JPH07171212A - Method for cleaning artificial dialysis therapeutic apparatus and its apparatus - Google Patents

Abstract

PURPOSE:To provide a method for cleaning an artificial dialysis therapeutic apparatus wherein dialysis waste water treatment can be simplified. CONSTITUTION:The cleaning apparatus is provided with a purified water manufacturing apparatus 1 wherein a raw water is received and is purified into a pure water, an ozone water generator 2 generating an ozone water if necessary, and a dialyzate feeding apparatus 4 receiving a pure water and outputs a dialyzate and this dialyzate feeding apparatus 4 is cleaned with the ozone water.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for cleaning an artificial dialysis treatment apparatus and its apparatus, and more particularly to a method for cleaning an artificial dialysis treatment apparatus using ozone water.

[0002]

2. Description of the Related Art Artificial dialysis treatment is a treatment method for acute renal failure, drug poisoning, chronic renal failure and the like, and its effectiveness is widely recognized as a method for removing waste products and toxic substances in the body of a patient.

FIG. 7 is a block diagram showing such an artificial dialysis treatment device.
Is a dialysate automatic supply device 41, a patient monitoring device 42,
It is composed of an artificial kidney 43 and a bypass passage 44. Moreover, FIG. 8 illustrates an outline of an operation cycle of the artificial dialysis treatment apparatus shown in FIG. 7.

An outline of the operation of the artificial dialysis treatment device 40 will be described below with reference to FIGS. 7 and 8. The preset (ST1) artificial dialysis treatment apparatus needs to be washed for about 30 to 50 minutes before dialysis treatment (ST2). After such washing treatment, dialysate replacement treatment is performed (ST3), and then dialysis treatment treatment (S
Start T4).

At the time of this dialysis treatment (ST4), the patient monitor 42 receives the dialysate from the automatic dialysate feeder 41, supplies it to the artificial kidney 43, and discharges it from the artificial kidney 43. In response to this, it is discharged. While repeating such processing, dialysis treatment is performed for, for example, about 6 hours, and then the artificial dialysis treatment device 40 is washed and disinfected (ST5 to ST7).

In the pre-cleaning process (ST5), water is supplied to the dialysate automatic supply device 41 and the dialysate automatic supply device 4 is supplied.
1 is washed, and the patient monitoring device 42 is washed while the patient monitoring device 42 and the bypass 44 are connected. The time required for these processes is, for example, 30
It's about a minute.

When the pre-cleaning process (ST5) ends, the chemical solution disinfection process (ST6) starts, but the chemical solution disinfection process (ST6)
In, the chemical solution is supplied to the automatic dialysate supply device 41,
The disinfection process of each device 41, 42 is performed in the same manner as the above-mentioned pre-cleaning process. The time required for this processing is, for example, 30 to
It takes about 60 minutes. Here, in the disinfection treatment (ST6), it is general to use a hypochlorous acid-based bactericide.

After the chemical solution disinfection process (ST6) is completed, a post-cleaning process (ST7) is performed. After this, the cleaning process (ST7) is
The same process as the pre-cleaning process (ST5), for example, 3
Each device 41, 42 is washed with water for about 0 minutes.

By the way, the discharged liquid at the time of dialysis treatment (ST4) and at the time of cleaning / disinfecting (ST5 to ST7, etc.) cannot be treated in the combined septic tank because it is wastewater that is not subject to septic tank treatment. A drainage treatment system (see Figure 9) is required. When treating dialysis effluent with this dialysis effluent treatment system, it is fundamental to remove the BOD source to below the effluent standard value by biological treatment.

[0010]

However, in the artificial dialysis treatment apparatus, since a hypochlorous acid type bactericidal agent is used in the disinfection process, this bactericidal agent is a microbial respiratory system enzyme which is the main part of the biological treatment. There is a problem that the biological treatment system does not function effectively because the microorganisms are significantly adversely affected by the inhibition and the termination of the cell assimilation.

Various proposals have been made in order to solve such a problem, but any of these measures has a problem that complicated work is required to eliminate the bactericidal effect in the dialysis wastewater.

The present invention has been made in view of this problem, and an object thereof is to provide a cleaning method for an artificial dialysis treatment apparatus and its apparatus which can simplify the dialysis wastewater treatment.

