RU2600836C1 - Device for disinfection of medical, biologically dangerous and potentially dangerous wastes by microwave radiation - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to microwave devices, intended for disinfection of medical, biologically dangerous and potentially dangerous wastes. Waste disinfection device comprises microwave chamber, containing operation chamber with container for placement of watered dangerous wastes, wherein at external side of operation chamber top part pressure unit is installed coaxially to hole in container cover with possibility of vertical movement inside operation chamber. In pressure unit on side, facing towards container, groove, forming inner cavity, is made, in immediate vicinity of container cover hole main sensor for measuring temperature of steam, escaping from container, is made, connected with control board. Control board is made with possibility of controlling power of magnetrons in normal operation mode based only on readings of above main sensor for measuring temperature of steam, escaping from container. Power control of magnetrons in emergency mode of device operation occurs only on basis of readings of sensor for measuring temperature of steam, mounted on tube for discharge of steam, escaping from container, outside container.

EFFECT: invention allows to increase reliability of device operation in case of emergency situations and minimize involvement of operator during decontamination of wastes.

1 cl, 8 dwg

Description

The claimed invention relates to microwave devices for the disinfection of medical and biohazardous and potentially hazardous waste, for example used disposable syringes, disposable intravenous infusion systems, glass slides for laboratory tests, sampling instruments for conducting clinical and biological blood tests, as well as various biological environments: blood, urine, blood plasma, hemacons, feces and tissues of organs with preliminary wetting.

The inventive microwave device allows you to transfer hazardous and potentially hazardous medical and biological waste into non-hazardous class waste (household waste) with minimal operator involvement.

The prior art devices for the disinfection of medical, biohazardous and potentially hazardous waste using microwave radiation, for example, patents for the invention RU No. 2480242, USA No. 5.407.641, USA No. 6.524.539, utility model patent RU No. 140769.

In these patents, humidified hazardous and potentially hazardous medical waste is placed in a container with the addition of water, which is placed in a microwave chamber (microwave chamber). Hazardous waste is disinfected by heating the container with microwave radiation, the source of which is magnetrons, the power of which is controlled using the readings of the temperature sensor of the steam leaving the container and / or the temperature sensor of the disinfected waste.

During the operation of these devices, a number of shortcomings were identified related to the low degree of automation of the preparation of the container with hazardous waste for disinfection, which required a lot of time and labor for the operator to prepare the container with waste for disinfection. In addition, the operating experience of such devices showed that the significant involvement of the operator in the preparation of the container with waste for disinfection led to serious errors related to the "human factor", the result of which was the failure of expensive equipment.

During operation of the device according to the patent for invention RU No. 2480242, in which the temperature of disinfection of medical waste inside the container was measured near the bottom and the temperature of the steam leaving the container, which was monitored using a temperature sensor located outside the container on the coil body for cooling and condensation of steam leaving the container, and outside the channel through which steam is removed from the container, it turned out that the operator is experiencing a number of difficulties inconvenience of installing the container into a microwave chamber connected with the fact that the operator has difficulty in installing the temperature sensor for measuring the temperature of the waste as it is immersed in a container filled with waste. At the same time, when installing a sensor for measuring the temperature of the waste, the operator may contact hazardous waste for some time, trying to push the temperature sensor to the bottom of the container through the thickness of the hazardous waste.

In addition, it was found that quite often the operator simply forgets to connect the tube to discharge the steam leaving the container to the fitting on the lid of the container, which leads to the fact that the temperature control sensor of the steam leaving the container is not connected to the medical waste disinfection process control system and the process waste disinfection is carried out without monitoring the temperature of the exhaust steam, which is carried out in order to duplicate the operation of the sensor for measuring the temperature of the waste in the container, in case of failure of this sensor to ensure the safe operation of the waste disinfecting device and the operator in order to exclude the uncontrolled operation of the magnetrons to constantly heat the container with hazardous waste and, as a result, excess steam generation, which is dangerous for the operation of the installation.

A situation may arise in which the sensor immersed in the container will show a low temperature of the waste and give a control signal to continue the operation of the magnetrons to heat the container, while in another part of the container there may be a significant overheating of the waste due to their heterogeneity and, accordingly, different ability absorb microwave radiation. If at the same time, the operator did not connect the steam pipe to the fitting on the lid of the container and thereby disconnected the temperature measuring sensor of the steam leaving the container, there is a possibility of ignition of the waste due to overheating and the absence of duplicate monitoring of the operation of the magnetrons.

In addition, it turned out that the operator, even if he did not forget to connect the fitting on the lid of the container to remove steam, experiences significant difficulties in connecting it due to the lack of free space between the lid of the container and the upper wall of the working chamber of the microwave installation.

In this regard, there was a need to create a reliable device for disinfection of hazardous medical waste, which minimized the participation of the operator in preparing the container and installing it inside the microwave chamber to start the process of disinfection of hazardous medical waste, and duplication of temperature control of steam leaving the container was implemented.

Below are various installation options for temperature sensors for steam leaving the container and / or waste temperature measuring sensors in microwave hazardous waste disinfection units using manual loading and automatic water supply to the container, known from the prior art.

