RU2221592C2 - Method for disinfection of medical waste and device for its realization - Google Patents

Abstract

FIELD: medicine and ecology, applicable for disinfection and sterilization of infected medical waste in hospitals. SUBSTANCE: the method provides for moistening of waste by aqueous solution of sensitinogen in the form of a surface-active agent, periodic irradiation of the waste in the working cavity by microwave energy with an isothermal cure in the pauses between the periods of irradiation and removal from the cavity. The device for realization of the method has a metal body forming the working cavity at least with one double-wall door and a continuous layer of heat insulation on the outer surface of the body and in the interwall space of the door. One or several microwave oscillators connected to the microwave inputs of the metal body serves as a source of microwave energy. A protective polymeric film is made on the microwave inputs. EFFECT: reduced specific power consumption by 5-7 times at a complete destruction of all microorganisms of vegetative and spore forms in the waste. 2 cl, 2 dwg, 1 tbl

Description

 The invention relates to the field of medicine and ecology, in particular to the disinfection of medical waste of predominantly dangerous and extremely dangerous classes of medical institutions, and can be used directly in places of primary waste generation.

Known microwave method of disinfection of medical waste, which consists in the fact that medical waste (plastics, glass, paper, etc.) is crushed, pre-heated with steam at a temperature of 140 ^o C and a pressure of up to 4.5 • 10 ⁵ PA, and then subjected to microwave irradiation for 10-15 minutes With specific energy consumption of 690-1380 kWh / t, complete disinfection of waste is achieved. [1. A.Tata, F. Beone. Hospital waste sterilization: a technical and economic comparison between radiation and microwaves treatments. Radiation Physics and chemistry, v. 46, N 4-6, p. 1153-1157, 1995].

Also known equipment for the treatment of medical waste, containing a loading hopper, at the outlet of which is located a grinder. The output of the grinder is connected to the input of the hollow body in which the waste is processed. As a heat source, a microwave device containing a magnetron is used, the output of which is connected through a transparent wall of the body to a cavity bounded by the body. Opposite the input of the hollow body, the output of the device is made. The outer wall of the housing can optionally be wrapped with heating tape. [2. UK patent 2320247, IPC A 61 L 11/00, the date of receipt of the application 11.12.97, application number 9726223. Inventions of the world, N 12, 1999]
Known technical solutions require for their implementation of large specific energy costs.

 Closest to the claimed object in technical essence is a method and device for disinfection of medical waste using microwave radiation. (Mikrowellen & HF Telecommunications Magazine, 1993, Vol. 19, N 3, S.179. There is a translation of “The use of microwave radiation for the disinfection of medical waste.” Information and analytical issue “Signal”, series “Foreign Electronics News”, N 19 (228), 1993, p. 24, GNPP Istok, Fryazino, Moscow Region).

 The known method includes preliminary grinding of the waste, moistening it with water vapor and mechanical movement into the cavity for microwave irradiation with a frequency of 2.45 GHz and a power of 7.2 kW. The resulting final product in the form of granules (whose volume is 30% less than the initial volume of waste) is a well-disinfected material that can be further disposed of along with other types of waste or incinerated in closed incineration plants. A known device that implements this method contains a waste shredder, a steam humidifier, a working cavity with inlet and outlet, a conveyor for moving the waste into the working cavity and removing them from the cavity, six microwave generators with an output of 1.2 kW each, the outputs of which are through Microwave adapters are directed into the working cavity, the power and cooling means of the generators, the control tool, as well as the outer casing of the device.

