, electricity and the removal of spent liquid funds.

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