RU2480242C1 - Disinfection system for medical and biological dangerous and potentially dangerous waste with use of microwave radiation - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to the disinfection of medical and biological waste. A disinfection system for medical and biological waste comprises a microwave chamber accommodating a working chamber and magnetrons mounted from the outside of the chamber with the chamber comprising a sealed container with a lid to accommodate water-wet waste, and the lid of the sealed container has a hole with a hose fitting for steam removal. From the outside of the chamber, there are a cooler for steam escaping from the container, and a sensor measuring the steam temperature coupled to a microprocessor control board. The container has a hole to mount a thermocouple to measure the disinfected waste temperature. The thermocouple is immersed to the bottom of the container into disinfested waste and connected to the microprocessor control board. The magnetron power is adjusted by one of the measured parameters, namely the temperature of steam escaping from the container or the temperature of disinfected that is the first to reach the value specified by an operator.

EFFECT: improved safety and adjustment accuracy of the waste disinfection process, and eliminates potential inflammation of disinfested waste.

5 cl, 12 dwg

Description

The invention relates to microwave systems for the disinfection of medical and biological hazardous and potentially hazardous wastes, for example, disposable syringes, disposable intravenous infusion systems, glass slides for laboratory tests, sampling instruments for conducting clinical and biological blood tests, and various biological media: blood, urine, blood plasma, hemacones, feces and tissues of organs with preliminary wetting.

The inventive microwave system allows you to transfer hazardous and potentially hazardous medical and biological waste into non-hazardous class waste (household waste) with a view to their subsequent regular disposal. The inventive microwave system is not intended for sterilization of medical and biological waste.

The prior art device and method for wet disinfection of infected medical waste using microwave disinfection methods, described, for example, in RF patent No. 2221592, priority date 03.15.2001, "Method for the disinfection of infected medical waste and device for its implementation", issued on name of the Obninsk Center for Natural Sciences and Technology.

In this patent, moistened hazardous and potentially hazardous medical wastes are placed in a container with the addition of aqueous solutions of sensitizers in the form of a surfactant (liquid soap), which are placed in a microwave chamber and subjected to periodic microwave irradiation with isothermal exposure in pauses between periods of exposure. The microwave camera is controlled by mechanical relays. The ventilation of the working area of the microwave camera is carried out using forced ventilation.

The disadvantage of this device is the lack of automatic control over the process of disinfection of waste, which in itself is potentially dangerous for the operator. The absence of sensors for monitoring the temperature of steam at the outlet of the container in which the disinfected waste is placed, and the absence of temperature control inside the container greatly increase the risk of ignition of the disinfected waste.

The use of a supply system of ventilation of the working chamber with the simultaneous absence of a filtration system of the air leaving the working chamber leads to the fact that odors that are unpleasant for the operator can be generated during the disinfection of waste, which themselves can be toxic.

The quality control of disinfection is carried out by the operator manually by opening the container and the operator visually inspecting the color change of the test strip in the container, which is inconvenient for the operator.

For guaranteed disinfection, the operator must use additional disinfectants in the form of liquid soap added to the container, which increases the amount of consumables.

The prior art installation according to US patent No. 6524539 "Microwave sterilizer", publication date 02/25/2003, intended for the disinfection and sterilization of dry or wet infected medical waste using microwaves on a container mounted on a turntable and placed in a sealed working chamber.

The control system for the disinfection process in this patent is carried out using automatic control of process parameters, which includes the mandatory operation of weighing the waste before disinfection and calculating the control unit the required amount of water to be added to the waste container, which complicates the overall disinfection process.

This installation requires a stationary connection of a water source for supply to a container with waste, as well as a stationary sewage system for discharging wastes after the waste disinfection procedure, which limits the possibility of using the device, for example, in the field.

The prior art also known US patent No. 5879643 "Microwave installation for heating, disinfection and sterilization of materials", publication date 03/09/1999, designed for liquid disinfection of microwave radiation of potentially hazardous waste placed in an airtight container installed in the working chamber of a microwave oven .

This installation is equipped with an automatic system for preventing the ignition of waste and a container, which is an injector located in the container cap, a pipe for the release of condensate, smoke and steam into the external environment, also installed in the container cap, as well as its own container fire extinguishing system installed in the working chamber.

