RU152576U1 - DEVICE FOR THERMAL DISINFECTION AND DESTRUCTION OF MEDICAL WASTE - Google Patents

Abstract

1. Apparatus for thermal disinfection and destruction of medical waste, having a sealed heat treatment chamber equipped with a sealed cover, between the external and internal side coaxial walls of the body of the heat chamber placed electric heating elements distributed along the wall height, characterized in that the heat treatment chamber is equipped with an air circulation system having closed loop, the supply pipes of which are connected to the bottom of the heat chamber body and connected to the air distributor, in the form of an axial perforated tube, and the suction nozzles of the air circulation system are connected to the upper part of the heat chamber body and are connected via external air ducts to ventilation pumps, while the upper part of the body forms a gas collection chamber and a gas outlet pipe is connected to it in the filtration system, equipped with solenoid valve. 2. The apparatus according to claim 1, characterized in that the electric heating elements are made flexible and form a cylindrical spiral distributed over the height of the wall of the heat chamber casing. The apparatus of paragraphs. 1 and 2, characterized in that the inner walls of the heat chamber are perforated and have a non-stick coating.

Description

The utility model relates to the field of medical technology, namely to facilities for the disposal of medical waste, mainly class B (epidemiologically hazardous waste) and C (extremely epidemiologically hazardous waste), according to the classification SanPiN 2.1.7.2790-10 [SanPiN 2.1.7.2790-10 “Sanitary and epidemiological requirements for the management of medical waste”]. The inventive device can be used in medical institutions, hospitals, epidemiological laboratories, pharmacies, research and medical institutions and other organizations that generate medical waste class B and C. Its purpose is the disinfection and recycling of potentially infected waste, such as sharp and sharp objects that have contact with the blood of a sick person (used disposable tools - solution transfusion systems, syringes, scalpels, probes, catheters, intu bation tubes, etc.), glass, plastic, waste dressings, sanitary pads, medical staff clothing, diapers, etc.

In the context of this application, the term “destruction” means “transformation of the structure of the treated waste, leading to a change in their appearance to an extent that excludes the possibility of their reuse”.

Numerous devices are known that allow disinfection of medical waste with the simultaneous destruction of processed products and materials.

A device for thermal sterilization of infected waste [patent RU No. 61560, publ. 03/10/2007], containing a sealed thermally insulated treatment chamber, inside of which there are grinding means made in the form of rotating knives, and a heating source - heating elements located in the lower part of the processing chamber and providing a temperature inside the chamber of 250 ° C. The device also includes a system for creating an atmosphere that does not support the oxidation of processed products, and, accordingly, is designed to suppress the ignition of waste inside the chamber. The knife system crushes the waste to a dusty state and during the grinding and mixing process the processed waste is heated throughout its entire depth, thereby sterilizing the infected waste. The main disadvantage of this design is its complexity, the presence of knives that quickly wear out during intensive operation, baking of polymer waste to the walls of the chamber, and the need to use additional means to prevent ignition of the dusty mass formed during processing.

Known Integrated installation for the disposal of solid medical waste [patent RU No. 108819, publ. 03/10/2007]. The installation includes a device for disinfecting and sterilizing waste, made in the form of a container containing a working chamber, in which waste is sterilized with saturated steam in a vacuum, and also has a device for destructuring waste, made in the form of a pressing machine, the output of which is waste receive in the form of briquettes. The disadvantage of the design is its complexity and energy intensity, as well as the need for overloading the processed waste from one technological unit to another.

In the above analogs and other known devices [patents RU No., No. 83415, 96507, 100403, 140164] waste destruction is carried out mechanically.

A device for the disposal of medical waste [patent RU 2430798, publ. 10.10.2011], taken as a prototype in which the destruction of solid medical waste is carried out by the method of temperature exposure. The device comprises a processing chamber made in the form of a cylindrical melting vessel with a lid mounted on a base plate having a hole in the center. The tank has a spherical lower part with an outlet gate exiting through an opening in the mounting plate, and means for thermal impact on the waste in the form of heating elements placed between the outer side surface of the tank and the casing. Heating elements are insulated from the casing with heat-insulating material from asbestos sheets and heat-insulating material from mineral wool. Heating elements are located in three groups in height. The sprue has an additional heater in the upper part, and a gate located under the base plate in the lower part. A device for transporting recycled waste is made in the form of a trolley with molds mounted on it for pouring molten mass. The prototype does not require prior grinding of recyclable materials. However, for its successful operation, preliminary sorting of medical waste is necessary, because the device is intended for processing materials whose melting temperature does not exceed 200 ° C. The presence of glass, polyamides, polyester and other materials among the waste materials, the melting temperature of which is higher than 200 ° C, can lead to blocking of the gate and the device getting out of working condition, and pushing the melt is a dangerous process. Polymer waste is baked to the walls of the chamber, and after each cycle, the walls need to be cleaned. Another disadvantage of the device is the need for repeatedly reloading the chamber during the processing cycle, that is, opening the lid of the chamber and lowering an additional batch into the volume inside which the melt is located, which carries the risk of burns to personnel serving the device, as well as the release of hot vapors into the room. The lack of a system for the removal and filtration of gases released during the melting of waste is also a disadvantage of the prototype device, because makes the process environmentally unsafe. In addition, the processing process is very energy intensive, as the full cycle is 5-6 hours.