In FIG. 1 “a”, “b”, “c” are diagrams of various options for installing temperature sensors for measuring the temperature of steam leaving a container in microwave hazardous waste disinfection units without using automatic water supply to a medical waste container (manual filling of water into a container), known from prior art that illustrate the evolution of minimizing operator participation in the preparation of a container with hazardous waste for the process of disinfection of waste while increasing the reliability of the mic ovolnovoy decontamination of the waste in general.

In FIG. 1 “a” shows the connection diagram for the temperature sensor of the steam leaving the container in a microwave installation for disinfection of hazardous waste, described in the patent for invention RU No. 2480242 in Fig. 7 of said patent. As seen in FIG. 1 “a”, the container 1 with hazardous waste 2 is closed by a lid 3, in which a temperature measuring sensor 4 of the disinfected waste 2 and a fitting 5 for connecting a tube 6 for removing steam leaving the container 1 are installed.

To improve the reliability of the microwave installation in RU patent No. 2480242, a sensor 7 is installed on the tube 6 outside the container 1 to measure the temperature of the steam leaving the container 1, which has a duplicate function that allows you to regularly complete the disinfection cycle of hazardous waste in case of emergency situations a possible complete failure of the temperature measurement sensor 4 of the disinfected waste 2, or, if during the preparation of the container by the operator, the sensor 4 was at the waste location, super- significantly more time for heating them up to decontamination temperature than the waste disposed in another part of the container, which require minimal time to heat disinfection temperature due to the inhomogeneity of the structure and composition of the waste.

In the event of the described abnormal situations, increased vaporization occurs in the container, which is detected by the sensor 7 to measure the temperature of the steam leaving the container 1, the signal from which is sent to the control unit, which gives a command to reduce power or turn off the magnetrons, thus preventing possible ignition of the waste 2 and the melting and failure of the container 1.

Figure 1 "b" shows the connection diagram of the temperature sensor leaving the container of steam in a microwave installation for the disinfection of hazardous waste, described in US patent No. 5,407,641 in Fig. 13, 14, 15 of the specified patent selected for the prototype. US Pat. No. 5,407,641 attempts to minimize operator involvement in preparing a waste container for disinfection. Moreover, as can be seen in FIG. 1 “b”, the container 1 with hazardous waste 2 is closed by a cover 3. A hole 8 is made in the cover 3, to which the operator manually presses the pressure block 11 using the clamping lever 9, which controls the eccentric cam 10, in which a channel 12 is made, connected to the tube 6 for the removal of steam leaving the container 1. At the same time, a sensor 7 is installed outside the container 1 for measuring the temperature of the steam leaving the container, located on the tube 6 for withdrawing the steam leaving the container 1.

The sensor 7 for measuring the temperature of the steam leaving the container performs the function of the main sensor in this device, according to the readings of which the power of the magnetrons is regulated. However, the presence of only one sensor 7 for measuring the temperature of the steam leaving the container and the absence of duplication of its operation is unsatisfactory from the point of view of the reliability of the device for disinfection of waste, since if the sensor 7 fails, it will not be possible to properly complete the process of disinfection of waste and the process of disinfection of waste becomes uncontrolled and very dangerous.

In addition, the installation of only one sensor 7 for measuring the temperature of the steam leaving the container outside the container 1 on the tube 6 is not satisfactory from the point of view of reliability of controlling the temperature of the steam leaving the container due to the large heat losses that occur when the steam passes from the outlet 8 in the lid 3 of the container 1 to the place where the sensor 7 for measuring the temperature on the tube 6 is located, which greatly complicates the maintenance of the optimal temperature of waste disinfection at 100 ° C inside Conner that, as a consequence, it leads to overheating or underheating and possible fire or decontamination of waste not complete.

In Fig 1 "c" shows the connection diagram of the temperature sensor leaving the container of steam in the inventive microwave installation for disinfection of hazardous waste.

As seen in FIG. 1 “into” the container 1 with hazardous waste 2 is closed by a cover 3. A hole 8 is made in the cover 3, to which the pressing block 11 is pressed automatically using a pneumatic system (not shown), in which from the side facing to the side container 1, a groove 13 is made, forming an internal cavity 14 in the pressure unit 11. In the internal cavity 14 of the pressure unit 11, in the immediate vicinity of the hole 8 in the lid 3 of the container 1, a main temperature sensor 15 is installed for steam leaving the container 1. The readings of the main sensor for measuring the temperature 15 of the steam leaving the container 1 are basic for controlling the power of magnetron operation. In the pressing block 11, a channel 12 is made, connected to a tube 6 for exhausting the steam leaving the container 1. On the tube 6, outside the container 1, a temperature measuring sensor 7 is installed for the steam leaving the container 1 that performs a duplicate function.

Placing the main temperature measurement sensor 15 of the steam leaving the container 1 in the inner cavity 14 of the pressure unit 11 in the immediate vicinity of the hole 8 in the lid 3 allows to increase the reliability of the temperature control of the steam leaving the container due to the absence of heat loss, since when the pressure unit 11 is in close contact to the lid 3, the internal cavity 14 of the pressure unit 11 forms a single volume with the internal volume of the container 1, in which there is a uniform distribution of the steam leaving the container 1.

