JP4498974B2 - Infectious waste treatment facility - Google Patents

Description

  The present invention is provided at a place where infectious waste is generated or treated in hospitals, laboratories, inspection institutions, etc. (referred to as hospitals in this specification and claims), and these infectious wastes. The present invention relates to a treatment facility for infectious waste that can be sterilized (including disinfection treatment) and sterilized so that it can be discharged into a general sewer later. In this specification and claims, the term “sterilization” refers to all forms of microorganisms (bacteria and viruses) that can all grow, unless specifically designated “sterilization (excluding disinfection)”. Treatment) and a disinfection treatment with a lower degree of destruction (death) than that to completely destroy (death) or removal.

  In hospitals etc., after excising various infectious lesions, or after collecting a tissue piece of a human body such as a piece of meat (simply referred to as a tissue piece) from a patient or the like as a test object, Disposal is done daily. In hospitals or the like having hospitalized patients, infectious microorganisms are also present in the urine, and these are sterilized and then discarded.

  Such sterilization can be roughly divided into two methods. One of them is a technique of sterilizing infectious waste by treating it with a medicine. The other is a technique in which infectious waste is kept in a tank at a predetermined temperature or higher for a predetermined time and sterilized by heating.

The former method requires relatively inexpensive equipment, but it is necessary to neutralize the infectious waste that contains the drug after the drug treatment, and therefore the running cost is high. There is a problem that the load on the environment is increased due to the addition of a large amount of drug.
On the other hand, the latter method is excellent in that infectious waste after heat sterilization can be passed directly to general sewers without post-treatment, but the equipment itself becomes a large scale, such as large hospitals. There is a problem that it is difficult to introduce such equipment unless it is a facility. Moreover, there is a problem that the amount that can be processed is small for the size of the equipment.

The present applicant has already provided an epoch-making infectious waste treatment facility that can carry out the latter method, and in particular, does not clog the pipeline of the treatment facility due to mixed solids ( Patent Document 1).
JP2003-260115A.

  However, since the infectious waste treatment facility described in Patent Document 1 is a so-called batch treatment type, the amount of treatment per unit time is small for an increase in the size of the facility.

  In view of such a situation, the present inventor aims to provide a small treatment facility for infectious waste with a low price of the equipment itself.

  The object of the present invention can be solved by a treatment facility for infectious waste having the following configuration.

The infectious waste treatment facility according to the present invention is an infectious waste treatment facility capable of sterilizing infectious waste and releasing it into a general drainage channel.
This processing equipment
A mixer for mixing the infectious waste and pressurized steam;
A discharge line for supplying infectious waste to the mixer;
A pressurized steam supply line for supplying pressurized steam into the mixer;
A staying conduit provided on the downstream side of the mixer and extended for a predetermined length to retain the infectious waste after being heated in the mixer for a predetermined time and sterilizing, and the staying A sterilization apparatus comprising a heating means for heating a pipe line to a predetermined temperature or higher;
A connecting pipe connecting the mixer and the sterilization apparatus;
It is characterized by comprising.

According to the infectious waste treatment facility according to the present invention having the above-described configuration, in the infectious waste before treatment supplied from the discharge pipe in the mixer, the pressurized steam is supplied. The temperature of the infectious waste itself is raised by mixing them in this mixer while exposed to an environment of high-temperature pressurized steam supplied from a pipeline. Next, the infectious waste heated in the mixer is supplied from the mixer to the sterilization apparatus via a connecting pipe, and the staying conduit in the sterilization apparatus is connected to the infectivity. The infectious waste is sterilized by allowing the waste to pass through, that is, passing the infectious waste over a predetermined time in a staying pipeline maintained at a predetermined temperature or higher.
Then, according to the infectious waste processing facility, the infectious waste to be treated in this way is sterilized by continuously passing through a mixer and a sterilization apparatus. It is possible to continuously process objects.
In addition, since the infectious waste can be efficiently heated by directly adding high-temperature pressurized steam to the infectious waste to be treated in the mixer, the equipment can be downsized.
As a result, according to the treatment facility for infectious waste, a large amount of infectious waste can be continuously treated per unit time.

  Further, in the infectious waste treatment facility, since the mixer and the sterilization apparatus are pressure vessels, infectious waste requiring high temperature for sterilization can be treated. It becomes composition.