In this installation, when disinfecting waste with a container lid accidentally opened, it is impossible to ensure the safety of the complete disinfection cycle due to the complete evaporation of liquid from the container with the subsequent operation of the internal fire extinguishing system in the working area of the chamber and inside the container, which will lead to interruption of the disinfection process.

The closest of the analogues is US patent No. 5407641 "Microwave installation and container for disinfection and sterilization of materials", publication date 04/18/1995, selected for the prototype.

The specified installation contains a working chamber and a container placed in the working chamber. Potentially hazardous waste intended for disinfection, which is moistened with liquid (water), is placed in the container. The container has a lower part and an upper lid that can be tightly connected to each other to obtain an internal space for the placement of waste to be treated with microwave radiation in the working chamber. There is a hole in the lid of the container. The installation is equipped with measuring instruments that allow controlling the temperature of the steam leaving the container. The measuring means is a temperature sensor of the steam leaving the container. In this case, the prototype shows several options for the location of the temperature sensor leaving the container of steam. In Fig. 13 (patent US 5407641) shows the temperature sensor leaving the container of steam, pos. 232, located outside the working chamber, which actually measures the heating temperature of the pipe exhausting the container from the container, by the temperature of which it is possible to indirectly judge the temperature of the steam leaving the container. In Fig. 8 and Fig. 11 (US patent 5407641) shows a second embodiment of the location of the temperature sensor of the steam leaving the container, item 58, made combined with the spray head of the injector for supplying water to the container. The third embodiment of the temperature sensor for steam leaving the container is shown in Fig. 1 and Fig. 5, item 14, in which the temperature sensor of the steam leaving the container is located in the lid of the container and connected to the microcontroller of the control system.

The power regulation of the microwave radiation supplied to the working chamber is carried out only by evaluating the signal from the temperature sensor of the steam leaving the container.

The disadvantage of the prototype is that the regulation of the power of microwave radiation (magnetrons) is carried out only by an indirect parameter - the temperature of the steam leaving the container, while the actual temperature of the disinfected waste in the container is not taken into account, and it can seriously differ from the indirect control parameter (temperature of steam leaving the container). For example, when disinfecting wastes cooled to low temperatures (for example, frozen blood hemacons), the evaporation of the liquid added to the container and the formation of escaping steam occurs faster than heating the entire volume of waste. Moreover, when controlling only the temperature of the steam leaving the container, the control system will give a command to reduce the power of the magnetron, which will lead to incomplete disinfection of the waste cooled to low temperatures.

The disadvantages of this system include the increased fire hazard of waste processing during depressurization or accidental opening of the container, while the process of disinfection of waste is interrupted due to an emergency fire hazard.

When the container is depressurized, for some reason, evaporation of the liquid from the waste occurs, followed by their drying during the disinfection process and possible fire.

The temperature control of only the steam leaving the container is insufficient to ensure safe continuous operation of the material disinfection unit due to the lack of simultaneous control of the temperature of the waste placed inside the decontamination container.

If only the temperature of the steam leaving the container is monitored, then when the container is depressurized in the absence of temperature control of the disinfected waste placed inside it, the temperature sensor of the steam leaving the container will continue to operate normally and falsely perceive the container heating as insufficient, since the container is depressurized the sensor of the steam leaving the container does not receive genuine information about the temperature of the steam leaving the container due to leakage of its part in ochuyu zone of the chamber. In this case, the sensor of the steam leaving the container during depressurization of the container reflects its temperature significantly lower than the actual temperature of the disinfected waste in the container and increases the power of the magnetron or continues to maintain it at the maximum level to increase the temperature in the container, thereby creating a critical situation of overheating of the container with waste and sharply increasing the likelihood of fire.

The objective of the invention is the creation of a fireproof microwave disinfection system for medical and biological hazardous and potentially hazardous waste, which allows for a complete continuous disinfection cycle in the event of an emergency (depressurization of the container, accidentally opening the container lid), combined with high comfortable conditions for the operator to work due to the significant reducing the smell of waste during disinfection and the possibility of documenting and / or visualizing Disinfection process on the control system monitor.

