KR102629230B1 - Mobile medical waste disposal system and method - Google Patents

Abstract

It relates to a mobile medical waste disposal system and method capable of sterilizing and pulverizing medical waste in a mobile manner in response to large-scale infectious disease outbreaks, including a supply unit for supplying medical waste to be processed, and pulverization for pulverizing medical waste supplied from the supply unit. a unit, a deodorizing unit that performs a deodorizing treatment on the medical waste pulverized by the pulverizing unit, a sterilization unit that performs a sterilization process on the medical waste pulverized by the pulverizing unit, and medical waste sterilized in the sterilization unit. By providing a configuration that includes a compression unit that compresses and a packaging unit that packages the medical waste that is compressed and discharged from the compression unit to be treated as general waste, it can be sterilized on its own in a place such as a quarantine facility for people at risk of infection. .

Description

Mobile medical waste disposal system and method}

The present invention relates to a mobile medical waste disposal system and method that can sterilize and pulverize medical waste in a mobile manner in response to large-scale infectious disease outbreaks. In particular, it is mounted on a mobile vehicle to continuously process medical waste and convert it into general waste. It relates to a mobile medical waste disposal system and method that can be mounted on a vehicle and moved, adds sterilization and deodorization functions during the treatment of medical waste, and can detect the sterilization state inside the sterilization chamber.

Medical waste is a type of waste discharged from health and medical institutions, animal hospitals, testing and inspection institutions, etc., which requires special management for health and environmental protection, including waste that is at risk of serious harm such as infection to the human body, accumulations such as human tissue, and carcasses of laboratory animals. It is a waste that is recognized as being waste.

Such medical waste includes, for example, cotton wool, bandages, gauze, disposable syringes, and infusion sets. These wastes may be contaminated with blood, body fluids, excrement, and fluids, and may be prone to secondary infections, etc. Due to this problem, it is separated from general waste and treated under strict management.

The most common way to dispose of medical waste is incineration. It is still the most widely used method to this day, and in Korea, most medical waste is disposed of through incineration. Generally, an incinerator is composed of an incinerator to burn medical waste, a dust collector to purify exhaust gas generated during combustion, and a heat exchanger to cool the exhaust gas.

However, many problems have been pointed out with the incineration method. In other words, it is known that when medical waste is incinerated, harmful components are contained in the exhaust gas, causing serious environmental pollution. In addition, since incineration facilities are far away from medical waste sources such as hospitals, long-distance transportation of medical waste is inevitable, as secondary infection or contamination may occur during the transportation process. Additionally, since incineration facilities require sufficient land and are one of the hazardous facilities, it is difficult to locate them close to waste generators such as hospitals.

Meanwhile, the Ministry of Environment has introduced 7,517 tons of COVID-19-related medical waste generated from hospitals, living treatment centers, and temporary facilities in the year since the first confirmed COVID-19 case in Korea occurred on January 20, 2020, under the 'same-day transportation and same-day transportation system', which is more stringent than the 'Waste Management Act'. The entire amount is being disposed of on the basis of ‘incineration’. In other words, according to the existing Waste Management Act, the standard for storage up to 7 days is set to same-day consignment, the standard for temporary storage within 2 days of transport is set to temporary storage prohibited and same-day transport, and the standard for incineration within 2 days of disposal is set to same-day incineration. Is in progress.

Therefore, at a time when large-scale infectious diseases such as COVID-19 are becoming a global problem, there is a way to fundamentally block secondary infections by developing facilities that can self-sterilize in places such as quarantine facilities for infected people or those at risk of infection. is also presented. For example, methods are being developed to dispose of medical waste through shredding and sterilization instead of incineration.

An example of this technology is disclosed in Documents 1 to 3 below.

For example, in Patent Document 1 below, there is a conveyor that transports shredded waste from the inlet of a long outer shell to the outlet, and is connected from a steam source to the inside of the outer shell from a position adjacent to the inlet toward an intermediate position between the inlet and the outlet. A conduit for direct contact of steam with waste in a first section of the extending shell, surrounding a second section of the shell along a portion of the length between the intermediate position and the outlet, and a shell at the location of the second section. A steam jacket that heats the inner wall of the cylinder, and steam is fed into the steam jacket at a temperature that maintains the temperature of the inner wall at the location of the second section in the range of 100 ℃ to 300 ℃ while the waste is transported into the second section. A waste disposal device including a means for introducing water and a blower for removing moisture from waste by creating a low pressure lower than atmospheric pressure in a portion of the outer shell body is disclosed.

In addition, Patent Document 2 below includes an input unit where medical waste is input and temporarily stored, a grinding unit that crushes the medical waste provided from the input unit, and a sterilization unit that creates a reduced pressure and high temperature environment to sterilize the medical waste pulverized in the grinding unit. Including, the input unit, the grinding unit, and the sterilizing unit are sequentially arranged up and down so that the medical waste moves by its own weight, the grinding unit has a first axis extending left and right, and a plurality of devices fastened to the first axis. A first cutting unit including a first cutter, a second axis extending left and right to correspond to the first axis, and a plurality of plurality of cutters fastened to the second axis so as to form a predetermined overlapping area with the plurality of first cutters. Disclosed is a medical waste disposal device including a second cutting unit including a first cutter and a plurality of second cutters arranged to be staggered from each other.

On the other hand, Patent Document 3 below includes an input means for supplying waste, a crushing body arranged at the bottom of the input means, and a plurality of cutter bodies provided in the crushing body with a plurality of blades arranged in an intertwined form. Disclosed is a medical waste sterilization shredder, which is a modular shredder comprising a shredder for pulverizing waste and a sterilization means for sterilizing and drying the shredded waste supplied by the shredder, wherein the shredder is detachably provided.

Republic of Korea Patent Publication No. 10-0586629 (registered on May 29, 2006) Republic of Korea Patent Publication No. 10-1801738 (registered on November 21, 2017) Republic of Korea Patent Publication No. 10-1973458 (registered on April 23, 2019)

In the technology disclosed in Patent Document 1 as described above, a configuration is disclosed in which containerized medical waste is shredded, then the shredded material is directly steam-injected and dehydrated using a screw conveyor, and the moisture is evaporated by contacting the shredded material with a high temperature surface. However, there was a problem that medical waste could not be treated under optimal conditions such as effective sterilization of medical waste, deodorization function, and waste grinding conditions, and that it could not be applied in a portable manner.

In addition, Patent Document 2 discloses a medical waste disposal device that is miniaturized and can be installed adjacent to the source of medical waste, such as in a medical institution. However, the technology disclosed in Patent Document 2 also has sterilization and deodorization functions, waste grinding conditions, etc. The technology has not been disclosed.