  Further, in the infectious waste treatment facility, if the heating means of the sterilization apparatus is constituted by a heating jacket configured to supply pressurized steam therein, it is already provided in a hospital or the like. It becomes the structure which can utilize the steam from the existing boiler. As a result, this processing facility can be installed at low cost.

  Further, in the infectious waste treatment facility, the flow control valve or the backflow prevention valve is disposed on the upstream side of the mixer and the downstream side of the sterilization apparatus, respectively. It is possible to realize a configuration in which the system up to the apparatus can be maintained in a pressurized state, and thus sterilization at a high temperature of 100 ° C. or higher is possible. Of course, instead of the flow rate adjustment valve or the backflow prevention valve, a system between the mixer and the sterilization apparatus can be maintained in a pressurized state by providing a throttle in the pipe. Is possible.

  Hereinafter, infectious waste processing equipment according to embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 is an overall schematic diagram conceptually showing the overall configuration of an infectious waste treatment facility according to an embodiment of the present invention.

In FIG. 1, reference numeral 1 denotes a processing stock solution tank for temporarily storing infectious waste (in the form of a liquid containing solids) according to the present invention and supplying it to a processing facility for infectious waste. Inside, a stock solution containing infectious waste discharged from a treatment room or the like of a hospital is stored. The processing stock solution tank 1 includes a supply pipe 11, a backflow prevention valve 12 for preventing the backflow of the stock solution to the processing stock solution tank 1 side, and a control pipe (open / close valve) 13. The passage 2 is connected to a mixing tank (a kind of mixer) 3 provided on the downstream side, and infectious waste is supplied into the mixing tank 3.
In the case of this embodiment, the mixing tank 3 is constituted by a pressure tank (pressure vessel). Further, the mixing tank 3 is connected to a steam generator (boiler) 5 via a pressurized steam supply pipe (pressurized steam supply pipe) 4 provided with a control valve (flow rate adjusting valve) 14 for adjusting a steam supply amount. The steam generator 5 is configured so that high-temperature high-pressure steam can be supplied into the mixing tank 3.
In the mixing tank 3, the infectious waste supplied from the discharge pipe 2 and the high-temperature pressurized steam supplied via the pressurized steam supply pipe 4 are directly mixed, and this high-temperature The infectious waste can be efficiently heated by high-pressure steam.
The mixing tank 3 is connected to a sterilization tank (a kind of sterilization apparatus) 7 through a connecting pipe 6, and infectious wastes heated in the mixing tank 3 are treated with the sterilization tank 7. It is configured so that it can be supplied to.
In the case of this embodiment, the sterilization tank 7 has a stay pipe 7B (stay pipe) having a predetermined length wound in a spiral shape (or meandering zigzag). The length of the staying pipe 7B is such that the time required for the infectious waste to stay in the sterilization tank 7 and sterilize is obtained. The length of the staying pipe 7B is also changed by the flow rate of the infectious waste flowing inside, that is, when the flow rate of the infectious waste flowing through the staying pipe 7B is large, it is necessary to increase the length. When the flow rate is small, the length can be shortened. Assuming that the cross-sectional area of the staying pipe 7B is constant, the flow rate of the infectious waste is directly related to the throughput per unit time. Since it is necessary to increase the length of the retention pipe 7B, it is necessary to increase the length of the retention pipe 7B in proportion to the flow rate. In general, the time during which infectious waste stays in the sterilization tank 7 is approximately 5 to 60 minutes.

The downstream end of the stay pipe 7B in the sterilization tank 7 is connected to a liquid discharge pipe 8, and the infectious waste sterilized in the sterilization tank 7 is generally discharged through the liquid discharge pipe 8. Released into waterways.
A control valve (pressure adjusting valve) 15 is disposed in the liquid discharge pipe 8.

  The sterilization tank 7 is provided with a heating jacket 7A as a heating means on the outer periphery of the sterilization tank 7, and the heating jacket 7A includes the steam generator 5 and the pressurized steam supply pipe 4. The high-temperature pressurized steam is supplied via a heating pressurized steam supply pipe 4B provided with a control valve (flow rate adjusting valve) 16 that is branched and extended from the center. For this reason, the temperature in this sterilization tank 7 can be maintained at a predetermined temperature or higher. And as said temperature more than predetermined, the infectious waste in the said retention pipe 7B has become the temperature of 121 degreeC or more in general. However, as a condition, it may be higher than this temperature, or may be lower than that depending on the type of infectious waste to be treated. In addition, when the stay pipe 7B which becomes the space separated and independent in the tank is used as a stay pipe line in the sterilization tank 7 as in this embodiment, a high temperature and high pressure is used in the sterilization tank 7. A heating means for heating the staying pipe 7B by directly supplying steam may be formed. In such a case, the configuration becomes simple.