[0013]

In order to achieve the above-mentioned object, a method for cleaning an artificial dialysis treatment device according to a first aspect of the present invention comprises a purified water producing device for receiving raw water and purifying the purified water into pure water. An ozone water generator that generates ozone water in response, and a dialysate supply device that receives pure water and outputs a dialysate are provided.
This dialysate supply device is characterized by being washed with the ozone water.

An artificial dialysis treatment apparatus according to a second aspect of the present invention comprises a purified water producing apparatus for receiving raw water and purifying the purified water into pure water, and an ozone generating apparatus for generating ozone as necessary.
A switch that selectively operates in response to the outputs of the purified water producing device and the ozone generator, outputs pure water directly during dialysis treatment, and outputs pure ozone water by mixing pure water and ozone during cleaning treatment. The mixing section and the dialysate supply device that receives the output of the switching mixing section are characteristically provided.

An artificial dialysis treatment apparatus according to a third aspect includes a purified water producing apparatus for receiving raw water and purifying the purified water into pure water, a first output section and a second output section, and the dialysis treatment apparatus is used for the dialysis treatment. A switching unit that outputs pure water from the purified water manufacturing device from the first output unit and outputs pure water from the purified water manufacturing device from the second output unit during the cleaning process, and a second output unit of this switching unit. An ozone water generator that is connected and receives pure water from the switching unit to generate ozone water, and is connected to the output unit of the ozone water generator and the second output unit of the switching unit to receive the pure water. And a dialysate supply device for performing a cleaning treatment operation by receiving ozone water.

[0016]

According to the present invention, the dialysate supply device and the auxiliary device are washed with ozone water. Since this ozone water has a bactericidal action, it is not necessary to use a hypochlorous acid type disinfectant as in the past.

[0017]

The present invention will be described in more detail based on the following examples. FIG. 1 illustrates an artificial dialysis treatment device including a cleaning device according to an embodiment of the present invention.

This apparatus receives a purified water producing apparatus 1 for purifying RO water by removing ions and bacteria from raw water, an ozone generator 2 for producing ozone by an electrolysis method, and a purified water producing apparatus 1. Output RO water as it is,
Alternatively, it is composed of a switching mixing section 3 which mixes ozone with this and outputs it, and a dialysate supply device 4 which receives RO water or ozone water from the switching mixing section 3. In addition,
The dialysate output from the dialysate supply device 4 is supplied to the artificial kidney, for example, via the patient monitoring device (see FIG. 7).

In FIG. 1, a purified water producing apparatus 1 is for purifying raw water into pure water based on a reverse osmosis method RO (reverse osmosis).
And a pretreatment unit 6, a check filter 7, a reverse osmosis membrane (RO membrane) module unit 8, a water storage tank 9, and pumps P ₁ , P ₂ and P ₃ (see FIG. 2). .

Raw water (tap water or well water) is pressurized by the raw water pump P ₁ and added to the pre-filter 5 as required. The pre-filter 5 is, for example, a filter of about 25 μm and removes coarse dust in the raw water. next,
In the pretreatment unit 6, the residual chlorine in the raw water is removed by the activated carbon, and the hardness component (calcium, magnesium, etc.) in the raw water is removed by the soft water resin.

After that, fine particles in the raw water and leaked particles of activated carbon and ion exchange resin are removed by a check filter 7 of about 5 μm, and then supplied to the reverse osmosis membrane module section 8 by the action of the high pressure pump P _2. To be done. In the reverse osmosis membrane module section 8, ions, bacteria, pyrogen, etc., which could not be removed by the pretreatment section 6, are removed by the action of the reverse osmosis membrane. Through the above processing, the raw water is purified to pure water, so that the RO water is fed by the water pump P.
It is supplied to the switching mixing section ₃ by 3.

The ozone generator 2 is a device for generating ozone by an electrolysis method. For example, as shown in FIG.
Electrolysis tank 10, gas-liquid separation tank 11, DC power supply device 1
It is composed of 2 etc. Here, the electrolytic cell 10 is composed of a pair or a plurality of anodes T ₁ and cathodes T ₂ , a cation exchange membrane 13 and the like. The porous electrodes are in close contact with both sides of the cation exchange membrane 13, and pure water is supplied to the anode chamber through the gas-liquid separation tank 11.