On the other hand, in Patent Document 3, waste such as syringes, rubber gloves, etc. are broken into original shapes by a shredder, pulverized, and then sterilized so that they cannot be reused. It is possible to make them easy to replace by applying a modular shredder. However, there was a risk of secondary infection during the shredding process, and there was a problem that medical waste could not be treated under optimal conditions such as sterilization and deodorization functions.

In other words, there is a problem that the device for processing medical waste disclosed in the above-mentioned patent documents, etc. cannot be applied to mobile vehicles, etc., and the technology that can detect the sterilization state during the sterilization process is not applied, so workers are exposed to secondary damage during the waste treatment process. There was also the problem that it could be infected.

The purpose of the present invention is to solve the problems described above. Unlike general waste, medical waste, which is likely to be contaminated with various pathogenic bacteria, can be continuously processed in a movable vehicle and converted into general waste. To provide a mobile medical waste disposal system and method.

Another object of the present invention is to provide a mobile medical waste disposal system and method that can self-sterilize in places such as quarantine facilities for people at risk of infection.

Another object of the present invention is to provide a mobile medical waste disposal system and method that can reduce processing costs while preventing secondary contamination by medical waste.

In order to achieve the above object, a mobile medical waste disposal system according to the present invention is mounted on a movable vehicle to continuously process medical waste and convert it into general waste, including a supply unit for supplying medical waste to be treated, and the supply unit. A crushing unit that crushes the medical waste supplied from, a deodorization unit that performs a deodorizing treatment on the medical waste that is pulverized by the crushing unit, a sterilization unit that performs a sterilization process on the medical waste that is pulverized by the crushing unit, It includes a compression unit for compressing the medical waste sterilized in the sterilization unit, a packaging unit for packaging the medical waste compressed and discharged from the compression unit to be treated as general waste, and when sterilizing and deodorizing the medical waste in the sterilization and deodorization unit, A spherical tester for testing spores and multi-drug resistant bacteria on medical waste is characterized in that it is built into the sterilization unit.

In addition, in the mobile medical waste disposal system according to the present invention, the spherical tester includes a spore and multi-drug resistant bacteria test kit for verifying the sterilization ability of medical waste in the sterilization unit, and a test kit for measuring the temperature and humidity inside the sterilization unit. It is characterized by comprising a data measurement unit, a storage unit for storing data measured by the data measurement unit, a wireless transmitter consisting of RFID (Radio Frequency Identification) for short-distance communication, and a power unit that supplies the necessary power to each of the spherical testers. .

In addition, in the mobile medical waste disposal system according to the present invention, the supply unit has a chamber shape, a first door that opens and closes the chamber to supply medical waste from the outside, and a second door provided on the side of the crushing unit, It includes a movable input tray, and the first door is provided with a detection device for detecting metal foreign substances in medical waste and a scale for measuring the weight of medical waste supplied through the first door, and the second door is It is provided on an upper part of the first door, the input table is movable from the position of the first door to the position of the second door, and the second door is provided to be movable above the input table.

In addition, in the mobile medical waste disposal system according to the present invention, the grinding unit has a chamber shape and communicates with the supply unit through the second door, and the grinding unit disposes of medical waste supplied through the second door. A grinding pressure regulator that applies pressure to the medical waste at a constant pressure for grinding, a drive motor that drives the grinding pressure regulator, metals, glass, plastic, vinyl, etc. contained in the medical waste pressed by the grinding pressure regulator, It is characterized by comprising a two-axis grinding unit that grinds textiles to a size of about 1 to 5 cm suitable for sterilization, a pressure control state of the grinding pressure control unit, and a control unit that controls forward or reverse rotation of the two-axis grinding unit. .

In addition, in the mobile medical waste disposal system according to the present invention, the grinding unit further includes a detection unit that monitors and detects the grinding state and supply rate of the medical waste by the two-axis grinding unit, and a cleaning unit that cleans the detection unit, and the detection unit It includes an inspection window provided at a lower portion of the two-axis crushing unit to enable viewing of the interior of the crushing unit, a photo coupler provided around the inspection window to detect the crushing state and supply density of medical waste, and the cleaning unit includes the photo coupler. It is characterized by cleaning the contaminated state of the coupler.

In addition, in the mobile medical waste disposal system according to the present invention, the deodorization unit removes ammonia (NH ₃ ), hydrogen sulfide (H ₂ S), methyl mercaptan (CH ₃ SH), and methyl sulfide ((CH ₃ ) contained in medical waste. ₂ S), trimethylamine ((CH ₃ ) ₃ N), and a plasma generator that generates atmospheric pressure plasma for deodorization of complex odors, and the plasma generated by the plasma generator is supplied to the grinding unit or the sterilization unit. It is characterized by

In addition, in the mobile medical waste disposal system according to the present invention, the sterilization unit is a sterilization chamber provided with a closed cylindrical upward slope and a screw conveyor (Conveyor Screw) installed inside, and superheated steam is supplied to the sterilization chamber. It includes an evaporation chamber that maintains the internal temperature of the sterilization chamber above a certain level, and a magnetron that generates 1,000 to 2,000 W microwaves with a frequency of 2 GHz band suitable for heat generation in the sterilization chamber, and the magnetron is located at the upper part of the sterilization chamber. It is characterized by being installed in multiple stages.

In addition, in the mobile medical waste disposal system according to the present invention, a heating boiler provided at the entrance of the sterilization chamber to spray steam of 150 ℃ or higher into the interior of the sterilization chamber to maintain the temperature inside the sterilization chamber at around 100 ℃, A hot air supplier that supplies hot air to the evaporation chamber to evaporate moisture generated as superheated steam supplied from the heating boiler expands in the sterilization chamber, is provided at the upper end of the rear end of the evaporation chamber, and the grinding unit and It further includes an exhaust blower that suppresses the release of unsterilized pathogens into the air by creating a negative pressure that is lower than atmospheric pressure in the sterilization chamber and the evaporation chamber.

In addition, in the mobile medical waste disposal system according to the present invention, the compression unit is provided at the lower part of the rear end of the evaporation chamber to compress the medical waste sterilized in the sterilization unit at high pressure into pellets, and the compression unit includes the above-mentioned It is characterized by a recovery window for recovering the old tester.

In addition, in the mobile medical waste disposal system according to the present invention, a display unit that displays the operating status and alarm of each unit, sets and controls the start and stop functions of each unit, and sets and controls the date, time, and processing number of the medical waste. , a control unit that manages data on processing weight and processing temperature, and a power unit that supplies the necessary power to each unit.