It should also be noted a general drawback inherent in the analogues described above: when the chamber is loaded heavily with medical waste, there is a sharp decrease in the amount of disinfectant that can penetrate the loading center, which leads to a significant decrease in the efficiency of the disinfection process.

The utility model is based on the task of eliminating these shortcomings and creating an apparatus for thermal disinfection and destruction of medical waste class B and C, without the use of mechanical methods of destruction. The technical result achieved is a decrease in the energy intensity of the apparatus in the absence of the need for preliminary sorting of medical waste according to the criterion of the melting temperature of the material (“universality”).

The problem is solved by changing the design.

The apparatus for thermal disinfection and destruction of medical waste incorporates an airtight recycling heat chamber equipped with an airtight lid. Between the external and internal lateral coaxial walls of the heat chamber housing, electric heating elements are distributed over the wall height. It differs from the prototype in that the processing heat chamber is equipped with an air circulation system having a closed loop. The supply pipes of the air circulation system are connected to the bottom of the heat chamber body and are connected to the air distributor, which is made in the form of an axial perforated tube. The suction nozzles of the air circulation system are connected to the upper part of the heat chamber housing, and are connected via external air ducts to the ventilation pumps. The upper part of the housing forms a chamber for collecting gases and is connected to it by a pipe for the exit of gases into the filtration system, equipped with an electromagnetic valve.

In a preferred embodiment, the electric heating elements are made flexible (flexible electric heaters are used), they form a cylindrical spiral distributed over the height of the wall of the heat chamber body. Genes can be distributed in another way, for example, in the form of zigzags along the generatrix of the cylindrical surface of the body, rectangular meanders forming a closed cylindrical ring. It is possible to use tubular electric heaters (heating elements), but this will lead to an increase in the dimensions of the installation.

The inner walls of the heat chamber may have perforation, which increases the heat transfer of the genes. On the walls inside the heat chamber can be applied non-stick coating - Teflon or silicone.

In order to better demonstrate the distinctive features of the utility model, as an example, not having any restrictive nature, the preferred embodiment is described below.

An example implementation is illustrated by the Figures of the drawings, in which: FIG. 1 is a schematic illustration of an installation which includes an apparatus for thermal disinfection and destruction of medical waste; FIG. 2 - the claimed device.

A device 2 for thermal disinfection and destruction of medical waste (hereinafter referred to as the device), a control unit 3, and a filtration system unit 4 are mounted on a common platform 1 of the installation.

The apparatus has a sealed cover 5. The housing has external and internal side walls 6 and 7, respectively, located coaxially, and which are the walls of the heat chamber 8. Between the walls 6 and 7 are placed flexible electric heating elements 9 (GENs), forming a cylindrical spiral, the turns of which are evenly distributed over the height of the wall 7. The bottom of the outer wall of the heat chamber is made deaf (does not have a drain hole). The inner wall 7 has a perforation and a Teflon coating is applied to its inner surface. The genes are separated from the wall 6 by a layer of thermal insulation (not shown in Fig. 2).

The heat chamber 8 is equipped with an air circulation system having a closed loop. The supply pipes 10 of the air circulation system are located in the bottom of the heat chamber. They pass in the gap between the outer and inner bottoms and are connected to the air distributor 11. The air distributor 11 is made in the form of an axial (located along the geometric axis of the housing) tube, the walls of which are perforated. The suction nozzles 12 of the air circulation system are connected to the upper part of the heat chamber 8, and are connected by external (located outside the housing) ducts 13 to the ventilation pumps 14, which pump air into the supply pipes 10. The upper part of the housing forms a chamber 15 for collecting gases and a pipe is connected to it gas outlet to the filtration system. An electromagnetic valve 16 is installed on the nozzle, opening / closing the access of gases to the block 4 of the filtration system. The valve 16 is designed in such a way that draws air from the environment, which leads to cooling of the gases entering the block 4.