The installation of the sensor 7 for measuring the temperature of the steam leaving the container 1 on the tube 6 outside the container can improve the reliability of the inventive device in case of emergencies associated with the possible complete failure of the temperature measuring sensor 15 of the steam leaving the container 1 due to fixing by the sensor 7 performing a duplicate function of excessive vaporization in the container 1, the signal from which goes to the control unit, which issues a command to reduce power or turn off the mag Metronome, preventing thus possible fire waste 2, melting and failure of the container 1.

The presence in the inventive device of the clamping unit 11 with an automatic drive allows you to minimize the operator’s participation in the preparation of the container 1 for the process of disinfection of waste, which consists only in manually pouring water into the container 1 with disinfected waste 2 for their preliminary wetting. For the connection of temperature measuring sensors 7 and 15 for the steam leaving the container 1 and the tube 6 for withdrawing the steam leaving the container 1, operator participation is not required.

In FIG. 2 “a”, “b”, “c”, “d” are diagrams of various options for installing temperature sensors for steam leaving the container in microwave hazardous waste disinfection units using automatic water supply to the medical waste container known from the prior art.

In FIG. 2 “a” shows a connection diagram for a temperature sensor of steam leaving a container in a microwave installation for disinfection of hazardous waste described in US Pat. No. 5,407,641 in Fig. 1 (specified patent). As can be seen from FIG. 2 “a”, the container 1 with hazardous waste 2 is closed by a cover 3, in which a temperature measuring sensor 16 is installed, the steam leaving the container 1, nozzle 5 for connecting the tube 6 to exhaust 1 pair leaving the container, and the fitting 17 for connecting the tube 18 for automatic water supply to container 1 with waste 2. In order to prepare this container for operation, the operator is forced to manually install a temperature measuring sensor 16 of steam leaving the container 1, connecting a pipe 6 to divert steam leaving the container 1 to fitting 5 and plugs 18 to the fitting 17 for automatic supply of water to the container 1 with waste 2.

In this design, it does not seem possible to automate the process of preparing container 1 for disinfection of waste and to exclude the operator from the process of preparing container 1 for work, since the operator is forced to manually connect the temperature measurement sensor 16, tubes 6 and 18, respectively, to fittings 5 and 17.

In addition, in this design there is no duplicate sensor leaving the container 1 steam, which reduces the reliability of the device when the failure of the temperature sensor 16 leaving the container 1 pair.

In FIG. Figure 2 “b” shows the connection diagram for the temperature sensor of the steam leaving the container in a microwave installation for disinfection of hazardous waste, described in US Pat. No. 6,524,539 in Fig. 1, Fig. 5 (said patent). As can be seen from FIG. 2 “b”, the container 1 with hazardous waste 2 is closed by a cover 3. A bracket 19 is installed in the cover 3, on the outside of which a temperature measuring sensor 16 is installed for the steam leaving the container 1. The same bracket 19 also serves as a means for attaching the injector 20 to automatically supply water to the container 1. The preparation of this container for disinfection of waste without operator intervention is difficult.

In addition, in this design there is no duplication of the temperature sensor 16 leaving the container 1 steam, which reduces the reliability of the device when this sensor fails.

In FIG. 2 “c” shows the connection diagram of the temperature sensor of the steam leaving the container in the microwave installation for the disinfection of hazardous waste, described in utility patent RU No. 140769 in Fig. 5 (said patent).

As seen in FIG. 2 “c”, the container 1 with hazardous waste 2 is closed by a lid 3, in which a temperature measuring sensor 4 of the disinfected waste 2 and a fitting 5 for connecting a tube 6 for removing steam leaving the container 1 are installed.

To improve the reliability of the microwave installation in the patent for utility model RU No. 140769 on the tube 6 outside the container 1, a sensor 7 is installed to measure the temperature of the steam leaving the container 1, which performs a duplicate function that allows you to regularly complete the disinfection cycle of hazardous waste in case of emergency, associated with either a possible complete failure of the temperature measurement sensor 4 of the disinfected waste 2, or if, during the preparation of the container by the operator, the sensor 4 turned out to be located Wastes that require significantly longer time to heat them to the disinfection temperature than wastes located in another part of the container that require shorter heating times to the disinfection temperature due to the heterogeneity of the structure and composition of the waste.

In the event of the described abnormal situations, increased vaporization occurs in the container, which is detected by the sensor 7 to measure the temperature of the steam leaving the container 1, the signal from which is sent to the control unit, which gives a command to reduce power or turn off the magnetrons, thus preventing possible ignition of the waste 2, as well as the melting and failure of the container 1.

In addition, in the lid 2 of the container 1, a fitting 17 is installed, to which a tube 18 is connected to automatically supply water to the container 1 with waste 2.

In this device, there is duplication of the operation of the temperature measurement sensor 4 of the disinfected waste 2 using the sensor 7 to measure the temperature of the steam leaving the container 1, however, it is impossible to exclude the operator from preparing container 1 for the waste disinfection process 2, since the operator is forced to manually connect the temperature measurement sensor 4 disinfected waste 2, tubes 6 and 18, respectively, to fittings 5 and 17.

In Fig 2 "g" shows the connection diagram of the temperature sensor leaving the container of steam in the inventive microwave installation for the disinfection of hazardous waste with automatic water supply to the container 1.