In addition, in the mobile medical waste disposal system according to the present invention, the medical waste disposal system is included in an enclosure and is provided to be separable from the vehicle, and the enclosure has the enclosure when the medical waste disposal system is mounted separately from the vehicle. It is characterized by a support device for maintaining a horizontal state.

In addition, in order to achieve the above object, the mobile medical waste disposal method according to the present invention is mounted on a movable vehicle to continuously process medical waste and convert it into general waste, which includes (a) medical waste to be treated; supplying waste to a supply unit, (b) pulverizing the medical waste supplied in step (a) in a shredding unit and deodorizing it in a deodorizing unit, (c) for the medical waste shredded in step (b) Performing sterilization in a sterilization unit, (d) compressing the medical waste sterilized in step (c) into a pellet form in a compression unit, packaging it in a packaging unit, and disposing of it as general waste, The sterilization process in step (c) is characterized by performing tests for spores and multi-drug resistant bacteria on the medical waste using a spherical tester.

In addition, in the mobile medical waste disposal method according to the present invention, in step (a), the medical waste bag is mounted on the first door, so that the metal detection device and the scale detect the metal mixed in the medical waste, and the scale measures the weight. And, the medical waste bag is supplied to the crushing unit with the first door closed and the second door opened.

In addition, in the mobile medical waste disposal method according to the present invention, step (b) is performed with the first door and the second door closed, and the grinding state in step (b) is determined by a detection unit provided in the grinding unit. It is characterized by being detected by.

In addition, in the mobile medical waste disposal method according to the present invention, the test result in step (c) is transmitted to the control unit in real time, and the medical waste treated in step (d) according to the test result is transferred to step (a). It is characterized by being reprocessed by proceeding to .

As described above, according to the mobile medical waste disposal system and method according to the present invention, a system is installed on a movable vehicle to continuously process medical waste and convert it into general waste, thereby providing a living isolation facility for people at risk of infection. The effect of being able to self-sterilize in the same place is achieved.

In addition, according to the mobile medical waste disposal system and method according to the present invention, during sterilization and deodorization, medical waste is tested for spores and multi-drug resistant bacteria, thereby preventing secondary contamination due to medical waste treatment. Lose.

In addition, according to the mobile medical waste disposal system and method according to the present invention, a supply unit for supplying medical waste to be processed, a grinding unit for grinding the medical waste supplied from the supply unit, and deodorizing treatment for the medical waste pulverized by the grinding unit. By providing a deodorization unit that performs, it is possible to continuously process medical waste in a sealed state, thereby preventing secondary contamination and reducing processing costs.

1 is a block diagram of a mobile medical waste disposal system according to the present invention;
Figure 2 is a conceptual diagram of a vehicle-integrated medical waste disposal system according to the present invention;
3 is a conceptual diagram of a medical waste disposal system separated from a vehicle;
4 is a configuration diagram of each unit in the medical waste treatment system according to the present invention;
5 is a view showing the combined state of the supply unit and the grinding unit according to the present invention;
Figure 6 is a diagram for explaining the input process of medical waste in the supply unit according to the present invention;
7 is a diagram showing an example of the structure of a detection unit provided in a grinding unit applied to the present invention;
Figure 8 is a view showing an example of the structure of the washing unit provided in the grinding unit applied to the present invention;
9 is a diagram showing an example of a sterilization unit structure applied to the present invention;
10 is a diagram showing an example of a magnetron mounted on a sterilization chamber applied to the present invention;
11 is a photograph of the plasma generator applied to the deodorizing unit of the present invention;
12 is a conceptual diagram of the operation of plasma generated in a deodorizing unit applied to the present invention;
13 is a configuration diagram of a spherical inspection machine applied to the present invention;
Figure 14 is a configuration diagram of a compression unit and a packaging unit applied to the present invention.

The above and other objects and new features of the present invention will become more clear by the description of this specification and the accompanying drawings.

The term "unit" used herein refers to mechanical parts and electrical and electronic parts in each component unit for performing, for example, supply, grinding, sterilization, deodorization, etc. of medical waste in the process of processing medical waste. This refers to components that work in conjunction with each other.

In addition, the term "medical waste" used herein includes cotton wool, bandages, gauze, disposable syringes, and IV sets contaminated with blood, body fluids, excrement, and sap, and contains metals, glass, plastic, vinyl, and textiles. This means that it is packaged in a certain amount with a garbage bag at a medical waste collection point, but is not limited to this. The above garbage bag is, for example, a volume-rate bag, and bags of 30, 50 [L], etc. can be applied, and the actual amount of garbage in the bag is about 20 to 35 [L], and the average weight of garbage in the bag is can be applied at about 3 to 4 [kg].

The sterilization and deodorization technology applied to the mobile medical waste disposal system according to the present invention can apply sterilization and optimal deodorization functions using low-temperature and atmospheric pressure plasma instead of the conventional method using steam and microwaves.

In addition, the tester applied in the past was made of Teflon, put a commercial spore test kit inside it, put it in a sterilization chamber, went through a sterilization process, and recovered it at the exit end for analysis. However, in the present invention, an RFID chip was used to analyze the inside of the sterilization chamber. It measures and records important conditions such as temperature and humidity, and files and parses them into a database to enable systematic and organized management. At the same time, system administrators or supervisory authorities can monitor the use and use of devices. It can improve efficiency and make it easier to secure authenticity in managing and inspecting performance maintenance.

In addition, the present invention can respond with mobility by applying a mobile medical waste sterilization and crushing device that can be driven by its own power, and the processing capacity also varies, for example, 30 [kg/hr] or 50 [kg/hr]. It can be optimally placed where needed.

Therefore, the mobile medical waste disposal system according to the present invention can prevent the spread of infectious diseases by directly sterilizing on-site, eliminate concerns about secondary infection among medical workers, managers and neighbors, and significantly reduce processing costs.

In addition, the mobile medical waste disposal system according to the present invention can diversify the processing capacity by scaling up or down when necessary, and can accommodate various needs, such as redesigning the size or arrangement and storing it in a container. We can respond.

Hereinafter, embodiments according to the present invention will be described with reference to the drawings.

Figure 1 is a block diagram of a mobile medical waste disposal system according to the present invention.