A disadvantage of the known technical solution is the increased specific energy costs (500 Wh / kg), as well as the large dimensions of the installation (7.2 x 3.3 x 2.8 m) and weight (11 t). In addition, the known method and device are designed to disinfect large volumes of medical waste (150 kg / h) and implement a continuous production cycle, therefore they are used only in large hospitals and medical centers. These shortcomings make it economically disadvantageous to use the known solution in those hospitals in which the daily amount of medical waste is less than the indicated volumes, and the use of one such device per group of hospitals that are geographically remote from each other entails additional costs associated with the need to comply with the collection, storage and transportation rules waste to the place of treatment, which increases the risk of uncontrolled losses and possible infection. [3. The rules for the collection, storage and disposal of waste from medical institutions. Sanitary rules and norms SanPiN 2.1.7.728-99. The publication is official. State system of sanitary and epidemiological regulation of the Russian Federation. Ministry of Health of Russia. Moscow. 1999]
The objective of the invention is to reduce specific energy costs during the disinfection of medical waste while maintaining high disinfecting and sterilizing effects of the method.

 The technical result is the reduction of specific energy costs (5-7) times during the disinfection of medical waste with the complete destruction of all microorganisms in waste, both vegetative and spore forms.

 Another technical result that is achieved when solving the problem is to reduce the size and weight of the device that implements the proposed method.

Achieving the indicated result is based on the following provisions:
- real medical waste (bandages, cotton wool, paper, glass, organic operating waste, etc.) are significantly heterogeneous in terms of their ability to absorb microwave energy. To achieve guaranteed microwave exposure to all parts of the disinfected mass of medical waste, the exposure time should be selected based on the worst absorption of microwave energy. The increase in exposure time leads to additional energy costs. These costs can be avoided if the processed waste is made homogeneous. In the known method and device, this uniformity is achieved by preliminary grinding of the waste. However, this method of homogeneity of the processed waste cannot be recognized as rational, since grinding is an energy-intensive process. In addition, the technological equipment used to grind and move the disinfected waste turns out to be infected and itself requires periodic disinfection, for example, during preventive and repair work. Humidification of treated waste water vapor, although it leads to the fact that the ability of all components to absorb microwave energy approaches the absorption capacity of water, but still requires large energy costs and does not give good wetting;
- according to the provisions of the theory of wetting surfaces of solids with liquids, the wetting angle depends on the ratio of the attractive forces between the molecules of the solid and the liquid and the forces of intermolecular attraction in the liquid. In all cases of non-wettability, the intermolecular attraction in the liquid exceeds the attractive forces of the liquid molecules to the molecules of the solid and an energy barrier is formed between the surfaces, preventing their rapprochement;
- to overcome this barrier, instead of energy-intensive thermal excitation of liquid molecules (which occurs in the prototype when wetting the waste with steam), other methods can be used to improve the wetting of the waste, for example, wetting regulators;
- the achieved thermal state of the waste can be maintained unchanged without supplying microwave or other energy during the time at which the harmful thermal effect on the microorganisms contained in the waste is still preserved, and after this time, if necessary, the microwave irradiation cycle can be repeated.

 The problem is solved in that in the method of disinfection of infected medical waste, in which the waste is moistened and placed in the working cavity, irradiated in the cavity with microwave energy and removed from the cavity, humidification is carried out with a liquid solution of a sensitizer in the form of a surface-active substance (surfactant) with water in the ratio of volumes (1.5-15)% surfactant, the rest is water, and the mass of the solution is more than 0.1 weight parts per weight part of the waste, irradiation is interrupted and resumed, in the pauses between irradiation an isothermal discharge rzhku waste using electronic control means, after the absorption of microwave energy irradiation is stopped and the waste is carried out last isothermal exposure.

 In addition, the task is solved by the fact that in the device for disinfection of infected medical waste containing a metal body forming an operating cavity with an input and an output, one or more microwave generators, the outputs of which are connected via microwave adapters to the microwave inputs of the metal case, means power and cooling of the generators, the device control means and the outer casing, the input and output of the metal case are made in the form of at least one double-walled door, in the space between which, and the outer portion of the metal housing and microwave adapters formed a continuous layer of insulation, and the microwave input is made protective polymer film.