The problem is solved in that in the disinfection system of medical and biological hazardous and potentially hazardous wastes using microwave radiation containing a microwave chamber equipped with magnetrons and a working chamber, while the magnetrons are installed outside the working chamber, and a sealed container having a lid is placed inside the working chamber connected to the container by means of clamping latches with the formation of an internal space for placement of water-wetted waste to be processed m radiation, while the lid of the sealed container has an opening equipped with a fitting with a hose to exhaust the steam emerging from the sealed container that is generated inside the container during exposure to microwave radiation; outside the working chamber, outside the heating zone of the disinfected waste, a means of cooling the steam exiting the sealed container is installed and measuring means in the form of a sensor for measuring the temperature of the steam leaving the sealed container, connected with a microprocessor control board designed to evaluate the signal from the measuring tool and control (decrease or increase) the power of the magnetrons depending on the results of the assessment, while the working chamber is equipped with a means to create uniform irradiation of a sealed container with disinfected waste, the new is that in the sealed container there is an additional hole for installing an additional measuring tool that measures temperature of the disinfected waste, made in the form of a thermocouple immersed in the disinfected waste to the bottom of the container, connected to a microprocessor control board that simultaneously evaluates two signals from two measuring instruments, namely, evaluating the signal from the measuring means in the form of a sensor for measuring the temperature leaving the sealed container steam and signal evaluation from a measuring tool that measures the temperature of the disinfected waste, while regulating (decrease increase or increase) of the magnetron power is carried out according to one of the measured parameters, namely, the temperature of the steam leaving the sealed container or the temperature of the disinfected waste, which first reached the value set by the operator.

In addition, a filter block is installed on the outside of the microwave chamber from the side opposite to the magnetrons, which contains a fan that removes air from the working chamber and directs it into the ventilation flange, in which a second fan with a carbon filter element is installed, which ensures forced passage and absorption of unpleasant odor removed from the working chamber of the air generated during the disinfection of waste.

In addition, the first magnetron is connected through the first waveguide to the upper part of the working chamber, and the second magnetron is connected through the second waveguide to the lower part of the working chamber, and the means for creating uniform irradiation of the sealed container with disinfected waste is made in the form of a microwave diffuser installed at the output of the first and / or a second waveguide facing the working chamber.

In addition, the system is additionally equipped with a documenting unit made in the form of a printer integrated in the cooling unit of the steam leaving the sealed container, which displays the results of the disinfection of waste in the form of the duration of the disinfection, the disinfection temperature, the date of disinfection and the evaluation of the disinfection result (successful or not) )

In addition, in another embodiment, the system can be equipped with a remote control based on a laptop with a display connected to the microprocessor control board via a Bluetooth channel, which allows to visualize on the display screen in real time the main parameters of the medical waste disinfection process, namely, to display the temperature steam leaving the sealed container, the temperature of the disinfected waste inside the sealed container, as well as allowing you to change andartnye or set new values of the basic parameters of the waste decontamination process, namely temperature decontaminating wastes placed inside the container, the temperature exiting the pressurized steam container, the duration of step disinfection and duration of cooling phase wastes and allowing to document and archive the data on the process of disinfecting medical waste.

The invention is illustrated by the following drawings:

figure 1 is a General front view of a microwave system designed for the disinfection of medical and biological hazardous and potentially hazardous waste without a remote control;

figure 1 "a" is a General frontal view of a microwave system designed for the disinfection of medical and biological hazardous and potentially hazardous waste, with a remote control based on a laptop;

FIG. 2 is a general frontal view of a microwave system designed to disinfect medical and biological hazardous and potentially hazardous waste with the microwave chamber door removed;

figure 3 is a General rear view of a microwave system designed for the disinfection of medical and biological hazardous and potentially hazardous waste;

4 is a front view of a microwave chamber;

FIG. 5 is a left side view of the microwave chamber;

6 is a front view ¾ on the container for disinfection of waste;

7 is a schematic diagram of a container for disinfecting waste;

Fig. 8 is a rear view from the left in perspective ¾ on the microwave chamber with the upper housing cover removed;

FIG. 9 is a front view in view ¾ of the cooling and documentation unit with the front and top covers of the housing removed;

figure 10 is a schematic block diagram of the operation of the control board 25 of the microwave camera;

11 - algorithm of operation of the microcontroller 56 of the control board 25 without a remote control;

Fig - algorithm of the microcontroller 56 of the control board 25 with remote control (with laptop 53).