As seen in FIG. 2 “g”, the container 1 with hazardous waste 2 is closed by a cover 3. In the cover 3, a hole 8 is made, to which the pressure unit 11 is pressed automatically using a pneumatic system (not shown), in which from the side facing to the side container 1, a groove 13 is made, forming an internal cavity 14 in the pressure unit 11. In the internal cavity 14 of the pressure unit 11, in the immediate vicinity of the hole 8 in the lid 3 of the container 1, a main temperature sensor 15 is installed for steam leaving the container 1. The readings of the main sensor for measuring the temperature 15 of the steam leaving the container 1 are basic for controlling the power of magnetron operation. In the pressing block 11, a channel 12 is made, connected to a tube 6 for exhausting the steam leaving the container 1. On the tube 6, outside the container 1, a temperature measuring sensor 7 is installed for the steam leaving the container 1 that performs a duplicate function.

Placing the main temperature measurement sensor 15 of the steam leaving the container 1 in the inner cavity 14 of the pressure unit 11 in the immediate vicinity of the hole 8 in the lid 3 allows to increase the reliability of the temperature control of the steam leaving the container due to the absence of heat loss, since when the pressure unit 11 is in close contact to the lid 3, the internal cavity 14 of the pressure unit 11 forms a single volume with the internal volume of the container 1, in which there is a uniform distribution of the steam leaving the container 1.

The installation of the sensor 7 for measuring the temperature of the steam leaving the container 1, performing a duplicate function, on the tube 6 outside allows to increase the reliability of the inventive device in case of emergency situations associated with the possible complete failure of the temperature measurement sensor 15 coming out of the container 1 steam, the account of the sensor 7 fixing excessive vaporization in the container 1, the signal from which goes to the control unit, which issues a command to reduce power or turn off the magnetrons, p thus preventing the possible ignition of waste 2, the melting and failure of the container 1.

Furthermore, as seen in FIG. 2 "g", in the clamping unit 11 a through channel 21 is made, to which the fitting 17 is connected from the outside, to which a pipe 18 is connected for automatic water supply to the container 1 with waste 2.

The presence of the clamping unit 11 with the automatic drive in the inventive device and the installation of the fitting 17 in the clamping block 11 with the connection of the pipe 18 for automatic water supply to it completely exclude the operator’s participation in preparing the container 1 for the waste disinfection process, since for connecting temperature measurement sensors 7 and 15 for the steam leaving the container 1, the tube 6 for draining the steam leaving the container 1 and the tube 18 for automatic water supply, the operator is not required.

The objective of the invention is to increase the reliability and safety of the claimed device in case of emergency situations associated with the possible complete failure of the main sensor for measuring the temperature of the steam leaving the container, which can lead to possible ignition of the waste, its melting or failure of the container, as well as the complete exclusion of operator participation in the preparation of the container for the waste disinfection process.

The technical result of the claimed invention to solve the problem lies in the installation outside the container on the tube of the steam leaving the container, another sensor for measuring the temperature of the steam leaving the container, which performs the duplicating function of the main sensor for measuring the temperature of the steam leaving the container, as well as in the inventive device a clamping unit mounted coaxially with an opening in the container lid from its outer side, equipped with an automatic drive providing zmozhnost vertical movement up and down the pressing block within the working chamber to the container lid. The clamping unit is equipped with a main sensor for measuring the temperature of the steam leaving the container, a pipe for removing steam leaving the container, and a fitting with a pipe for automatically supplying water to the container. The supply of the claimed device by the clamping unit allows to completely exclude operator’s participation for connecting the main temperature measuring sensor and the temperature measuring sensor of the steam leaving the container, as well as the pipe for removing steam leaving the container and the pipe for automatically supplying water to the container.

The invention is illustrated by the following drawings.

In FIG. 3 "a" is a front view of the inventive device for disinfecting medical, biologically hazardous and potentially hazardous waste using microwave radiation when manually pouring water by the operator into a container with disinfected waste.

In FIG. 3 “b” - frontal view of the clamping unit 11 is shown for automatic supply of water to a container with disinfected waste without operator intervention.

In FIG. 4 - shows a perspective view of the claimed device for disinfection of medical, biologically hazardous and potentially hazardous wastes using microwave radiation, rear view from the left with the rear and left covers of the case removed, as well as the removed control panel cover.

In FIG. 5 - shows a perspective view of the inventive device for the disinfection of medical, biologically hazardous and potentially hazardous wastes using microwave radiation, rear right view with the right housing cover and control panel cover removed (the rear housing cover is installed).

In FIG. 6 - shows the location of the clamping unit 11 with a pneumatic drive before starting the operation of the inventive device.

In FIG. 7 - shows the location of the clamping unit 11 with a pneumatic drive during operation of the inventive device.

In FIG. 8 - shows the electrical control circuit of the claimed device.

The inventive device for the disinfection of medical, biohazardous and potentially hazardous wastes using microwave radiation consists of a microwave chamber 22 with a door 23 containing a working chamber 24, inside which a container 1 with disinfected waste 2 is stationary placed. The container 1 is closed by a lid 3. The lid 3 is fixed to container 1 with clamps 25.

The microwave chamber 22 is equipped with two magnetrons 26 mounted outside the working chamber 24. The magnetrons 26 are connected to a ~ 220V power supply via transformers 27. The device for disinfecting medical, biohazardous, and potentially hazardous wastes using microwave radiation is controlled using a control board 28 installed outside the working chamber 24.