  Further, the temperature sensor 17 for detecting the temperature inside the mixing tank 3, in this embodiment, the temperature of the infectious waste inside, is extended to or from the mixing tank 3. The connecting pipe 6 is disposed at a location close to the mixing tank 3. Further, a temperature sensor 18 for detecting the temperature in the warming jacket 7A is also disposed in the warming jacket 7A, and the temperature of infectious waste in the tank is also disposed in the sterilization treatment tank 7. Temperature sensors 19a to 19c for detecting the above are disposed. Further, a temperature sensor 25 for detecting the temperature of the infectious waste after processing discharged from the liquid discharge pipe 8 is also provided in the liquid discharge pipe 8.

  The temperature sensors 17, 18, 19a to 19c, and 25 are connected to a control device 50 that controls the processing equipment via control lines 17A, 18A, 19A to 19C, and 25A, respectively. The temperature information detected by the 17, 18, 19a to 19c is configured to be transmitted to the control device 50.

  The control valves 13, 14, 15, 16 are connected to the control device 50 via control lines 13A, 14A, 15A, 16A. The control device 50 is connected to the control valves 13, 14, 15, 16 “opening / closing operations (operations including an arbitrary“ open ”state”) can be controlled.

Further, in this embodiment, a fresh water tank 10 is provided, and fresh water in the fresh water tank 10 is divided into a supply pump 20 and a fresh water supply pipe 22 branched into two on the way (branched portion pipes 22A and 22B). The fresh water can be supplied to the discharge pipe 2 and the discharge pipe 8 through the above. Control valves (open / close valves) 23 and 24 are provided in the branched pipes 22A and 22B of the fresh water supply pipe 22, respectively. These control valves 23 and 24 are connected to the control device 50 through control lines 23A and 24A, and the control device 50 controls the opening / closing operation (operation including any “open” state). It is configured to be able to.
The control valves 23 and 24 are controlled by a control device 50 so that fresh water can be supplied to the discharge pipe 2 or the liquid discharge pipe 8.

  By the way, in the said Example, although the high temperature steam from the steam generator 5 is used as a heating means of the sterilization processing tank 7, it is not necessarily limited to this, For example, an electric heater, another heater, or Other heating devices can be used.

  And the infectious waste processing facility according to the present embodiment configured as described above can treat infectious waste as follows. Hereinafter, the operation of this processing facility will be described together with the control contents of the control device 50.

In the case where an infectious waste is to be processed by this processing facility, the control device 50 is activated when a main switch (not shown) of this processing facility is turned on. Next, when a processing start switch (not shown) is turned ON, the control device 50 opens the control valves 14 and 16, and transfers the high temperature from the steam generator 5 to the mixing tank 3 and the sterilization processing tank 7. The high pressure steam is supplied, and the mixing tank 3 and the sterilization tank 7 are heated to a predetermined temperature.
Next, the control device 50 turns on the supply pump 11 and “opens” the control valves 13 and 15. As a result, infectious waste in the processing stock solution tank 1 is supplied to the mixing tank 3 through the discharge pipe 2. At this time, since the backflow prevention valve 12 is disposed in the discharge pipe 2, even if the supply pump 11 is stopped, infectious waste flows back through the discharge pipe 2 and the processing stock solution. There is no return to the tank 1 side. The amount of infectious waste supplied to the mixing tank 3 is controlled by the control device 50 controlling the number of rotations of the supply pump 11. This control will be described later. The amount of infectious waste supplied to the mixing tank 3 may be adjusted by controlling the opening degree of the control valve 13.

And since the high-temperature high-pressure steam generated in the steam generator 5 is supplied into the mixing tank 3 through the pressurized steam supply pipe 4, the infectivity supplied into the mixing tank 3. Waste is directly exposed to the high temperature steam in the mixing tank 3 and mixed. For this reason, the infectious waste in the mixing tank 3 is effectively heated. The temperature sensor 17 transmits temperature information to the control device 50 to check whether or not the infectious waste has been heated to a predetermined temperature in the mixing tank 3.
When the temperature information from the temperature sensor 17 is lower than a predetermined temperature, the control device 50 increases the opening of the control valve 14 to increase the amount of high-pressure steam, or If the amount exceeds a predetermined value, the temperature of the infectious waste discharged from the mixing tank 3 is controlled by reducing the rotation speed of the supply pump 11 to reduce the amount of infectious waste. Is controlled to a predetermined value. On the other hand, when the temperature information from the temperature sensor 17 is higher than a predetermined value by a predetermined value or more, the control device 50 reduces the opening of the control valve 14 to reduce the amount of high-pressure steam, Alternatively, control is performed to increase the rotation speed of the supply pump 11.