The invention is claimed in two versions: without a remote control and with a remote control based on a laptop.

The first embodiment of the invention without a remote control

The microwave disinfection system for medical and biologically hazardous and potentially hazardous waste consists of a microwave chamber 1, including a working chamber 2, inside of which a sealed container 3 with a cover 4 is stationary. The lid 4 of the sealed container 3 is equipped with a thermocouple 5 for measuring the temperature of the disinfected waste and a nozzle 6 s silicone hose 7 for the removal of steam leaving the container. The microwave chamber 1 is equipped with two magnetrons 8 and 9 mounted outside the working chamber 2. The magnetron 8 is connected by means of a waveguide 10 to the upper part of the working chamber 2. The magnetron 9 is connected by means of a waveguide 11 to the lower part of the working chamber 2. Uniform distribution of microwave radiation in the working chamber 2 is provided by a diffuser 12. The magnetrons 8 and 9 are connected to two power transformers 13. On the side opposite to the magnetrons 8 and 9, on the outside of the housing 14 of the microwave chamber 1, a filter unit 15 is installed.

The filtration unit 15 contains a fan 16, which removes air from the working chamber 2 and directs it to the ventilation flange 17, in which a second fan 18 is installed, which ensures the forced passage of the air removed from the working chamber 2 through the carbon filter element 19. The carbon filter element 19 provides reliable absorption of very unpleasant odors emerging from the working chamber 2 in the process of disinfection of waste. In the lower part of the housing 14 of the microwave chamber 1 there are air inlets 20. The working chamber 2 is closed by a door 21 with a glass 22 and a handle 23. On the right side of the door 21 there is a front panel 24 with a control board 25 based on a microcontroller. To carry out the process of disinfecting waste, a bag of hazardous waste 26 is placed in a sealed container 3, one liter of water 27 is added, the sealed container 3 is closed with a lid 4 with a sealing gasket 28 and the latches 29 snap in. In this case, the thermocouple 5 for measuring the temperature of the disinfected waste is in a protective casing 30, placed deep down to the bottom of the sealed container 3, so as to ensure its contact with the disinfected waste. The operator starts the waste disinfection program by pressing the "start" button 31 on the front panel 24, while the control board 25 includes the magnetrons 8 and 9 and fulfills the specified waste disinfection program. In the process of disinfecting waste in a sealed container 3, steam is formed at a temperature of about 100 ° C, which through a fitting 6 in the lid 4 of the sealed container 3 through a silicone hose 7 enters the cooling and documentation unit 32.

The cooling and documentation unit 32 is mounted on top of the microwave chamber 1 and includes a coil 33 with cooling fans 34. A sensor 35 is installed in front of the coil 33 of steam 36 coming out of the sealed container 3. Steam 36, leaving the sealed container 3, enters the coil 33, where it is cooled by a fan 34, it condenses and is led out through a second silicone tube 37 into a glass 38 for collecting condensate. The sensor 35 exiting from the sealed container 3, the pair 36 is connected to the control board 25 by an electric wire 39. A printer 40 is also placed in the cooling and documentation unit 32, from which the paper 41 emerges, on which the results of disinfection of waste are documented in the form of the duration of disinfection, disinfection temperature, date disinfection and assessment of the result of disinfection (successful or not). The printer 40 is equipped with a power supply 42 and a cooling system of the power supply 42 in the form of two fans 43. The control board 25 allows you to control the power of the magnetrons 8 and 9 and receive data from the sensor 35 coming out of the sealed container 3 pair 36 and thermocouple 5, which measures the temperature inside the sealed container 3. A thermocouple 5 for measuring the temperature of the disinfected waste is connected via an electric wire 44 through connector 45 to the control board 25. On the front panel 24 of the control board 25, a 46 ’button is installed n "emergency shutdown of the microwave system. On the front panel 24 of the control board 25, a display 47 of the current state of the disinfection process is also installed, which displays the stages of the disinfection process (heating, holding, cooling), as well as the time until the end of each current stage. Under the display 47 on the front panel 24 of the control board 25 there is an additional indication system indicating the presence of power in the network (indicator 48), the presence of communication with the wireless remote control (indicator 49), the operation of the magnetrons (magnetron indicator 50). Below them is another block of indication 51 of the stage of the disinfection process and indicator 52 of the error of the disinfection process (successful / normal or unsuccessful / error).