The control board 28 is a printed circuit board on which the STM32F family microcontroller is installed, processing the signal from the main sensor to measure the temperature 15 of the steam leaving the container 1 and issuing control signals to turn magnetrons 26 on / off, start the pneumatic system of the inventive device and start the automatic feed system water into the container 1 (if the device is equipped with an automatic system for supplying water to the container). The regulation of the power of the magnetrons by the control board 28 in the normal mode of operation of the device occurs only according to the readings of the main sensor 15 for measuring the temperature of the steam leaving the container 1. A sensor 7 for measuring the temperature of the steam leaving the container is connected to a control board 28 configured to control the power of the magnetrons 26 based on the readings of this sensor. When adjusting the power of the magnetrons 26 in the emergency mode of operation of the device, the control board 28 uses only the readings of the sensor 7 to measure the temperature of the steam leaving the container.

The main sensor 15 for measuring the temperature of the steam leaving the container, connected to the control board 28, while the control board 28 is configured to control the power of the magnetrons 26 in the normal operation of the device only on the basis of the readings of the main sensor 15 for measuring the temperature of the steam leaving the container, and regulating the power of the magnetrons 26 in an abnormal mode of operation of the device only on the basis of the readings of the sensor 7 for measuring the temperature of the steam leaving the container.

The intake of ambient air into the working chamber 24 is carried out using the duct 29. The fan 30 removes air from the working chamber 24 and directs it through the charcoal filter 31 outside the microwave chamber 22. The charcoal filter 31 provides reliable absorption of very unpleasant odors coming out of the working chamber 24 in the process of disinfection of waste.

A control panel 33 is installed on top of the microwave chamber 22 in the casing 32. A start button 34 is placed on the control panel 33, with which the disinfection process is started, a stop button 35 for emergency interruption of the disinfection process, installation operation indicators 36, screen 37 for display graphic and digital information on the course of the disinfection process, by which the operator can control the process of disinfection of waste. The control panel also has an exit hole 38 for the paper of the printer 39, which is installed inside the casing 32, by which the results of the decontamination process are documented.

The door 23 is equipped on the inside with two latches 40 and a window 41.

A through hole 8 is made in the lid 3 of the container 1. In the upper part of the working chamber 24, a pressing block 11 is installed coaxially with the hole 8 in the lid 3 of the container 1, in which a groove 13 is formed on the side facing the container 1, forming an inner cavity 14 in the pressure block 11. In the inner cavity 14 of the pressure block 11 in the immediate vicinity of the hole 8 in the lid 3 of the container 1, a main temperature sensor 15 is installed for steam leaving the container 1. The readings of the main sensor for measuring the temperature 15 of the steam leaving the container 1 are the main ones for regulating the power of magnetrons 26. The main sensor 15 is a resistance thermometer Type 902190, manufactured by Jumo GmbH & Co., Germany, sold in the Russian Federation since 2008 . In the pressing block 11, a channel 12 is made, connected to a tube 6 for withdrawing the steam emerging from the container 1 that is formed inside the container 1 during exposure to it by microwave radiation. On the tube 6, outside the container 1, a temperature measuring sensor 7 is installed for the steam leaving the container 1 that performs a duplicate function. As a sensor for measuring temperature 7 for the steam leaving the container 1, the precision IC of the temperature transducer AD592ANZ, manufactured by Analog Devices, USA, sold in the Russian Federation since 2010, is used. Outside the working chamber 24, outside the heating zone of the disinfected waste 2, a coil 42 is attached to the pipe 6 for exhausting the steam leaving the container 1 to cool the steam removed from the container 1, which is collected in the form of condensate in a glass 43. A fan 44 is used to cool the coil 42.

If there is an automatic supply of water to the container 1 for humidification of waste 2 without operator intervention, an additional through channel 21 is made in the pressure unit 11, in which a fitting 17 is installed at one end for automatically supplying water to the container 1. The fitting 17 passes through the upper wall of the working chamber 24 and the second end is connected to a flexible tube 18 for automatically supplying water to the container 1, which, in turn, is connected to a stationary water supply system through an automatic system for supplying water to the container 1, described example, in the patent for utility model RU No. 140769 (see Fig. 3 "b").

The clamping unit 11 has the ability to vertically move up and down inside the working chamber 24 from its upper wall to the lid 3 of the container 1, which is provided using the clamping mechanism, made in the form of a pneumatic assembly, including a compressor 45, pneumatically connected through a system of tubes 46 with a pressure switch 47 and a pneumatic switch 48 having one input “a” and two outputs “b” and “c”. The input "a" of the pneumatic switch 48 is pneumatically connected to the compressor 45, and the outputs "b" and "c" using tubes 49 and 50, respectively, are pneumatically connected to the inputs "g" and "d" of the pneumatic cylinder 51 having a stem 52, mechanically rigidly connected with a cap 53 using a screw 54 and configured to vertically move up and down under the action of the air pumped by the compressor 45 together with the clamping unit 11. In the cap 53 from the side facing the container 1, with a press fit, the clamping block 11 is installed.

The pressure unit 11 is provided with a cap 53, which is rigidly connected to the pressure unit 11 on one side and connected to the pressure mechanism on the other hand.