A smoke filter 17 is located inside the block 4 of the filtration system and a carbon filter 18 is installed sequentially downstream of it. A pump 19 of the filtration system is located behind the carbon filter. The cleaned air flows out of the filtration system through the outlet 20. The control unit 3 ensures that the pumps 14 and 19, the valve 16 are turned on, and controls the switching modes of the generators.

Installation works as follows.

Class B and C medical waste, in accordance with the requirements of SanPiN, previously collected in one-time packaging (bags, containers), are placed in heat-resistant bags 21, which are closed with screeds, loaded into the heat chamber 8. In some cases, special loading baskets can be additionally used, and in heat-resistant bags can be placed filler capable of adsorbing liquid medical waste and translate them into a gel state. After tightly closing the lid 5 from the control unit 3, the unit is turned on (power-on generators are turned on) and the internal volume of the heat chamber with the placed waste is heated to a temperature of 200 ° C, which is reflected on the display of the control unit 3. The air circulation system is turned on and the pumps 14 supply air, which extends along the height and volume of the chamber, exiting through the openings of the air distributor 11 (axial perforated tube). In the upper part of the heat chamber 8, heated air is taken into the external air ducts and again fed into the heat chamber 8. This allows you to quickly and evenly heat waste packages throughout the volume of the heat chamber 8. The waste is kept in the heat chamber at a temperature of 200 ° C for 30 minutes, the mode is controlled and It is supported by a control system, which ensures the reliability of the disinfection process. Then there is a process of cooling and filtering the gases formed as a result of thermal exposure. On command from the control unit, the generators 9 are turned off, the fans 14 continue to work, the electromagnetic valve 16 opens and the gases accumulated in the chamber 15 are pumped out by the pump 19 to the filtration system unit 4, where a two-stage cleaning system passes, during which even the smell of exhaust gases is removed. Upon completion of the exhaust gas removal and purification, heat-resistant bags with medical waste are manually unloaded.

During the heat treatment, medical waste is disinfected. Studies have shown that the disinfection efficiency, characterized by the total microbial number (TBC) after the treatment cycle does not exceed 10.

In addition, in the process of thermal exposure, physical modification and a very significant decrease in volume (by approximately 20%) and transformation of the form of the processed waste occur. Some of the materials are smelted, turning the processed waste into a shapeless, sintered mass, which excludes their reuse. Using the installation leads to the possibility of further treatment of treated medical waste of class B and C in conjunction with medical waste of class A, which allows them to be disposed of in solid domestic waste landfills.

The duration of the waste recycling cycle, taking into account the loading and unloading times, does not exceed 1.2 hours. With a maximum load of the working chamber of 60 kg, the developed industrial unit is capable of processing 400 kg of medical waste with an 8-hour working day. This capacity is enough to dispose of all class B and C wastes for a 350 hospital bed.

Thus, the claimed device produces an effective disinfection of medical waste of class B and C and does not require prior grinding of the processed materials. The presence of a closed system of circulation of heated air, with an air distributor located along the axis of the chamber, allows you to quickly and evenly heat waste packages throughout the volume of the heat chamber. Since the destruction is not accompanied by a complete melting of the waste, the installation has low energy intensity at high productivity. Disposal is carried out without prior sorting of medical waste according to the criterion of the melting temperature of the material, and thus is universal. The presence of a gas filtration system improves environmental friendliness and safety for personnel. The installation is convenient in operation and maintenance, compact, easily transported, because located on a mobile platform.

The results of laboratory studies evaluating the effectiveness of the sterilizer using test microorganisms Mycobacterium tuberculosis, Candida albicans, Bacillus cereus, Klebsiella pneumoniae, Pseudomonas aeruginosa, hepatitis C virus indicate the destruction of 100,000% of the test cultures of microorganisms in all modes.

Claims (3)

1. Apparatus for thermal disinfection and destruction of medical waste, having a sealed heat treatment chamber equipped with a sealed cover, between the external and internal side coaxial walls of the body of the heat chamber placed electric heating elements distributed along the wall height, characterized in that the heat treatment chamber is equipped with an air circulation system having closed loop, the supply pipes of which are connected to the bottom of the heat chamber body and connected to the air distributor, in the form of an axial perforated tube, and the suction nozzles of the air circulation system are connected to the upper part of the heat chamber housing and are connected via external air ducts to ventilation pumps, while the upper part of the housing forms a gas collection chamber and a gas outlet pipe is connected to it in the filtration system solenoid valve. 2. The apparatus according to claim 1, characterized in that the electric heating elements are flexible and form a cylindrical spiral distributed over the height of the wall of the heat chamber housing. 3. The apparatus according to paragraphs. 1 and 2, characterized in that the inner walls of the heat chamber are perforated and have a non-stick coating.

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