A second embodiment of the invention with a laptop-based remote control is shown in FIG. 1 “a”.

The second embodiment of the invention is a completely similar embodiment of the invention according to the first embodiment, which is further equipped with an external remote control based on laptop 53 with a display 54. The remote control based on laptop 53 is connected to the control board 25 of the microwave camera 1 via Bluetooth 55.

The remote control based on the laptop 53 allows you to visualize on the display screen 54 in real time the main parameters of the process of disinfection of medical waste, namely to display the temperature of the steam 36 leaving the sealed container 3 and the temperature of the disinfected waste, measured with a thermocouple 5 to measure the temperature of the disinfected waste .

In addition, the remote control based on the laptop 53 allows you to change the main parameters of the disinfection process for medical waste, namely the temperature of the disinfected waste placed inside the container 3, the temperature of the outgoing steam 36, the duration of the disinfection stage and the duration of the cooling stage.

In addition, the remote control based on laptop 53 allows you to document and archive data on the process of disinfection of medical waste.

The process of disinfection of medical and biological hazardous and potentially hazardous waste is as follows.

Medical or biological hazardous and potentially hazardous wastes are collected at the places of their generation in special plastic bags of red or yellow color, with especially hazardous wastes placed in red packets, and potentially hazardous wastes in yellow packets.

Waste bags are placed in a sealed container 3, after which they moisturize the waste by adding 0.5-1.0 liters of water. Then, the sealed container 3 is closed with a lid 4 with a sealing gasket 28 and a protective casing 30 for the thermocouple 5 for measuring the temperature of the disinfected waste and the latches 29 are latched. In this case, the thermocouple 5 is placed in the disinfected waste. A thermocouple 5 for measuring the temperature of the disinfected waste is connected using an electric wire 44 through the connector 45 to the control board 25.

With the lid 4 of the sealed container 3 closed, the fitting 6 is also placed inside the sealed container 3.

At the same time, the lower end of the fitting 6 is placed near the lid of the container 4 in the upper part of the sealed container 3, where steam generated as a result of heating of the disinfected waste accumulates.

When the sealed container 3 is heated during the disinfection of waste, steam 36 is formed at a temperature of about 100 ° C, which, through the nozzle 6 connected to the silicone hose 7, enters the sensor 35 of the steam 36 leaving the sealed container 3, which is located in the cooling and documentation unit 32.

The sensor 35 emerging from the sealed container 3, the pair 36 is connected to the control board 25 by means of an electric wire 39.

If there is no remote control in the form of a laptop 53 with a display 54 in the waste disinfection system, the waste disinfection program is started by pressing the “start” button 31 on the front panel 24 of the microwave chamber 1. The only waste disinfection program included in the control board 25 is launched. . In this embodiment, it is not possible to change a predetermined waste disinfection program.

The block diagram of the control board 25 is shown in Fig.10.

The control board 25 contains a series-connected microcontroller 56, a data reception and synchronization unit 57, which is a timer and an ADC (analog-to-digital converter), and a data transmission / reception unit via Bluetooth 55 (in this embodiment, is turned off). The microcontroller 56 is based on the Nec UPD 78F1142 chip.

The microcontroller 56 controls the power of the magnetrons 8 and 9 and fulfills the set waste disinfection program shown in Fig. 11 by heating the sealed container 3. In this case, the temperature data of the disinfected waste placed inside the sealed container 3 is taken using a thermocouple 5 to measure the temperature of the disinfected waste , and the data on the temperature of the steam 36 leaving the sealed container 3 is removed using the sensor 35 of the steam 36 coming out of the container 3. The temperature data is disinfected The waste collected inside the container and the temperature of the steam leaving the container are fed back to the data reception and synchronization unit 57.

After starting the disinfection program with

 the operator presses the "start" button 31, the microwave system begins to carry out the specified stages of disinfection of waste (heating, exposure, cooling).