The mobile medical waste disposal system according to the present invention is a system that is mounted on a movable vehicle to continuously process medical waste and convert it into general waste. As shown in FIG. 1, medical waste to be processed at a medical waste collection point is collected and A supply unit (10) for supplying, a grinding unit (20) for grinding the medical waste supplied from the supply unit (10), and a sterilization unit ( 30), a deodorizing unit 40 that performs deodorizing treatment on the medical waste pulverized by the pulverizing unit 20, a pressing unit 50 that compresses the medical waste sterilized in the sterilization unit 30, A packaging unit 60 that packages the medical waste compressed and discharged from the compression unit 50 to be disposed of as general waste, a display unit 70 that displays the operating status and alarm of each unit, and start and stop of each unit. Includes a control unit 80 that sets and controls functions and manages data on the date, time, processing number, processing weight, and processing temperature of medical waste, and a power unit 90 that supplies the necessary power to each unit. can do. Medical waste packaged in the packaging unit 60 may be deodorized and sterilized in the sterilization unit 30, deodorization unit 40, etc. described above and then loaded into a general waste loading dock.

As shown in FIGS. 2 and 3, the medical waste disposal system described above may be included in the enclosure 200 and provided in the vehicle 100, or may be provided separately from the vehicle 100. Figure 2 is a conceptual diagram of a vehicle-integrated medical waste disposal system according to the present invention, and Figure 3 is a conceptual diagram of a medical waste disposal system separated from the vehicle.

As shown in FIG. 2, when the medical waste disposal system according to the present invention is mounted on the vehicle 100, the vehicle 100 can process, for example, 4,700 kg of medical waste per hour. It can be prepared in the following dimensions: [mm] (L) × 2,000 [mm] (W) × 2,700 [mm] (H), and 2.5 to 3.5 ton wing body vehicles can be used.

The engine output of such a vehicle 100 can be 150 to 200 [HP] (114 to 152 [kW]), the vehicle engine can be a diesel engine, and the power consumption can be about 32.7 [kW]. This power consumption is the power consumption in each unit, for example, grinder: 10.0 [kW], electric boiler: 9.5 [kW], magnetron: 5.0 [kW], plasma generator: 2.0 [kW], exhaust blower. : 1.0[kW], heat air supply: 1.0[kW], control device: 1.0[kW], others: 1.0[kW].

Regarding the above-described power consumption, the power unit 90 is a self-power supply device that can be designed to basically generate electricity by driving a generator using the vehicle engine to cover the power requirement of the device, but is not limited to this. If it is difficult due to space constraints in the engine room, an independent generator can be installed as the power unit 90 and applied.

Meanwhile, as shown in FIG. 3, when the enclosure 200 is applied separately from the vehicle 100, a general truck capable of loading and unloading can be used, and is equipped with an independent support device 210 and the enclosure 200 when in operation. It may be arranged to be drawn out from the lower part toward the support surface.

As shown in FIG. 3, the support device 210 is provided to maintain the horizontal state of the enclosure 200 when the medical waste disposal system according to the present invention is mounted separately from the vehicle 100. The support devices 210 are provided at the four corners of the enclosure 200, and are maintained in a horizontal state when operating the medical waste disposal system according to the present invention.

In the support device 210, after the horizontal device 211 made of a hydro cylinder comes out and completes the operation, the vertical device 212 composed of a servo motor and a screw jack operates to ground the weight of the enclosure 200 by grounding it to the floor. While supporting, the torque can be detected and the torque control of each of the four support devices can be performed independently to absorb the uneven condition of the floor surface. In this way, even if the floor surface is uneven, the height of each vertical support device can be absorbed differently within a certain range to efficiently adjust the level, and the height of the enclosure 200 can also be appropriately adjusted to increase work efficiency.

Next, the medical waste disposal system provided in the enclosure 200 will be described with reference to FIG. 4.

Figure 4 is a configuration diagram of each unit in the medical waste treatment system according to the present invention.

The supply unit 10 and the grinding unit 20 have a chamber shape as shown in FIGS. 4 and 5. Figure 5 is a diagram showing the combined state of the supply unit and the grinding unit according to the present invention.

The supply unit 10 has a first door (hereinafter referred to as 'medical waste') that opens and closes the chamber to supply medical waste (hereinafter referred to as 'medical waste') contained in a waste bag (1) made of garbage bags collected in a medical waste collection point. 11) and a second door 12 provided on the side of the grinding unit 20, and an input table 13 that can move up and down. As shown in FIG. 4, the first door 11 can be bent at 90 degrees and laid down. This first door 11 includes a detection device for detecting metal foreign substances in medical waste and a detection device that detects metal foreign substances in medical waste through the first door. A scale may be provided to measure the weight of medical waste supplied. However, it is not limited to this, and the detection device and scale may be provided on the input table 13. In addition, the first door 11 can be opened and closed by an administrator, and the second door 12 is provided on an upper part of the first door 11 and is operated by a control unit 80. 15) is provided so that it can be opened and closed. The input tray 13 is provided to be movable from the position of the first door 11 to the position of the second door 12 by a cylinder 14, and the second door 12 is connected to the input tray. It can be provided to be movable on the input table 13 by the opening and closing axis 15 as the (13) rises and falls.

As described above, in the supply unit 10 according to the present invention, the first door 11, which is the outer door, and the second door 12, which is the inner door, are installed separately, and the two doors are not opened at the same time, thereby preventing the medical waste bag from being opened. (1) When pulverizing, it can operate as a structure to prevent backflow of contaminated dust or bacteria. In other words, by installing a metal foreign matter detection device and a weight measurement scale at the first door 11, which is the entrance door and waste supply door, automatic weight measurement and metal foreign matter exceeding the standard can be effectively removed. Therefore, when a waste bag is placed on the first door (11) equipped with a metal detection device and scale and the input tray (13), it detects and warns if metal of a certain size or more is mixed, and automatically measures and records the weight. When a manager pushes a medical waste bag (1) found to be normal into the chamber and closes the first door (11), the weight of the medical waste can be recorded and added up as the waste disposal amount.

As shown in FIG. 5, the pulverizing unit 20 has a chamber shape and is provided to communicate with the supply unit 10 through the second door 12.

The crushing unit 20 is formed in an (21), a drive motor 22 that drives the grinding pressure regulator 21, and sterilizes metals, glass, plastics, vinyl, and fibers contained in the medical waste pressed by the grinding pressure regulator 21. A two-axis grinding unit (23) that grinds to a size of about 1 to 5 cm, a control unit that controls the pressure control state of the grinding pressure adjusting unit (21) and forward or reverse rotation of the two-axis grinding unit, and the two axes. It may include a detection unit that monitors and detects the grinding state and supply rate of the medical waste by the grinding unit 23 and a cleaning unit that cleans the detection unit. The control unit may be included in the control unit 80.

The crushing unit 20 maintains a constant pressure by pressing at an optimal pressure regardless of whether it is medical waste tightly packed at high density or conversely light and blowable waste, through the crushing pressure regulator 21, thereby efficiently crushing medical waste. You can run it with The grinding pressure can be optimally adjusted in real time by feeding back the feed rate from the control unit 80.