 Reducing the time of microwave irradiation (or reducing energy costs) necessary for the destruction of microorganisms in waste and their spores is achieved by wetting the waste with a sensitizer liquid solution in the form of a surfactant with water in a volume ratio of (1.5-15)%, the rest is water and the mass of the solution is more than 0.1 parts by weight per one part by weight of waste. This improves the wettability of all waste fragments due to the fact that in the interfacial space “microorganism surface - water molecule surface” the existing energy barrier is replaced by an oriented adsorption layer, which increases the sensitivity of microorganisms to the mechanical effect of polar water molecules that rotate twice during the microwave period on their cell wall impacts around its electrical center.

 An additional reduction in the time of microwave irradiation is achieved by introducing isothermal exposure of the waste, the duration of which is determined by the quality of the thermal insulation of the housing of the working cavity of the device from the environment and in the proposed device reaches at least half the duration of microwave irradiation.

 The concentration of surfactants in the solution is selected to the maximum within the specified limits during the disinfection of waste of organic origin, microbiological cultures and strains, the surface of the fragments of which has strongly pronounced water-repellent properties, as well as food waste from the infectious departments; the minimum concentration of surfactants is prescribed for relatively dry medical waste (contaminated cotton-gauze and textile materials, paper, cellulose, plastics, glass, metal, etc.), when the waste contains no fragments of organic origin.

 The maximum weight of the solution is selected from the ratio of 0.25 parts by weight of solution to one part by weight of waste for relatively dry medical waste that does not contain fragments of organic origin. The density of such waste, as practice shows, is (0.3-0.4) kg / l. The minimum mass of the solution in the ratio of at least 0.1 weight parts of the solution per weight part of the waste is selected for medical waste of organic origin, microbiological cultures and strains having a density of (0.7-0.8) kg / l.

 The energy level of microwave irradiation is assigned depending on the hazard class of the waste and on the degree of resistance of microorganisms to microwave and thermal effects. In the disinfection of hazardous medical waste, the so-called Class B waste (potentially infected waste; materials and instruments contaminated with secretions, including blood; patient discharges; pathological wastes; organic operational wastes (organs, tissues, etc.); all wastes from infectious departments (including food); waste from microbiological laboratories working with microorganisms of 3-4 pathogenicity groups; biological vivarium waste), provided that the type of microorganisms contained in the waste known (for example, only vegetative forms are present, and spore forms are absent)), the microwave irradiation energy is set at 50 Wh / kg (energy consumption will be 1.3 • 50 = 65 Wh / kg, see table).

 If the type of microorganism is unknown, then the maximum level of microwave irradiation is set, but not lower than 158 Wh / kg (energy consumption will be 1.3 • 158 = 205 Wh / kg, see table). When neutralizing extremely hazardous wastes, the so-called class B wastes (materials in contact with patients with especially dangerous infections; wastes from laboratories working with microorganisms of 1-4 pathogenicity groups; wastes from tuberculosis, mycological hospitals; wastes from patients with anaerobic infection) prescribe the maximum microwave level energy, but not lower than 158 Wh / kg.

 The duration of isothermal exposure after the cessation of microwave irradiation is at least half the duration of exposure.

 These differences allow us to achieve a reduction in specific energy costs during the disinfection of infected medical waste with the complete death in the waste of microorganisms of both vegetative and spore forms, as well as reduce the size and weight of the device that implements the proposed method.

 In FIG. 1 and 2 depict the appearance of the device, its composition and installation option in a wall partition are shown.

The proposed device contains a working cavity 1, limited by a metal casing 2, an input 3 and an exit 4 door, two microwave generators 5, the outputs of which are connected via microwave adapters 6 to the microwave inputs 7 of the metal housing 2, power and cooling means 8 of the generators 5, control means 9 and the outer casing 10 of the device. On the outer surface of the metal housing 2, on the microwave adapters 6 and in the inter-wall space of the doors 3 and 4, a continuous layer of thermal insulation 11 is made in the form of a 30 mm thick foam sheet. In the proposed device, the quality of thermal insulation of the working cavity 1 from the external environment is such that the waste temperature of 100 ^o C achieved in 8-14 minutes of microwave exposure decreases for 90 minutes during isothermal exposure to 90 ^o C.