  In the mixing tank 3, the infectious waste that has been heated as described above is transported to the sterilization tank 7 through the connection pipe 6.

  In the sterilization treatment tank 7, the infectious waste is spent in the stay pipe 7B for a predetermined time, specifically about 5 to 60 minutes. In this embodiment, for example, it takes at least about 20 minutes. Sterilized by passing through. In this sterilization tank 7, the temperature of the infectious waste passing through the stay pipe 7B is maintained at 121 ° C. or higher by the heating jacket 7A. All infectious bacteria are killed.

  And also in this sterilization tank 7, based on the temperature information from the temperature sensor 18 and the temperature sensors 19a to 19c, the control device 50 controls the control valve 16 and the control valve 15 or the supply pump 11 (or the control pump 11). The valve 13) is controlled so that the aforementioned temperature can always be maintained.

  The infectious waste that has been sufficiently detoxified after the infectious bacteria have been killed in this way is discharged (discharged) out of the treatment facility via the outlet pipe 8.

  In the processing equipment configured as described above, the backflow prevention valve 12 (or the control valve 13) and the control valve 15 are provided on the upstream side of the mixing tank 3 and the downstream side of the sterilization processing tank 7, as described above. Since they are arranged, a state in which the space between them is pressurized as compared with the atmospheric pressure can be maintained, and therefore, the temperature of at least 121 ° C. can always be maintained in the sterilization treatment tank 7.

  Further, as described above, in this treatment facility, a plurality of temperature sensors 17, 18, 19a to 19c and a plurality of control valves 13 to 16, 24 are disposed in the treatment process (flow path) of infectious waste. Since these control valves 14-16 (or control valves 13-16), 24 are appropriately controlled by the control device 50 based on the temperature information from the temperature sensors 17, 18, 19a-19c, infectivity A temperature sufficient to sterilize the waste can be stably formed.

  And since the treatment equipment configured in this way can treat infectious waste by so-called “continuous treatment”, and infectious waste and high-temperature high-pressure steam are directly mixed in the mixing tank 3, Even in a compact processing facility, it is possible to process a fairly large amount of infectious waste.

Further, when the treatment of infectious waste is completed, or at every predetermined time interval, the control device 50 closes the control valve 13 to turn on the supply pump 20, and the control valves 23, 24 is opened, the fresh water in the fresh water tank 10 is supplied to the mixing tank 3, the sterilization treatment tank 7, the discharge pipe 2, the connection pipe 6, and the liquid discharge pipe 8, and the fresh water is heated to the temperature. It becomes possible to clean the inside of the mixing tank 3, the sterilization processing tank 7, the discharge pipe 2, the connection pipe 6, and the liquid discharge pipe 8.
The fresh water in the fresh water tank 10 is supplied to the discharge pipe 2 in place of infectious waste when the mixing tank 3 and the sterilization tank 7 are heated to a predetermined temperature at the beginning of use. It may be.
Further, when the temperature of the infectious waste after treatment discharged from the liquid discharge pipe 8 is high, the control device 50 opens the control valve 24 so that the temperature is lowered. When configured to be performed, it is a preferable configuration in that it can be discharged into a general sewer as it is.

  In addition, in the said Example, although the case where sterilization processing (except disinfection processing) was exclusively demonstrated, when performing disinfection processing using this installation, the heating temperature of the said sterilization processing tank (sterilization processing apparatus) 7 Is maintained at a level lower than 121 ° C. (for example, about 110 ° C.), or by shortening the residence time in the residence pipe (retention pipeline) 7B, so-called “disinfection treatment” can be performed more easily. In such a case, a larger amount can be treated as compared with the case of sterilization treatment (excluding disinfection treatment).

  The treatment facility for infectious waste according to the present invention can be used in facilities where infectious waste is generated such as hospitals and inspection institutions.

It is the schematic which shows the whole structure of the processing equipment of the infectious waste concerning one Example of this invention.