The two-axis grinding unit 23 of the above-described grinding unit 20 can basically grind metals, glass, plastic, vinyl, fibers, etc. into a size of about 1 to 5 cm suitable for sterilization. That is, the two-axis pulverizing unit 23 can be designed with an appropriate blade width, for example, about 25 mm or more, and can be driven at low speed through a reducer to amplify the force required for pulverizing.

The control unit of the control unit 80 measures the force applied to the grinding unit 20 for safe operation of peripheral devices such as the drive motor 22, the two-axis grinding unit 23, and the reducer, and for continuous operation of the device, and measures the force applied to the grinding unit 20 to exceed a certain size. If so, it automatically stops and repeats reverse and forward operations to remove overloaded substances caught on the blades of the two-axis crusher (23) and then switches to forward operation to control the device to operate continuously without stopping.

The process of inputting and pulverizing medical waste in the supply unit 10 and the pulverizing unit 20 will be described with reference to FIG. 6. Figure 6 is a diagram for explaining the input process of medical waste in the supply unit according to the present invention.

First, as shown in (a) of FIG. 6, the manager opens the first door 11 and mounts the medical waste bag 1 on the first door 11, so that the metal detection device and the scale are activated. Metals mixed in medical waste are detected and weighed by a scale. In other words, when the first door 11, which is the supply door, is closed, it becomes a door that closes the supply unit 10, but when it is open, it becomes a stand with a built-in scale and automatically measures the weight of the waste, and the measurement results are sent to the control unit. It is sent to (80). Such data can be transmitted through wired or wireless connection between the supply unit 10 and the control unit 80. When the first door 11 is opened, the second door 12 remains closed.

Next, as shown in (b) of FIG. 6, the medical waste is placed on the input table 13 by pushing the medical waste bag 1 into the chamber and closing the first door 11. Even in the state shown in (b) of FIG. 6, the second door 12 remains closed.

Next, when the medical waste supply button provided on the control unit 80 is pressed, as shown in FIG. 6 (c), the second door (12) is opened and closed by operation of the opening and closing axis 15 of the second door 12. 12) moves to the left and becomes ready to feed medical waste into the shredding unit 20.

Next, after the second door 12 is completely moved to the left side of the chamber of the supply unit 10, the cylinder 14 rises to deposit medical supplies on the input table 13, as shown in (d) of FIG. 6. Waste is conveyed towards the opening of the second door 12, which is the upper part of the grinding unit 20.

Continuing, the medical waste transferred to the open side of the second door 12 is transferred to the medical waste bag as the second door 12 moves toward the closed position on the input table 13, as shown in (e) of FIG. 6. (1) falls into the chamber of the grinding unit 20, and the second door 12 closes the chamber of the grinding unit 20.

Accordingly, within the chamber of the grinding unit 20, as shown in (f) of FIG. 6, the grinding pressure regulator 21 operating in a bellows manner descends and presses the medical waste bag 1 with an appropriate pressure. , the input table 13, which has risen to the top, lowers again and returns to the state of preparation for the next operation.

As shown in FIG. 7, the detection unit provided in the grinding unit 20 includes an inspection window 24 provided at a lower portion of the two-axis grinding unit 23 to enable viewing of the interior of the grinding unit 20, It includes photo couplers 241 and 242 provided around the inspection window 24 to detect the pulverization state and supply density of medical waste. Figure 7 is a diagram showing an example of the structure of a detection unit provided in a grinding unit applied to the present invention.

As shown in FIG. 7, the photo couplers 241 and 242 are provided as an optical measurement device consisting of a photo diode 241 and a photo transistor 242, and there are three photo couplers on each axis in the X-axis direction and Y-axis direction. It can be installed more than once.

The cleaning unit 25 is provided to clean the contamination of the photo couplers 241 and 242, as shown in FIG. 8, in order to clean the detection unit. Figure 8 is a diagram showing an example of the structure of the washing unit provided in the grinding unit applied to the present invention.

As shown in FIG. 8, the washing unit 25 includes a supply pump 251 that transports water supplied through a water supply pipe, compresses the water supplied to the supply pump 251 with compressed air, and temporarily stores it. It is provided with a water compression tank 252, an air compressor 254 for compressing and transporting air supplied through an air supply pipe, and an air compression tank 252 for temporarily storing the compressed air, and the water stored in the water compression tank 252 Water can clean the photo diode 241 through the valve and nozzle 253, and air stored in the air compression tank 252 can clean the photo transistor 242 through the valve and nozzle 253.

In the mobile medical waste disposal system according to the present invention, an inspection window 24 is installed at the bottom of the grinding unit 20 to allow the manager to visually determine the state of medical waste grinding, and photo couplers 241 and 242, which are sensors, are installed. By installing it, the pulverization state and supply density of medical waste can be detected, and the supply rate (e.g., 30 to 50 [kg/h]) can be adjusted in real time considering the current situation such as the sterilization preparation state of the sterilization unit 30. .

In addition, the structure is designed so that waste powder, air, liquid, etc. generated during the grinding process do not leak to the outside through the measuring device, and if leakage occurs, the stuffing box of the axis is installed in the two-axis grinding unit 23 so that it can be visually confirmed immediately. Design the Stuffing Box and Bearing Box.

In addition, with long-term use of the grinding unit 20, there is a high possibility that leakage may occur due to wear due to friction between the airtight device and the axis of the two-axis grinding unit 23, and to repair this, the equipment must be stopped and expensive maintenance is required. Since cost is incurred, in order to prevent this, the present invention uses a wear-resistant sleeve to reduce device maintenance time and cost.

As shown in FIGS. 4 and 9, the sterilization unit 30 includes a sterilization chamber 31 having a sealed cylindrical shape with an upward slope and a screw conveyor (Conveyor Screw, 33) installed therein. ), an evaporation chamber 32 that maintains the internal temperature of the sterilization chamber 31 above a certain level by supplying superheated steam to the sterilization chamber 31, and a frequency of 2 GHz band suitable for heat generation in the sterilization chamber 31. It may include a magnetron 34 that generates ~2,000 W of microwaves. Figure 9 is a diagram showing an example of a sterilization unit structure applied to the present invention.

As shown in FIG. 9, the sterilization chamber 31 is designed with an upward inclination of 15 to 20 degrees, and a screw conveyor 33 is provided inside to transport the pulverized clothing waste upward. Accordingly, the finely crushed medical waste passing through the crushing unit 20 slowly passes through the sterilization chamber 31 along the screw conveyor 33. The time passing through the sterilization chamber 31 is basically adjustable by the rotation speed of the screw transporter 33, and it is desirable to basically design it to ensure sufficient time for sterilization, for example, about 30 minutes. do.