 In Fig. 1, for simplicity, a second microwave generator 5, a second set of power and cooling means 8, a second microwave adapter 6, mounted on the opposite wall of the working cavity 1, and a protective polymer film on the microwave inputs 7 of the metal case are not shown 2, preventing the penetration of moisture from the working cavity 1 to the outputs of the microwave generators 5.

The device has the following parameters:
- the output power of each microwave generator is 500 watts;
- operating frequency (2450 ± 50) MHz;
- input power 1300 W;
- the volume of the working cavity is 170 l.

 Selecting and setting the required operating mode (set level of microwave power) and processing time (exposure time and duration of isothermal exposure), as well as disabling microwave power when trying to open any of the doors and the inability to turn on microwave power when the door is open or there is no working load the cavity is carried out by an electronic control means 9. The levels of industrial interference and microwave power flux density created by a working installation comply with the requirements established by standards.

 The proposed device is installed and fixed in the common wall of two adjacent rooms of the medical unit of a medical facility in such a way that the doors of the device go to different rooms. This makes it possible to isolate rooms isolated from each other for waste that has not yet been disinfected and already disinfected, and exclude the possibility of crossing their paths and joint storage. Both rooms meet the requirements for the internal premises for temporary storage of medical waste specified in the link [3].

 An example implementation of the method and operation of the device.

 In two vessels, a sensitizer liquid solution is prepared - in one vessel of a minimum concentration of 1.5%, in the second - a maximum concentration of 15%. Solutions are prepared as follows. Both liters are poured N liters of drinking water according to GOST 2874. Then 15 • N ml of Progress liquid detergent TUZ 8-10719-77, approved for use by the document of the Ministry of Health of the Russian Federation, Methodical Instructions for Disinfection, Presterilization Cleaning and Sterilization, is poured into the first vessel. medical devices ", Moscow, 1998, and the contents of the vessel are mixed until the surfactant is dissolved.

 15 • N ml of Progress liquid detergent is poured into the second vessel and the contents are mixed until the surfactant is dissolved.

 Instead of liquid detergent, washing powder, for example, Lotus TU2381-001-00335215-94, taken in exactly the same volume ratios, can be used. For convenience, both vessels should be marked with labels with the inscriptions, for example, "Minimum concentration", "Maximum concentration".

All relatively dry class B wastes generated in the medical unit are collected in standard disposable plastic bags, which are pre-installed inside standard rigid polymeric reusable containers with an internal volume of 36 l, lining their inner walls with a lap top of the bag over the upper walls of the container. After filling the bag to 3/4 of its volume (27 l), which is:
(0.3-0.4) kg / l • 27 l = (8.1-10.8) kg = (9.45 ± 1.3) kg,
the maximum mass of the solution is uniformly poured into the bag: (9.45 ± 1.3) • 0.25 = (2.3 ± 0.3) kg taken at a minimum concentration of 15 ml of surfactant per liter of water. Next, air is removed from the bag and, twisting together the upper edges of the bag, tie the ends of the twist with a knot and close the container with a lid.

 All Class B organic waste (operational waste, microbiological cultures and strains, vaccines, virologically hazardous material) is collected similarly, but since their density is, as practice shows, (0.7-0.8) kg / l, the bag is filled half (18 l), while the mass of collected waste will be: (0.7-0.8) kg / l • 18 l = (12.6 ± 14.4) kg = (13.5 ± 0.9) kg . With this filling, the weight of the waste container does not exceed 15 kg, which allows one person to transport the loaded container. Then the minimum amount of solution is uniformly poured into the container: (13.5 ± 0.9) kg • 0.1 = (1.35 ± 0.9) L taken at a maximum concentration of 150 ml of surfactant per liter of water. Next, air is removed from the bag, tied as described above and closed the container.

 Class B waste collection is carried out similarly.

 The collection of sharp tools (needles, feathers) is carried out separately from other types of waste in a one-time standard solid packaging in one layer. The assembled tool is poured with a solution with a minimum concentration of surfactant so that the tool is only half filled with solution. Hard packs with tools are closed with lids and placed in a horizontal position inside a reusable container.