Therefore, pure water (H ₂ O) is electrolyzed into oxygen and hydrogen in the anode chamber, a mixed gas of ozone O ₃ and oxygen O ₂ is produced from the anode T ₁ , and hydrogen is produced from the cathode T _2. Gas H
₂ occurs. Ozone O ₃ thus generated is
It is separated from pure water in the gas-liquid separation tank 11 and output.

The switching mixing section 3 is a section that selectively operates depending on whether it is during dialysis treatment or during cleaning treatment. During dialysis treatment, RO water from the purified water producing apparatus 1 is directly output, During the cleaning process, RO water from the purified water producing apparatus 1 and ozone from the ozone generating apparatus 2 are mixed to output ozone water. Instead of RO water, tap water may be deionized with ion exchange resin or the like to use pure water.

The dialysate supply device 4 is a device for supplying dialysate to the artificial kidney during dialysis treatment.
As shown in, the dilution water tank 14 and the mixing tank 15
And a dialysate tank 16 and the like. The operation of each part of the dialysate supply device 4 will be described for cases other than during the cleaning process.
Water is first stored in the dilution water tank 14, and heated by the heater 17 and circulated by the degassing pump 18 to be heated and degassed.

The mixing tank 15 has a stock solution A tank 19 for liquid A.
And the undiluted solution from liquid B undiluted solution tank 20 is diluted water tank 14
It is mixed with the dilution water from and is stirred by the stirring pump 21. Then, the dialysate that has undergone such processing is transmitted to and stored in the dialysate tank 16, and the liquid transfer pump 22
Is supplied to the patient monitoring device. When the dialysis treatment process for about 6 hours is completed while repeating the above operation, it is necessary to perform the disinfection / washing process.

As described above, in this disinfection / cleaning process, RO water and ozone are mixed in the switching mixing section 3, and this ozone water is supplied to the dialysate supply device 4. The ozone water is first drained by washing the diluting liquid tank 14, then washing the mixing tank 15 and the dialysate tank 16. In the case of the conventional device, the dilution water tank 14
Was only washed with water, but in the case of the present invention, since it is washed with ozone water, the cleaning effect can be ensured. Further, in the conventional apparatus, disinfection was carried out using a hypochlorous acid type disinfectant, but in the present invention, since all disinfection is performed with ozone water, wastewater treatment becomes easy.

More specifically, in the case of the conventional device, the dialysis wastewater treatment device 30 as shown in FIG. 9 was indispensable. Then, first, the storage tank 31 is designed to make the drainage uniform.
In the reaction tank 32, acid and alkali are injected from the liquid tanks 34 and 35 in the reaction tank 32 based on the signal from the PH electrode 33 to pre-neutralize to a neutral range, and then the pH adjustment range is narrowed. Based on the signal from the ORP electrode 36, the reducing agent was injected from the chemical liquid tank 37 to eliminate the bactericidal agent.

However, according to the present invention, since sterilization and cleaning are performed with ozone water without using a sterilizing agent, it is not necessary to inject an acid such as sulfuric acid or a reducing agent, and the treatment can be simplified. Becomes That is, the sulfuric acid or the like in the liquid tank 34 is for neutralizing sodium hypochlorite, and the reducing agent in the chemical liquid tank 37 is for reducing the oxidizing power of sodium hypochlorite. In the present invention in which the cleaning / disinfecting treatment is performed with water, neither the acid nor the reducing agent is required.

Further, in the present invention, instead of the neutralization treatment by the alkali injection, the drainage liquid can be neutralized with calcium carbonate, coral sand or the like, which would further simplify the treatment and reduce the equipment cost. Can be reduced. The wastewater after the neutralization treatment is added to the contact aeration tank 38, and the biofilm adhering to the contact filter medium oxidizes and decomposes organic substances to remove the BOD source. In the case of conventional equipment,
In some cases, this biological treatment did not work effectively,
In the present invention, since the disinfection / cleaning treatment is performed with ozone water, the BOD value can be surely reduced.

The separated biofilm is sent to the disinfecting tank only for the water that has been settled and separated in the settling tank 39, and is sterilized by chlorine in the disinfecting tank 40 to be water that does not impair hygiene before being discharged. .