The control board program 25 has four preset parameters: the temperature of the disinfected waste placed inside the container (T backflow, internal cont.), The temperature of the steam leaving the container (T backflow), the temperature of the end of cooling (T back. final cooling) and the holding time of the container at a given temperature (t ass. exp.).

To carry out the heating step of the sealed container 3, the microcontroller 56 takes data on the current state of the temperature of the disinfected waste placed inside the container (T current waste internal cont.), (Data from thermocouple 5) and the temperature of the output steam (T current output steam ) from the sealed container 3 (data from the sensor 35) and compares them with the set values (T ass. exhaust. internal. and T ass. output steam).

The interrogation of a thermocouple 5 for measuring the temperature of the disinfected waste and a sensor 35 measuring the temperature of the steam leaving the container is carried out 10 times per second.

During the “heating” stage, the disinfected waste begins to emit very unpleasant odors, which are removed from the working chamber 2 with the help of a filtration unit 15 and sent to the ventilation flange 17, in which a second fan 18 is installed, which ensures forced passage of air removed from the working chamber 2 through the coal filter element 19. The carbon filter element 19 provides reliable absorption of very unpleasant odors emerging from the working chamber 2 in the process of disinfection of waste. In this case, the fans 16 and 18 forcibly cool the sealed container 3, however, the cooling of the container is compensated by heating the magnetrons 8 and 9.

If both parameters (the current temperature of the disinfected waste placed inside the container and the current temperature of the steam leaving the container) have not reached the set value, then the microcontroller gives the command to turn on the magnetrons 8 and 9 for heating. The stage of heating the sealed container 3 occurs until at least one of the above parameters (the current temperature of the disinfected waste placed inside the container, or the current temperature of the steam leaving the container) reaches the set value.

When one of the above parameters reaches the set value, the microcontroller 56 proceeds to control the magnetrons 8 and 9 in the holding mode.

When the system is operating in the holding mode, the magnetrons are turned on / off periodically to maintain the set value for the set hold time (t set hold time) of one of the parameters that have reached the set value (set temperature of the disinfected waste placed inside the container or set exit temperature from the steam container). At the same time, the microcontroller 56 compares the duration of the current holding time (t current. Holding time) with a given holding time (t set holding time). If the specified duration of the holding step is not reached, then the microcontroller 56 continues to periodically turn on / off the magnetrons to maintain the set value of one of the parameters that have reached the set value. If the specified duration of the holding phase is reached, then the microcontroller 56 proceeds to the next stage of "cooling", turning off the magnetrons 8 and 9.

At the cooling stage, the microcontroller 56 compares the predetermined cooling temperature (T ass. Cooling) according to one of the adjustable parameters (the reached temperature of the disinfected waste placed inside the container or the reached temperature of the steam leaving the container) with the current cooling temperature (T tech. Cooling) .

The interrogation of a thermocouple 5 for measuring the temperature of the disinfected waste and a sensor 35 measuring the temperature of the steam leaving the container is carried out 10 times per second.

If the compared temperatures do not coincide (T ass. Cooling. <T tech. Cooling), then there is a forced cooling of the sealed container 3 with the help of fans 16 and 18 to a predetermined cooling temperature.

If the compared temperatures are equal (T ass. Cooling. = T tech. Cooling), then the report on the decontamination procedure of the waste is printed on the printer 40, from which the paper (check) 41 comes out, which displays the results of the decontamination of waste in the form of the decontamination duration, disinfection temperature, the date of disinfection and evaluation of the result of disinfection (successful or not), which indicates the completion of the disinfection program.

The inventive microwave waste disinfection system allows for the normal disinfection of medical and biological hazardous and potentially hazardous waste even in the event of an emergency, for example, when the cover 4 of the sealed container 3 is accidentally opened or if there is a crack in the case of the sealed container 3, while the system allows in a fireproof mode, to carry out normally and to complete the disinfection process without interrupting the technological cycle of disinfection frozen out waste.

When depressurization of the sealed container 3 or in case of an accidental accidental removal of the lid 4 of the container, intense evaporation of water from the waste in the sealed container 3 occurs.