 Refillable containers for collecting hazardous waste of class B are yellow in color, and for collecting extremely hazardous classes of C - red (according to the requirements of [3]. The working cavity of the device has such dimensions that two containers of the same hazard class are placed in it at the same time.

 Waste collection, humidification, removal of air from the bag, closing of the bag and container, delivery of the container to the disinfection room is carried out by a responsible employee of the medical unit and is carried out with a gauze bandage and rubber gloves in compliance with safety requirements when working with pathogens of infections of pathogenicity groups 1-4 [3].

 Next, the door 3 of the device is opened and two containers of the same hazard class are placed in the working cavity of the device.

The door 3 is closed, while the control means 9 automatically selects a maximum level of microwave irradiation of 1000 watts. If necessary, you can select other, lower power levels. The appropriate controls 9 select the necessary exposure time, for example 0.1 h (6 minutes), which corresponds to microwave energy 1000 W • 0.1 h = 100 Wh (or (100 Wh • 3600 s) = 30 kJ), time exposure, for example 3 minutes, as well as the maximum, for example 100 ^o C, and the minimum, for example 90 ^o C, the temperature of the waste. Next, press the START button of the control means 9 and on the light displays located above each door (the display panel is not shown in the drawing), the countdown of the selected time in seconds begins. At minimum exposure times, the maximum temperature of 100 ^o With may be unattainable, in this case, the control device 9 interrupts the exposure upon reaching the required temperature.

 In the initial stage of microwave irradiation of waste, intense volumetric heating of the liquid phase of the solution and the fractions wetted by the solution occur. But from the moment vaporization begins, which occurs very quickly, the process of foaming begins. As the exposure increases, the temperature of the waste increases, the amount of foam and steam increases, the free part of the bag expands and fills the entire volume of the rigid container, the pressure in it rises and ensures that wet foam penetrates the waste composition, all fractions are moistened and electrically oriented are formed on their surface adhesive layer, including on the surface of microorganisms and their spores.

From this moment on, the polar energy molecules stop repelling them from the surface of microorganisms and spores (which usually have a negative electric charge) and they act directly on the cell wall of microorganisms and on the spore shells, destroying them. This moment occurs before the liquid phase of the solution boils and, like the moment of boiling, is measured by two sensitive temperature sensors installed on the outer part of the ceiling and the bottom of the working cavity 1 under the insulation layer 11 (temperature sensors are not shown in the drawing). Thus, during the treatment of waste, their temperature is always maintained at an optimal level, for example (90-100) ^o С, at which the process of destruction of microorganisms, vegetative and spore, proceeds with maximum efficiency, and the liquid phase does not reach the boiling stage.

 With long times of microwave exposure, a certain amount of steam (water molecules) can break out of the bag into the container and from the container into the working cavity and condense on the walls of the working cavity in the form of water droplets, therefore, due to the requirements of sanitation and good electrical conductivity, the walls of the working cavity are made of non-magnetic stainless steel, and the bottom of the working cavity has recesses to collect the resulting condensate. Variants of removing steam from the cavity are possible, for example by means of a thermostatted outlier and a liquid disinfecting shutter. After the selected time, the control means 9 gives a sound signal. In the opposite room, another operator, after a beep, making sure on the light panel above the door 4 that the designated processing time has expired, opens the door 4, removes the containers from the working cavity 1 and closes the door 4. The medical waste thus treated can be stored and transported to disposal sites or burial in reusable containers, and after unloading the containers, they can again be returned to health facilities.

 The control of the waste disinfection process is carried out on the light panel of the control 9. In addition, periodic technical and laboratory monitoring of the effectiveness of the disinfection or sterilization of the waste is carried out by using the appropriate test microorganisms located in the working cavity along with the waste during device loading.

 Verification of the effectiveness of the proposed method was carried out as follows.