Meanwhile, as shown in FIG. 4, the sterilization unit 30 is provided at the inlet end of the sterilization chamber 31 and sprays steam of 150° C. or higher into the inside of the sterilization chamber 31 to sterilize the sterilization chamber 31. A heating boiler 220 that maintains the internal temperature at around 100°C, and an evaporation chamber ( 32), a hot air supplier 230 that supplies hot air to the evaporation chamber 32, which is provided at the upper end of the rear end of the evaporation chamber 32 and reduces the pressure of the grinding unit 20, the sterilization chamber 31, and the evaporation chamber 32. An exhaust blower 240 may be combined to suppress unsterilized pathogens from being released into the air by forming a negative pressure weaker than atmospheric pressure.

By providing the heating boiler 220 at the inlet end of the sterilization chamber 31, the high-temperature sterilization and moisture heat generation efficiency in the sterilization chamber 31 and the evaporation chamber 32 can be increased.

As shown in FIG. 9, the magnetron 34 may be installed in multiple stages, for example, 5 stages, at the upper part of the sterilization chamber 31, and each magnetron 34 generates steam in the sterilization chamber 31. It may be provided with a structure as shown in FIG. 10 to prevent condensation and temperature drop. Figure 10 is a diagram showing an example of a magnetron mounted on a sterilization chamber applied to the present invention.

The magnetron 34 is designed with a double jacket cooling structure for continuous operation to prevent damage due to heat generation from the magnetron.

In addition, the installation of the magnetron 34, which can evenly inject microwaves into the sterilization chamber 31, and the design of the waveguide 341 determine the specifications, opening size, and spacing of the waveguide depending on the capacity of the sterilization chamber 31. You can.

Meanwhile, the control unit 80 controls the temperature of the entire sterilization chamber to be maintained above a certain temperature, for example, 95°C or above, and in order to keep the sterilization chamber 31 warm, the outside of the chamber is insulated or manufactured as a double chamber. This can improve thermal efficiency by preventing heat from being easily conducted. In other words, if the thermal efficiency in the sterilization chamber 31 is improved, condensation of water vapor can be prevented and the number of magnetrons installed can be reduced, thereby reducing electricity consumption. In addition, a sight glass may be installed in the middle of the sterilization chamber 31 to easily check the transport and sterilization status of medical waste.

The deodorization unit 40 is equipped with a plasma generator for deodorization during the crushing and sterilization operation of medical waste in the crushing unit 20 and the sterilization unit 30, and this plasma generator generates an atmospheric pressure dielectric discharge as shown in FIG. 11. A plasma generator can be applied. Figure 11 is a photograph of a plasma generator applied to the deodorizing unit of the present invention.

That is, the deodorization unit 40 removes ammonia (NH ₃ ), hydrogen sulfide (H ₂ S), methyl mercaptan (CH ₃ SH), methyl sulfide ((CH ₃ ) ₂ S), and trimethylamine ( (CH ₃ ) ₃ N) and a plasma generator that generates atmospheric pressure plasma for deodorization of complex odors, and the plasma generated by the plasma generator may be supplied to the grinding unit 20 or the sterilization unit 30. .

The deodorizing unit 40 uses the principle of atmospheric pressure without the need for a vacuum system to generate deodorizing ions from air and moisture in the air and continuously inject them into the grinding device, so that sterilization and deodorization are performed from the grinding unit 20. .

The plasma generator, which is the deodorizing unit 40, is installed to implement the optimal deodorizing function of the sterilization grinding device, and combines sterilization treatment by heat using pressure superheated steam and a magnetron and sterilization treatment using plasma to form a complex sterilization device. can do.

The plasma generated in the deodorizing unit 40 is sprayed circumferentially into the grinding unit 20 to sterilize odors and pathogens scattered from the grinding unit 20, and is also sprayed into the sterilization chamber 31 at regular intervals. It may be arranged to be discharged from the discharge blower 240 while proceeding along the sterilization chamber 31.

As shown in FIG. 12, the above-mentioned plasma shows much higher efficiency in generating chemical radicals than other methods by applying the atmospheric pressure plasma method, so it can be effectively applied for sterilization or deodorization purposes as shown in the following chemical formula. Figure 12 is a conceptual diagram of the operation of plasma generated in a deodorizing unit applied to the present invention.

H ₂ O + e → H + OH + e

O ₂ + 2e → O ₂ ^- +e

2OH → H ₂ O ₂

N ₂ + O → NO + N

N ₂ + O ₂ → N ₂ O + O

2NH ₃ + 6OH → N ₂ + 6H ₂ O

In addition, the above-described heating boiler 220 functions as a steam generator, and the steam generator supplies superheated steam to the sterilization chamber 31 to raise the internal temperature of the sterilization chamber 31 to a certain level or higher. It is provided to maintain and at the same time supply appropriate moisture to the waste to increase the moisture heating effect by the microwave of each sterilization unit (30). The heating boiler 220 uses electricity as its main energy source and has a continuous evaporation rate, for example, 10 to 30 [kg/h] and a steam pressure, for example, 5 to 10 [kg/h], which match the performance of the sterilization chamber 31. kg/cm ² ] can produce superheated steam (e.g., above 180°C).

The hot air supplier 230 is provided to evaporate the superheated steam supplied to the sterilization chamber 31 in the evaporation chamber 32 because there is a possibility that the superheated steam supplied to the sterilization chamber 31 may build up and make the waste wet. If this worsens, water may be generated. For example, the hot air supplier 230 uses an electric heater to generate hot air of about 60 to 80°C, and supplies the hot air to the evaporation chamber 32 with a blower to dry medical waste in the process. there is. In addition, during the treatment process, the temperature and blowing amount of hot air supplied from the hot air supply device 230 may be adjusted according to the wetness and dryness of the medical waste.

As shown in FIG. 4, the discharge blower 240 adjusts the pressure of the grinding unit 20 and the sterilization chamber 31 to a negative pressure weaker than atmospheric pressure, for example, △P≥0.001~0.025[mBAR] or 1.0~2.5[ It is designed to prevent unsterilized pathogens from being released into the air by forming a negative pressure of [Pa]. Additionally, the discharge blower 240 may be installed to separate pulverized and sterilized waste from air containing steam (including hot air) and efficiently collect only the waste of treated medical waste from the outlet.

Meanwhile, in the mobile medical waste disposal system according to the present invention, a ball type inspection kit as shown in FIG. 13 may be built into the sterilization unit 30. Figure 13 is a configuration diagram of a spherical inspection machine applied to the present invention.