In this case, the steam 36 leaving the container enters the working area of the microwave chamber 1 and is removed from there by the built-in fans 16 and 18. As a result of emergency steam 36 entering the working area of the microwave chamber 1, the steam does not reach the sensor 35 for the temperature of the outgoing steam, as a result whereupon the sensor 35 starts to falsely show the low temperature of the steam leaving the container, which is perceived by the system as insufficient heating of the working chamber 1, and the microcontroller 56 should give a command to increase the heating by turning on the magnet thrones 8 and 9. As a result, further work magnetrons 8 and 9, when an emergency happens complete evaporation of water from waste and drying, followed by possible fire.

If you only monitor the temperature of the steam leaving the container (as is the case in the prototype), then when the container is depressurized and there is no temperature control of the disinfected waste placed inside it, the temperature sensor of the steam leaving the container will continue to work normally and falsely sense the container’s heating as insufficient, since when the container is depressurized, the sensor of the steam leaving the container does not receive genuine information about the temperature of the container leaving steam due to a leak in the part of the working zone of the chamber. In this case, the sensor of the steam leaving the container during depressurization of the container reflects its temperature significantly lower than the actual temperature in the container and increases the magnetron power or continues to maintain it at the maximum level to increase the temperature in the container, thereby creating a critical situation of overheating of the container with waste and sharply increasing the probability their ignition and, as a consequence, emergency interruption of the waste disinfection process.

The inventive microwave system allows to exclude the development of the emergency described above and to avoid interruption of the waste disinfection process in case of emergency depressurization of the sealed container 3 due to additional temperature control of the disinfected waste placed inside the container 3, using a thermocouple 5.

When the pressurized container 3 is depressurized in the inventive device, the temperature sensor 35 of the steam leaving the container cannot reach a predetermined temperature (T ass.output steam) due to its leakage into the working chamber, but at the same time, the microcontroller 56 doesn’t malfunction, leading to an increase in the power of magnetrons 8 and 9, because the operation of magnetrons 8 and 9 is additionally controlled by a thermocouple 5 by additionally measuring the temperature of the disinfected waste placed inside a sealed container 3. In this case, since the magnetrons 8 and 9 are controlled in the inventive system when at least one of the controlled parameters (the temperature of the steam leaving the container or the temperature of the disinfected waste placed inside the container) is reached, in case of emergency depressurization of the container, despite that the temperature of the steam leaving the container does not reach the set value, the operation of the magnetrons 8 and 9 is controlled by controlling the temperature of the disinfected waste placed inside When the container.

Upon reaching a predetermined temperature of the disinfected waste placed inside the container (T ass. Waste internal cont. ≤ T current waste internal cont.), Despite the fact that the temperature of the steam leaving the container is lower than the preset temperature (T ass. pair ≥ T current output pair), the microcontroller 56 gives the command to turn off the magnetrons 8 and 9 and go to the next stage “exposure”. Further, the system operates in the normal mode described above.

The operation algorithm of the microwave waste disinfection system with a remote control based on laptop 53 is shown in FIG. 12.

The difference between this algorithm and the algorithm of the system shown in Fig. 11 is that the algorithm has the ability to set

and changes by the operator of the basic parameters of the medical waste disinfection process, namely, the temperature of the disinfected waste placed inside the container, the temperature of the escaping steam, the duration of the disinfection stage and the duration of the cooling stage (“Entering Preset Parameters” block), as well as displaying the main the parameters of the waste disinfection process, namely, the current temperature of the disinfected waste placed inside the container (T current waste, internal cont.) and the current output temperature present from the steam container (T cur. O. steam), and the current exposure time (t tech. time. resists.) (unit display the parameters of the waste decontamination process).

Another difference of the algorithm of the second embodiment of the invention is the possibility of archiving the data of the disinfection process of the waste in the laptop 53 with the possibility of their subsequent output and documenting on any external printer (unit for archiving the parameters of the waste disinfection process).

The inventive microwave waste disinfection system allows, unlike the prototype, in which the process of disinfection of waste is controlled only by measuring an indirect control parameter, the temperature of the steam leaving the container, to switch to a more accurate and safe way to regulate the disinfection process by introducing a direct measurement of the temperature of the disinfected waste , which allows you to create a duplicated security control system and completely eliminate the possible fire of disinfected waste.