As compressor 45, an air compressor TM40-E / F is used, manufactured by Topsflo, China, sold in the Russian Federation since 2014.

As a pressure switch 47, a pressure switch SK-3A of 1-5 bar is used, manufactured by Yaoda, China, implemented in the Russian Federation since 2012.

As a pneumatic switch 48, an electromagnetic air distributor V5221E2-08, manufactured by EMC, China, has been used in the Russian Federation since 2013.

As the pneumatic cylinder 51, the pneumatic cylinder SD32 * 30, manufactured by EMC, China, has been used in the Russian Federation since 2013.

In the clamping unit 11, from the side facing the roof 3 of the container 1, a groove 13 and a sample 55 are made in which a sealing ring 56 is installed. The diameter of the groove 13 is larger than the diameter of the hole 8 in the cover 3 of the container 1.

On the right side of the microwave chamber, an “on” button 57 of the inventive device is installed at the bottom, and an electromechanical relay 58 is installed next to the control board 28, electrically connected to the control board 28 and the pneumatic switch 48, as well as a power supply 59. A cord is located on the rear panel of the inventive device power supply 60.

The inventive device operates as follows. The device using the power cord 60 is connected to an AC voltage ~ 220V. The operator turns on the device by pressing the "on" button 57, while the voltage ~ 220V is supplied to the compressor 45 and to the power supply 59. A pressure switch 47 is connected in series with the compressor 45. The power supply 59 converts the alternating voltage ~ 220V into two types of direct voltage = 24V and = 12V. A constant voltage = 12V is supplied to the control board 28 and an electromechanical relay 58, and a constant voltage = 24V is supplied to a graphic and digital information display on the progress of the disinfection process, by which the operator can control the process of disinfecting waste 37, and the printer 39 (Fig. 8 ) The control board 28 can provide a control signal - control voltage (Ucont.) To the electromechanical relay 58, while the contacts of the electromechanical relay 58 are closed, and the supply voltage = 12V is supplied to the pneumatic switch 48. If there is no control signal from the control board 28, the contacts of the electromechanical relay open, and the supply voltage = 12V is not supplied to the pneumatic switch 48.

The automatic preparation of the device for work begins. The compressor 45 begins to pump outside air into the inside of the pneumatic system, while through the system of tubes 46 air is supplied to the pressure switch 47 and to the input “a” of the pneumatic switch 48. The air supplied to the input “a” of the pneumatic switch 48 in the absence of a control signal from the control board 28 (supply voltage = 12V is not supplied to the pneumatic switch 48), then goes to its output "in" and through the tube 50 then goes to the input "d" of the pneumatic cylinder 51. The air entering the pneumatic cylinder 51 begins to push to 52, and it begins to rise up to the stop, while the pressure block 11 rises up, not reaching the upper inner wall of the working chamber 24, approximately 3-5 mm, and excess air from the pneumatic cylinder 51 through the inlet “g” through the tube 49 enters the output "b" of the pneumatic switch 48, where it is discharged into the atmosphere. Thus, the clamping unit 11 occupies the working position until the operator installs the container 1 in the working chamber 24.

The working pressure in the pneumatic system of the inventive device is regulated using a pressure switch 47, tuned to a working pressure of 1 atm. When the set pressure in the pneumatic system of the device is 1 atm. the pressure switch 47 is triggered, while the power supply circuit of the compressor 45 opens, and the compressor 45 stops working and pumps air into the pneumatic system. Pressure switch 47 allows you to automatically maintain a given operating pressure of 1 ATM. throughout the work until the device is disconnected from the power supply ~ 220V.

The operator places the hazardous waste 2 in container 1 and moistens it (in the absence of automatic water supply to container 1), adding about 3 liters of water to container 1. Then the operator closes the container 1 with hazardous waste 2 with a lid 3 and fixes it with clamps 25. The operator places the closed container 1 inside the working chamber 24, closes the door 23 of the microwave chamber 22 and presses the "start" button 34, starting the waste disinfection program.

In this case, the control board 28 supplies a control signal to the electromechanical relay 58, while the contacts of the electromechanical relay 58 are closed, and the supply voltage = 12V is supplied to the pneumatic switch 48.

At the same time, inside the pneumatic switch 48, the air supply channels are switched to the pneumatic cylinder 51.

The air received at the input "a" of the pneumatic switch 48, begins to flow to its output "b" and through the tube 49 then enters the input "g" of the pneumatic cylinder 51, creating excessive pressure in it. The rod 52 begins to fall down to the stop of the clamping unit 11 to the cover 3 of the container 1 with a clamping pressure of 1 atm., And excess air from the pneumatic cylinder 51 through the inlet “e” through the tube 50 enters the outlet “c” of the pneumatic switch 48, where it is reset to the atmosphere. Thus, the clamping unit 11 occupies the working position to start the process of disinfection of waste, and the main temperature measurement sensor 15 leaving the container 1, the pair is located opposite in the immediate vicinity of the hole 8 in the lid 3 of the container 1.