The spherical tester 250 is a spherical tester capable of monitoring, recording, and transmitting data of the sterilization chamber 31 in order to verify the sterilization ability of the sterilization chamber 31 and determine whether there is an abnormality in the sterilization chamber 31. (Inspection Kit), spores and multi-drug resistant bacteria can be tested on medical waste during sterilization and deodorization processing in the sterilization and deodorization unit.

As shown in FIG. 13, the spherical tester 250 includes a spore and multi-drug resistant bacteria test kit 2501 for verifying the sterilization ability of the sterilization unit 30 for medical waste, and the sterilization unit 30. A data measurement unit 2502 that measures internal temperature and humidity, a storage unit 2503 that stores data measured by the data measurement unit 2502, and a wireless transmitter 2504 consisting of RFID (Radio Frequency Identification) for short-distance communication. And it may include a power supply unit 2505 that supplies the necessary power to each of the spherical testers.

The spherical tester 250 can be inserted at the entrance to the sterilization chamber 31 and collected from the last waste outlet to test for sterilization of spores and multi-drug resistant bacteria. If the sterilization test for these fungi does not pass, the waste is recovered. It can be prepared for reprocessing.

The spherical tester 250 is made of a material with chemical high-temperature stability, for example, Teflon, and can be divided into two parts, upper and lower, and fastened with screws to facilitate disassembly and assembly of the tester. In order to verify reliable sterilization ability, in principle, as shown in FIG. 13, a spore test kit and a multi-drug resistant bacteria test kit 2501 are built in the center of the spherical tester 250, and a data measurement unit 2502 and a data measurement unit 2502 are installed on the left and right sides. A wireless transmitter 2504 is installed.

The wireless transmitter 2504 may be provided with a built-in RFID (Radio Frequency Identification) chip, which is a radio frequency identification device. The spherical tester (250) with a built-in RFID chip moves inside the sterilization chamber (31) and the evaporation chamber (32) and measures and records data such as movement path by time zone, total movement time, temperature and humidity in real time and transmits them wirelessly. In order to facilitate collection, a visual and audible alarm may be provided upon exiting the evaporation chamber 32 and a message may be automatically sent to the manager.

The RFID frequency of the wireless transmitter 2504 can be selected in a frequency band that facilitates wireless transmission depending on the structure of the sterilization chamber 31 and evaporation chamber 32 and the location and size of components such as sight glass. The data measurement unit 2502 can measure information such as identification number, date and time information, temperature, humidity, and ion concentration for each movement path and location within the sterilization chamber 31 and the evaporation chamber 32.

The recovery of the old tester 250 can be carried out by applying effective recovery means such as sounding a visible and audible alarm when the tester exits the evaporation chamber 32, sending a message to the manager, and installing a recovery robot. If the state remains unchecked, the control unit 80 may be configured to execute a system interrupt.

The storage unit 2503 of the old tester 250 stores the collected data as a file in CSV (comma-separated values) format, and encrypts the CSV file to prevent arbitrary manipulation or change, so that it can be easily managed by the supervisory office. It is provided so that you can do this, and CSV files can also be used as basic data for building a database.

The compression unit 50 is a medical waste compression device (garbage pressurizer), and is provided for efficient management of treated waste due to the characteristics of a mobile medical waste sterilization and shredding device. In other words, the compression unit 50 is designed to reduce the volume and make management easier by compressing waste at high pressure and turning it into pellets, since storage space is likely to be restricted in the case of bulky waste.

That is, as shown in FIGS. 4 and 14, the compression unit 50 is provided at the outlet 35 provided at the lower portion of the rear end of the evaporation chamber 32, and the medical product sterilized in the sterilization unit 30 It may be composed of a waste compressor 51 and a compression unit 52 that operates the compressor 51 to compress waste at high pressure and turn it into pellets. Figure 14 is a configuration diagram of the compression unit and packaging unit applied to the present invention.

As shown in FIG. 14, the waste compactor 51 uses a pneumatic or hydraulic cylinder in a compression container having a square shape to compress the waste 2, which is medical waste treated as general waste, into an approximately square shape. It is pelletized by operating in the forward and backward directions by the compression unit 52, and the pelletized waste 2 is packaged and bundled by the packaging unit 60 provided at the rear of the compression unit 50, making it easy to load or transport. Therefore, it can be transported to a general waste loading area. Meanwhile, a recovery window for recovering the spherical tester 250 may be provided in the compression container of the pressing unit 50.

In addition, the display unit 70 shown in FIG. 1 is a monitor made of an LCD, etc., and can display the operating status and alarms of each unit in an easy-to-understand manner for the manager, and the control unit 80 is used for grinding, sterilization, and other functions. It is designed to set and control the overall necessary functions, such as the operation mode of the deodorizing unit main body and its auxiliary devices, and the start and stop of each unit, and processing related functions such as processing date, time, processing number, processing weight, processing temperature, etc. of the sterilizing and grinding device. Important data can be automatically recorded, stored, and made available for printing when needed.

Meanwhile, the power unit 90 may use power generated by the vehicle 100 as shown in FIG. 2 or may be provided by a separately provided generator.

Although the invention made by the present inventor has been described in detail according to the above-mentioned embodiments, the present invention is not limited to the above-described embodiments and can of course be changed in various ways without departing from the gist of the invention.

By using the mobile medical waste disposal system and method according to the present invention, it is possible to self-sterilize in places such as quarantine facilities for people at risk of infection.

10: supply unit
20: Grinding unit
30: Sterilization unit
40: Deodorization unit
50: Compression unit
60: packaging unit

Claims (15)