In addition, the claimed system allows the organization of duplication of the security control system to prevent the ignition of contaminated waste in a sealed container 3 during emergency depressurization, in contrast to the prototype, in which the fire safety of the system is ensured by the installation of an additional smoke sensor inside the working chamber, indicating that the emergency the process of igniting the disinfected waste has already occurred (US patent No. 6524539, which is an additional patent to the selected prototype )

In addition, by introducing a thermocouple into the system that measures the temperature of the disinfected waste, it became possible to efficiently disinfect complex waste, for example, highly chilled or high-density waste, the heating of which by microwave radiation is uneven and, therefore, problematic.

Claims (5)

1. A system for disinfecting medical and biological hazardous and potentially hazardous wastes using microwave radiation, comprising a microwave chamber equipped with magnetrons and a working chamber, the magnetrons being installed outside the working chamber, and a sealed container having a lid connected to the container by pressure latches with the formation of an internal space for the placement of water-wetted waste to be treated with microwave radiation, while The sealed container has an opening equipped with a fitting with a hose for draining the steam emerging from the sealed container that is generated inside the container during exposure to microwave radiation; outside the working chamber, outside the heating zone of the disinfected waste, there is installed a cooling device for the steam leaving the sealed container and a measuring tool in the form a sensor for measuring the temperature of the steam exiting the sealed container connected to the microprocessor board board designed to evaluate the signal from the measuring tool and control (decrease or increase) the power of the magnetrons depending on the results of the assessment, while the working chamber is equipped with a means for creating uniform irradiation of a sealed container with disinfected waste, characterized in that there is an additional container in the sealed container hole for installing an additional measuring tool that measures the temperature of the disinfected waste in filled in the form of a thermocouple immersed in the disinfected waste to the bottom of the container, connected to a microprocessor control board that simultaneously evaluates two signals from two measuring instruments, namely, evaluating the signal from the measuring means in the form of a sensor for measuring the temperature of the steam leaving the sealed container and evaluating the signal from a measuring tool that measures the temperature of the disinfected waste, while regulating (decreasing or increasing) the power of the magnetro new is carried out according to one of the measured parameters, namely the temperature of the steam leaving the sealed container or the temperature of the disinfected waste, which was the first to reach the value set by the operator. 2. The system for the disinfection of medical and biological hazardous and potentially hazardous wastes using microwave radiation according to claim 1, characterized in that a filter unit is installed on the outside of the microwave chamber opposite the magnetrons, containing a fan that removes air from the working chamber and directs it into the ventilation flange, in which a second fan with a carbon filter element is installed, providing forced passage and absorption of unpleasant odor removed from the slave eyes of the air chamber generated during the disinfection of waste. 3. The disinfection system of medical and biological hazardous and potentially hazardous wastes using microwave radiation according to claim 1, characterized in that the first magnetron is connected through the first waveguide to the upper part of the working chamber, and the second magnetron is connected through the second waveguide to the lower part of the working chamber, and the means for creating uniform exposure of the sealed container with disinfected waste is made in the form of a diffuser of microwave radiation installed at the output of the first and / or and a second waveguide facing the working chamber. 4. The system for the disinfection of medical and biological hazardous and potentially hazardous wastes using microwave radiation according to claim 1, characterized in that the system is additionally equipped with a documenting unit made in the form of a printer integrated in the cooling unit of the steam leaving the sealed container, on which the results of disinfection of waste are displayed in the form of time for the duration of disinfection, temperature of disinfection, the date of disinfection and evaluation of the result of disinfection (successfully Do not). 5. The system for the disinfection of medical and biological hazardous and potentially hazardous wastes using microwave radiation according to claim 1, characterized in that the system is equipped with a remote control based on a laptop with a display connected to the microprocessor control board via a Bluetooth channel, allowing visualization on on-screen display in real time the main parameters of the medical waste disinfection process, namely to display the temperature of the steam leaving the sealed container, t the temperature of the disinfected waste inside the sealed container, as well as allowing you to change standard or set new values for the main parameters of the disinfection process, namely the temperature of the disinfected waste placed inside the container, the temperature of the steam leaving the sealed container, the duration of the disinfection stage and the duration of the waste cooling stage, as well allowing to document and archive data on the medical waste disinfection process.

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