Explanation of symbols

1 ... processing stock solution tank
2 ... discharge pipe (discharge pipe)
3 ... Mixing tank (mixer)
4. Pressurized steam supply pipe (pressurized steam supply pipe)
7 ... Sterilization tank (sterilization equipment)
7A ... Warming jacket (heating means)
7B ... Retention pipe (retention pipe line)
12 ... Backflow prevention valve
14 ... Control valve

Claims (4)

Supplying pressurized steam directly to infectious waste , mixing them and raising the temperature, then maintaining the infectious waste at a certain high temperature for a certain period of time and sterilizing it, and then releasing it into a general drainage channel in the processing equipment is capable infectious waste,
This processing equipment
A mixer comprising a pressure vessel for mixing the infectious waste and pressurized steam;
A discharge pipe for supplying infectious waste to be processed to the mixer , comprising a backflow prevention valve for preventing backflow and a control valve capable of opening and closing the flow path and adjusting the flow rate in the middle ,
A pressurized steam supply line for supplying pressurized steam into the mixer;
A staying conduit provided on the downstream side of the mixer and extended for a predetermined length to retain the infectious waste after being heated in the mixer for a predetermined time and sterilizing, and the staying A sterilization apparatus comprising a pressure vessel, which is provided with a heating jacket provided on the outer peripheral portion to supply pressurized steam to the inside in order to heat the pipe line to a predetermined temperature or higher;
A pressurized steam supply line for heating for supplying pressurized steam into the heating jacket of the sterilization apparatus;
A connecting pipe connecting the mixer and the sterilization apparatus;
A drainage pipe for discharging infectious waste that is extended from the downstream end of the sterilization apparatus and sterilized;
A flow rate adjusting valve for adjusting a flow rate or a pressure adjusting valve for adjusting a pressure, which is disposed in the outlet pipe;
A control device for controlling the flow regulating valve or the pressure regulating valve;
An infectious waste treatment facility characterized by comprising: The processing equipment is
A temperature sensor that is disposed at or near the mixer and detects the temperature of the infectious waste in the mixer and transmits the temperature information to the control device;
A temperature sensor that detects the temperature of infectious waste in the sterilization apparatus and transmits the temperature information to the control device;
A control valve which is provided in the pressurized steam supply pipe and adjusts the steam supply amount of the pressurized steam according to a command from the control device;
A control valve which is provided in the heating pressurized steam supply pipe and adjusts the steam supply amount of the pressurized steam according to a command from the control device;
Further comprising
In sterilizing infectious waste, the control device further comprises:
When the detected temperature in the mixer is lower than the desired temperature, control is performed to increase the degree of opening of the control valve of the pressurized steam supply line. Control to reduce the opening of the control valve in the steam supply line,
In addition, when the detected temperature in the sterilization apparatus is lower than a desired temperature, control is performed to increase the opening of the control valve of the pressurized steam supply pipe for heating, while it is higher than a predetermined temperature. 2. The infectious waste treatment facility according to claim 1, wherein in such a case, control is performed to reduce the opening of the control valve of the pressurized steam supply line . The processing equipment further comprises:
A processing stock solution tank containing the infectious waste to be treated;
A supply pump configured to be capable of adjusting a supply flow rate by controlling a rotation speed by the control device, and supplying infectious waste in the processing stock solution tank to the discharge pipe;
With
When the detected temperature in the mixer is lower than a desired temperature, the control device operates to open the control valve of the pressurized steam supply line further or reduces the rotation speed of the supply pump. On the other hand, when the detected temperature in the mixer is higher than a desired temperature, the control valve of the pressurized steam supply line is operated to close more or the rotation speed of the supply pump is increased. as such, infectious waste according to claim 2, characterized by being composed treatment facility. The processing equipment further comprises:
A fresh water tank containing fresh water,
A fresh water supply pipe for supplying fresh water from the fresh water tank to the discharge pipe and the liquid discharge pipe via an on-off valve that is opened and closed under the control of the control device;
Comprising
When the processing of the infectious waste is completed, the control device operates both the on-off valve from closed to open, stops the supply pump, and adds the pressurized steam supply line into the mixer. While supplying pressurized steam, the pressurized steam is supplied from the heating pressurized steam supply line to the heating jacket of the sterilization apparatus, and the mixer and sterilization are performed with fresh water heated to the desired temperature. The infectious waste treatment facility according to claim 3, wherein the treatment device is configured to be washed .

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