In a rigid polymer container with a volume of 36 l, a plastic bag of no less volume was placed and filling it 3/4 of the volume with relatively dry cotton-gauze and textile waste, paper, plastic, glass and metal fragments - equivalent to real waste, in different places of the bag ( at the bottom, in the middle and at the top) test samples were placed in glass tubes with cotton-gauze caps and in plastic bags. Test samples (in plastic bags) were disposable cotton napkins, cotton wool, disposable polymer syringes with needles and blood transfusion systems seeded with Ps.aeruqinosa ATCC 27853 reference strains with an initial concentration of 1 • 10 ⁹ cells / cm ³ , E.coli ATCC 25922 with an initial concentration of 1 • 10 ⁹ cells / cm ³ , Staphilococci ATCC 26874 with an initial concentration of 1 • 10 ⁹ cells / cm ³ , as well as you. Cereus, you. Subtilis and you. Stearothetrmophilus with an initial concentration of 1 • 10 ⁹ cells / cm ³ . In test tubes, pure one-day cultures of microorganisms were tested. Samples in test tubes were seeded with each strain separately and the tubes were closed with cotton-gauze plugs. Thioglycol medium, sugar broth (based on Hottinger broth) and Saburo medium were used as nutrient media. An aqueous solution of a detergent of different weights and concentrations was previously added to half of the tubes and bags; no solution was added to the other half of the tubes. After placing the tubes and bags in the bag, 1 liter of water was poured into the waste for additional microwave load of the device, the bag and container were closed and weighed. The weight of the container was 10 kg. The container was placed in the working cavity of the device and subjected to microwave irradiation, setting each time more and more radiation energy. After each irradiation with the selected energy level, the tubes and bags were removed from the container immediately after irradiation and, repeating the experiment with new tubes and bags, they were removed after isothermal exposure. In each case, after the experiments, the vital activity of microorganisms was checked in microbiological laboratories by determining the mobility of microorganisms by microscopy (crushed drop method) and plating them on nutrient media.

 The test results for different types of microorganisms under different experimental conditions are presented in the table (see the end of the description).

 The results of checking the effectiveness of the proposed method show that wetting the waste with an aqueous solution of a sensitizer in the form of a surfactant and conducting isothermal exposure can reduce the required time of microwave exposure.

 Test reports are available from the applicant.

 The technical advantage of the proposed method for the disinfection of medical waste and a device for its implementation is to reduce specific energy costs during the treatment of waste by 5-7 times, as well as reducing the weight (up to 50 kg) and dimensions of the device implementing the method (1250x536x476 mm), which expands their scope application to the level of medical institutions of the district and village scale. When installing the proposed device directly in the medical units, one more advantage is achieved - the possibility of rejecting the traditionally used in large quantities of liquid disinfectants based on chlorine, dangerous to human health and the environment.

 The method and installation are reliable in operation, environmentally friendly and allow destroying vegetative and spore microorganisms in medical waste, so that medical waste treated with this method can be stored, disposed of and disposed of without fear that they can become sources of infection.

 Implementation of the proposed solution for the disinfection of medical waste in medical institutions will improve the sanitary and epidemiological situation in society associated with environmental pollution by sources of infection - medical waste.

Claims (2)

1. The method of disinfection of infected medical waste, in which the waste is moistened and placed in the working cavity, irradiated in the cavity with microwave energy and removed from the cavity, characterized in that the moistening is carried out with a liquid solution of a sensitizer in the form of a surfactant with water in a volume ratio (1 , 5-15)% surfactant, the rest is water, and the mass of the solution is more than 0.1 parts by weight for one weight part of the waste, irradiation is interrupted and resumed, in the pauses between irradiation, isothermal exposure of the waste is carried out using electronic controls, after the expiration of the irradiation time, the last isothermal exposure is carried out. 2. A device for disinfecting medical waste, comprising a metal housing forming an operating cavity with an input and an output, one or more microwave generators, the outputs of which are connected via microwave adapters to the microwave inputs of the metal housing, power and cooling generators, device control and an outer casing, characterized in that the entrance and exit of the metal body is made in the form of at least one double-walled door, in the inter-wall space of which, on the outer surface of the metal Busan microwave adapters formed a continuous layer of insulation, and the microwave input is made protective polymer film.

Images