After the clamping unit 11 occupies the working position to start the waste disinfection process, the control board 28 supplies the supply voltage (U _pit ) ~ 220 V to the transformers 27, turns on the magnetrons 26 and the waste disinfection process begins, similar to that described in RU patent No. 2480242. At the same time, the control of the process of disinfecting hazardous waste and the control of magnetrons 26 is carried out on the basis of the readings of the main temperature measuring sensor 15 leaving the container 1 steam, and the readings of the sensor 7 for measuring the temperature of the steam leaving the container 1, performing a duplicate function, begin to be used to monitor the disinfection process hazardous waste and control of magnetrons 26 only in the event of an emergency related to the failure of the main temperature sensor 15 1 steam leaving the container.

Upon completion of the waste disinfection process, a message appears on the screen 37 for the operator about the end of the waste disinfection process and a receipt is printed on the printer 39 documenting the main parameters of the waste disinfection process. At the same time, the control board 28 removes the control signal from the electromechanical relay 58, its contacts open, and the supply voltage = 12V is not supplied to the pneumatic switch 48.

In the absence of a control signal from the control board 28 inside the pneumatic switch 48, the air supply channels to the pneumatic cylinder 51 are switched.

The air entering the input “a” of the pneumatic switch 48 then goes to its output “b” and through the tube 50 then goes to the input “d” of the pneumatic cylinder 51. The air entering the pneumatic cylinder 51 begins to push the rod 52, and it starts to rise up to stop, while the clamping unit 11 rises up, not reaching the upper inner wall of the working chamber 24, approximately 3-5 mm, and excess air from the pneumatic cylinder 51 through the inlet “g” through the tube 49 enters the outlet “b” of the pneumatic switch 48, where discharged into the atmosphere. Thus, the clamping unit 11 occupies the initial position that it occupied before the operator installed container 1 in the working chamber 24 of the container 1. Now the operator can remove the container 1 with disinfected waste from the working chamber 24 and send the waste for subsequent disposal.

The following is a description of the operation of the inventive device with automatic water supply to the container 1 for moistening hazardous waste 2 without operator intervention.

Before starting work with the device, the operator must make sure that the claimed device is connected to the stationary water supply system as described in the patent for utility model RU No. 140769, and the water supply tap from the stationary water supply system to the claimed device is open.

The device using the power cord 60 is connected to an AC voltage ~ 220V. The operator turns on the device by pressing the "on" button 57, while the voltage ~ 220V is supplied to the compressor 45 and to the power supply 59. A pressure switch 47 is electrically connected to the compressor 45. The power supply 59 converts the alternating voltage ~ 220V into two types of direct voltage = 24V and = 12V. A constant voltage = 12V is supplied to the control board 28 and an electromechanical relay 58, and a constant voltage = 24V is supplied to a graphic and digital information display on the progress of the disinfection process, by which the operator can control the process of disinfecting waste 37, and the printer 39 (Fig. 8 ) The control board 28 can provide a control signal to the electromechanical relay 58, while the contacts of the electromechanical relay 58 are closed, and the supply voltage = 12V is supplied to the pneumatic switch 48. If there is no control signal from the control board 28, the contacts of the electromechanical relay are open and the supply voltage = 12V not supplied to pneumatic switch 48.

The automatic preparation of the device for work begins. The compressor 45 begins to pump outside air into the inside of the pneumatic system, while through the system of tubes 46 air is supplied to the pressure switch 47 and to the input “a” of the pneumatic switch 48. The air supplied to the input “a” of the pneumatic switch 48 in the absence of a control signal from the control board 28 (supply voltage = 12V is not supplied to the pneumatic switch 48), then goes to its output "in" and through the tube 50 then goes to the input "d" of the pneumatic cylinder 51. The air entering the pneumatic cylinder 51 begins to push to 52, and it begins to rise up against the stop, the clamping unit 11 together with the nozzle 17 automatically supplying water to the container 1 connected to a flexible tube 18, rise upwards. In this case, the pressing unit 11 does not reach the upper inner wall of the working chamber 24 of approximately 3-5 mm, and excess air from the pneumatic cylinder 51 through the inlet “g” through the tube 49 enters the outlet “b” of the pneumatic switch 48, where it is discharged into the atmosphere. Thus, the clamping unit 11 occupies the working position until the operator installs the container 1 in the working chamber 24.

The working pressure in the pneumatic system of the inventive device is regulated using a pressure switch 47, tuned to a working pressure of 1 atm. When the set pressure in the pneumatic system of the device is 1 atm. the pressure switch 47 is triggered, while the power supply circuit of the compressor 45 opens, and the compressor 45 stops working and pumps air into the pneumatic system. Pressure switch 47 allows you to automatically maintain a given operating pressure of 1 ATM. throughout the work until the device is disconnected from the power supply ~ 220V.

The operator places the hazardous waste 2 in container 1, closes the container 1 with hazardous waste 2 with a lid 3 and fixes it with clamps 25 and puts the closed container 1 inside the working chamber 24, then closes the door 23 of the microwave chamber 22 and presses the "start" button 34, launching the program disinfection of waste.

In this case, the control board 28 supplies a control signal to the electromechanical relay 58, while the contacts of the electromechanical relay 58 are closed, and the supply voltage = 12V is supplied to the pneumatic switch 48.

At the same time, inside the pneumatic switch 48, the air supply channels are switched to the pneumatic cylinder 51.