Next, another embodiment of the present invention will be described with reference to FIG. This apparatus comprises a purified water production apparatus 1a for purifying raw water into pure water, an ozone water generator 2a for receiving pure water to generate ozone water, and a dialysate supply apparatus 4a for receiving pure water and outputting a dialysate. And ozone water generator 2
a and a dialysate supply device 4a, and a switching unit 3a for supplying pure water to only one of them.

The ozone water producing apparatus 2a is not particularly limited as long as it produces ozone water, but it is also possible to use, for example, one that produces ozone by a silent discharge method. Specifically, it suffices to supply ozone from an oxygen cylinder or the like to a high-voltage (several KV) discharge field and mix the generated ozone with pure water to produce ozone water.

The output switching unit 3a operates manually or automatically, supplies pure water to the dialysate supply unit 4a during dialysis treatment, and produces pure water into ozone water during disinfection / cleaning processing. Supply to the device 2a. Also in the device shown in FIG. 5, since the dialysate supply device 4a is washed using ozone water, there are the same advantages as those of the device in FIG.

The configuration of the apparatus is not limited to those shown in FIGS. 1 and 5, but may be appropriately changed as long as the dialysate supply apparatus is washed with ozone water. For example, in FIG.
As shown in (a), the RO has a built-in ozone water generator.
A water / ozone water production apparatus 1b may be provided to selectively output RO water or ozone water. Further, as shown in FIG. 6B, a dialysate supply device 4c having a built-in ozone water generator.
Alternatively, the cleaning operation may be performed by the ozone water generated by itself.

[0036]

As described above, the cleaning method for an artificial dialysis treatment apparatus and the apparatus according to the present invention use ozone water to sterilize and clean the apparatus. In other words, since it is not necessary to use a hypochlorite-based disinfectant, complicated work for eliminating the bactericidal effect in dialysis wastewater is not required, which simplifies dialysis wastewater treatment and reduces the cost of the entire system. Can be planned.

[Brief description of drawings]

FIG. 1 is a block diagram showing a main part of an artificial dialysis treatment device according to an embodiment of the present invention.

FIG. 2 is a block diagram of a purified water producing device.

FIG. 3 is a block diagram of an ozone generator.

FIG. 4 is a block diagram of a dialysate supply device.

FIG. 5 is a block diagram showing a main part of an artificial dialysis treatment apparatus which is another embodiment of the present invention.

FIG. 6 is a block diagram showing a main part of an artificial dialysis treatment device which is still another embodiment of the present invention.

FIG. 7 illustrates the overall configuration of an artificial dialysis treatment device.

FIG. 8 illustrates an operating cycle of the device shown in FIG. 7.

FIG. 9 is a block diagram illustrating an example of a dialysis wastewater treatment device.

[Explanation of symbols]

 1 Purified Water Production Device 2 Ozone Generator 3 Switching Mixing Section 4 Dialysate Supply Device

Claims (5)

[Claims] 1. A purified water producing apparatus for receiving raw water and purifying it into pure water, an ozone water generating apparatus for generating ozone water as necessary, and a dialysate supply for receiving pure water and outputting a dialysate. And a device for cleaning the dialysate supply device with the ozone water. 2. A purified water producing device that receives raw water and purifies it into pure water, an ozone generator that generates ozone as necessary, and an output of the purified water producing device and the ozone generator. Selective operation, direct output of pure water during dialysis treatment, and output of ozone water by mixing pure water and ozone during cleaning, and dialysate supply that receives the output of this switching mixing section An artificial dialysis treatment device comprising: a device. 3. A purified water producing apparatus for receiving raw water and purifying the purified water into pure water, a first output section and a second output section, and the pure water from the purified water producing apparatus is used for dialysis treatment. A switching unit that outputs the pure water from the purified water producing device from the second output unit during the cleaning process, and a pure water from the switching unit that is connected to the second output unit of the switching unit. An ozone water generator that receives ozone water and is connected to an output section of the ozone water generator and the second output section of the switching section, receives pure water to perform a dialysis treatment operation, An artificial dialysis treatment device comprising: a dialysate supply device that receives and performs a cleaning process operation. 4. The artificial dialysis treatment apparatus according to claim 3, wherein the purified water producing apparatus, the switching unit, and the ozone water generating apparatus are integrated. 5. The artificial dialysis treatment device according to claim 3, wherein the switching unit, the ozone water generator, and the dialysate supply device are integrated.