A system mounted on a movable vehicle to continuously process medical waste and convert it into general waste,
a supply unit that supplies medical waste for processing;
A grinding unit for grinding the medical waste supplied from the supply unit,
A sterilization unit that performs sterilization processing on medical waste pulverized by the crushing unit,
a deodorizing unit that performs deodorizing treatment on the medical waste pulverized by the pulverizing unit;
A compression unit that compresses the medical waste sterilized in the sterilization unit,
It includes a packaging unit for packaging the medical waste compressed and discharged from the compression unit to be treated as general waste,
During sterilization and deodorization processing in the sterilization and deodorization unit, a spherical tester that tests for spores and multi-drug resistant bacteria on medical waste is built into the sterilization unit,
The supply unit has a chamber shape, a first door that opens and closes the chamber to supply medical waste contained in a waste bag from the outside, a second door provided on the crushing unit side at the top of the first door, and the first door. It includes an input table that can move up and down from the position of the first door to the position of the second door,
The first door is provided so that the medical waste can be loaded by being bent at 90 degrees and laid down, and is equipped with a detection device to detect metal foreign substances in the medical waste and a scale to measure the weight of the medical waste supplied through the first door. Contains,
The second door is provided to be able to move left and right by operating an opening and closing axis on the input table,
When the first door is opened and the medical waste is loaded, the second door is maintained in a closed state, and when the first door is closed and the medical waste is placed on the input table, the second door is maintained in an open state. ,
The mobile medical waste disposal system is characterized in that the medical waste is placed on the input table when the first door is closed, and is dropped into the chamber of the crushing unit when the second door is closed. . In paragraph 1:
The spherical tester includes a spore and multi-drug resistant bacteria test kit to verify the sterilization ability of medical waste in the sterilization unit,
A data measurement unit that measures the temperature and humidity inside the sterilization unit,
A storage unit for storing data measured by the data measurement unit,
A wireless transmitter consisting of RFID (Radio Frequency Identification) for short-distance communication and
A mobile medical waste disposal system comprising a power supply unit that supplies the necessary power to each of the spherical inspection machines. delete In paragraph 1:
The grinding unit has a chamber shape and communicates with the supply unit through the second door,
The crushing unit is
A grinding pressure regulator that applies pressure to the medical waste at a constant pressure to grind the medical waste supplied through the second door;
A drive motor that drives the grinding pressure regulator,
A two-axis grinding unit that grinds metals, glass, plastics, vinyl, and fibers contained in the medical waste pressed by the grinding pressure control unit into a size of about 1 to 5 cm suitable for sterilization,
A mobile medical waste disposal system comprising a control unit that controls the pressure control state of the grinding pressure control unit and the forward or reverse rotation of the two-axis grinding unit. In paragraph 4,
The grinding unit further includes a detection unit that monitors and detects the grinding state and supply rate of the medical waste by the two-axis grinding unit, and a cleaning unit that cleans the detection unit,
The detection unit
An inspection window provided at the lower part of the two-axis grinding unit to enable viewing of the interior of the grinding unit,
It includes a photo coupler provided around the inspection window to detect the pulverization state and supply density of medical waste,
A mobile medical waste disposal system, wherein the cleaning unit cleans the contaminated state of the photo coupler. In paragraph 1:
The deodorization unit removes ammonia (NH ₃ ), hydrogen sulfide (H ₂ S), methyl mercaptan (CH ₃ SH), methyl sulfide ((CH ₃ ) ₂ S), and trimethylamine ((CH ₃ ) ₃ contained in medical waste. N) and a plasma generator that generates atmospheric pressure plasma for deodorization of complex odors,
A mobile medical waste disposal system, characterized in that the plasma generated by the plasma generator is supplied to the grinding unit or the sterilization unit. In paragraph 1:
The sterilization unit is
A sterilization chamber with a sealed cylindrical uphill slope and a conveyor screw installed inside,
An evaporation chamber that supplies superheated steam to the sterilization chamber to maintain the internal temperature of the sterilization chamber above a certain level,
It includes a magnetron that generates 1,000 to 2,000 W microwaves with a frequency of 2 GHz, which is suitable for generating heat in the sterilization chamber,
A mobile medical waste disposal system, characterized in that the magnetron is installed in multiple stages at the upper part of the sterilization chamber. In paragraph 7:
A heating boiler provided at the entrance of the sterilization chamber to spray steam of 150°C or higher into the interior of the sterilization chamber to maintain the temperature inside the sterilization chamber at around 100°C,
A hot air supplier that supplies hot air to the evaporation chamber to evaporate moisture generated as superheated steam supplied from the heating boiler expands in the sterilization chamber;
It is provided at the upper end of the rear end of the evaporation chamber, and further comprises an exhaust blower that suppresses the release of unsterilized pathogens into the air by forming a negative pressure weaker than atmospheric pressure in the grinding unit, the sterilization chamber, and the evaporation chamber. Features a mobile medical waste disposal system. In paragraph 8:
The compression unit is provided at the lower part of the rear end of the evaporation chamber and compresses the medical waste sterilized in the sterilization unit at high pressure into pellets,
A mobile medical waste disposal system, characterized in that the compression unit is provided with a recovery window for recovering the old tester. In paragraph 1:
A display unit that displays the operating status and alarms of each unit,
A control unit that sets and controls the start and stop functions of each unit and manages data on the processing date, time, processing number, processing weight, and processing temperature of medical waste;
A mobile medical waste disposal system further comprising a power unit that supplies the necessary power to each unit. In paragraph 1:
The medical waste disposal system is included in the enclosure and is separable from the vehicle,
A mobile medical waste disposal system, characterized in that the enclosure is provided with a support device to maintain a horizontal state of the enclosure when the medical waste disposal system is mounted separately from a vehicle. A method of continuously processing medical waste and converting it into general waste by being mounted on a movable vehicle,
(a) supplying medical waste to be processed to a supply unit,
(b) crushing the medical waste supplied in step (a) in a crushing unit and deodorizing it in a deodorization unit,
(c) carrying out sterilization treatment in a sterilization unit on the medical waste ground in step (b),
(d) compressing the medical waste sterilized in step (c) into pellet form in a compression unit, packaging it in a packaging unit, and disposing of it as general waste,
For the sterilization process in step (c), the medical waste is tested for spores and multi-drug resistant bacteria using a spherical tester,
The supply unit in step (a) has a chamber shape, a first door that opens and closes the chamber to supply medical waste contained in a waste bag from the outside, and a first door provided on the crushing unit side at the top of the first door. It includes a second door and an input tray that can move up and down from the position of the first door to the position of the second door,
The first door is provided so that the medical waste can be loaded by being bent at 90 degrees and laid down, and is equipped with a detection device to detect metal foreign substances in the medical waste and a scale to measure the weight of the medical waste supplied through the first door. Contains,
The second door is provided to be able to move left and right by operating an opening and closing axis on the input table,
When the first door is opened and the medical waste is loaded, the second door is maintained in a closed state, and when the first door is closed and the medical waste is placed on the input table, the second door is maintained in an open state. ,
The mobile medical waste disposal method characterized in that the medical waste is placed on the input table when the first door is closed, and is dropped into the chamber of the crushing unit when the second door is closed. . In paragraph 12:
In step (a), a mobile medical waste disposal method is characterized in that the medical waste bag is mounted on the first door, the metal detection device and the scale detect the metal mixed in the medical waste, and the scale measures the weight. In paragraph 13:
Step (b) is performed with the first door and the second door closed,
A mobile medical waste disposal method, characterized in that the grinding state in step (b) is detected by a detection unit provided in the grinding unit. In paragraph 14:
The inspection results in step (c) are transmitted to the control unit in real time,
A mobile medical waste disposal method, characterized in that the medical waste treated in step (d) is reprocessed by proceeding to step (a) according to the test results.

Images