The air received at the input "a" of the pneumatic switch 48, begins to flow to its output "b" and through the tube 49 then enters the input "g" of the pneumatic cylinder 51, creating excessive pressure in it. The rod 52 begins to fall down to the stop of the clamping unit 11 to the cover 3 of the container 1 with a clamping pressure of 1 atm., And excess air from the pneumatic cylinder 51 through the inlet “e” through the tube 50 enters the outlet “c” of the pneumatic switch 48, where it is reset to the atmosphere. Thus, the clamping unit 11 occupies the working position to start the process of disinfection of waste, and the main temperature measurement sensor 15 leaving the container 1, the pair is located opposite in the immediate vicinity of the hole 8 in the lid 3 of the container 1.

After the clamping unit 11 occupies the working position to start the waste disinfection process, the control board 28 gives a control signal to an automatic water supply device (not shown), for example, such as described in utility model patent RU No. 140769, and water starts to flow automatically without operator intervention into container 1 with hazardous waste 2 to moisten it. Approximately three liters of water flows into container 1 with a volume of 30 liters.

Then, the control board 28 supplies a voltage of ~ 220 V to the transformers 27 and turns on the magnetrons 26 and the process of disinfection of waste begins, similar to that described in patent RU No. 2480242. At the same time, the control of the process of disinfecting hazardous waste and the control of magnetrons 26 is carried out on the basis of the readings of the main temperature measuring sensor 15 leaving the container 1 steam, and the readings of the sensor 7 for measuring the temperature of the steam leaving the container 1, performing a duplicating function, are used to monitor the disinfection hazardous waste and control of magnetrons 26 only in the event of an emergency related to the failure of the main temperature sensor 15 1 steam leaving the container.

Upon completion of the waste disinfection process, a message appears on the screen 37 for the operator about the end of the waste disinfection process and a receipt is printed on the printer 39 documenting the main parameters of the waste disinfection process. At the same time, the control board 28 removes the control signal from the electromechanical relay 58, its contacts open, and the supply voltage = 12V is not supplied to the pneumatic switch 48.

In the absence of a control signal from the control board 28 inside the pneumatic switch 48, the air supply channels to the pneumatic cylinder 51 are switched.

The air entering the input “a” of the pneumatic switch 48 then goes to its output “b” and through the tube 50 then goes to the input “d” of the pneumatic cylinder 51. The air entering the pneumatic cylinder 51 begins to push the rod 52, and it starts to rise up to stop, while the clamping unit 11 together with the fitting 17 of the automatic water supply to the container 1 connected to the flexible tube 18, rise up. The pressure unit 11 does not reach the upper inner wall of the working chamber 24 of approximately 3-5 mm, and the excess air from the pneumatic cylinder 51 through the inlet “g” through the tube 49 enters the outlet “b” of the pneumatic switch 48, where it is discharged into the atmosphere. Thus, the clamping unit 11 occupies the initial position that it occupied before the operator installed container 1 in the working chamber 24 of the container 1. Now the operator can remove the container 1 with disinfected waste from the working chamber 24 and send the waste for subsequent disposal.

Thus, the claimed device is a safe and convenient device for the operator to disinfect medical waste and will be widely used in modern hospitals, hospitals, clinics and other medical institutions.

Claims (2)

1. A device for disinfecting medical, biologically 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 container having a lid connected to the container by clamps is placed inside the working chamber with the formation of an internal space for the placement of hazardous waste wetted with water to be treated with microwave radiation, while in the upper part of the working a pressure unit is mounted coaxially with the hole in the container lid on the outside of the container, which has the ability to vertically move up and down inside the working chamber to the container lid using the pressure mechanism, a channel is connected in the pressure block to the pipe to exhaust the steam generated inside the container container during exposure to it by microwave radiation, a temperature measuring sensor is installed on the tube to remove the steam leaving the container outside the container steam from the container, outside the working chamber outside the zone of heating of the disinfected waste, a coil is attached to the pipe for discharging the steam leaving the container to cool the steam discharged from the container, while the sensor for measuring the temperature of the steam leaving the container is connected to a control board made with the ability to control power magnetrons based on the readings of this sensor, characterized in that a groove is formed in the clamping block from the side facing the container, forming an inner in which, in the immediate vicinity of the hole in the container lid, a main sensor is installed for measuring the temperature of the steam leaving the container connected to the control board, the control board being configured to control magnetron power in the normal operation of the device only on the basis of the readings of the main sensor for measuring the temperature of the steam leaving the container and regulating the power of the magnetrons in the emergency mode of operation of the device only on the basis of the readings of the sensor for measuring I is the temperature of the steam leaving the container, while the pressure unit is equipped with a cap, which is rigidly connected to the pressure unit on the one hand and connected to the pressure mechanism on the other hand, made in the form of a pneumatic unit, which includes a compressor pneumatically connected using a tube system with a pressure switch and a pneumatic switch having one input "a" and two outputs "b" and "c", the input "a" of the pneumatic switch is pneumatically connected to the compressor, and the outputs "b" and "c" using tubes, respectively,pneumatically connected to the inlets “g” and “d” of the pneumatic cylinder, the pneumatic cylinder has a rod mechanically rigidly connected to the cap and configured to vertically move up and down under the action of the air pumped by the compressor together with the pressure unit. 2. The device according to p. 1, characterized in that the clamping block has a through channel, to which a fitting is connected externally connected to a pipe for automatically supplying water to a container with hazardous waste.

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