KR101012191B1 - Apparatus to produce hemo dialysate and method to produce hemo dialysate - Google Patents

Abstract

PURPOSE: A renal dialysate preparation device and a renal dialysate preparation method are provided, which makes fixed number process of a reverse osmosis purification unit unnecessary. CONSTITUTION: A renal dialysate preparation device comprises: a main movement pipe which forms a movement route of water flowing in from the outside and in which a renal dialysis is installed in the rear end; a first water purification unit(140) processing water flown into the main movement pipe into purified water; a reverse osmosis purification unit(150) purifying the water passed through the first water purification unit by reverse osmosis; a second water purification unit(160); and a by-pass movement pipe(190).

Description

Apparatus to produce hemo dialysate and method to produce hemo dialysate}

An apparatus for producing kidney dialysis water and a method for producing kidney dialysis water are disclosed. More specifically, kidney dialysis can be moved to the second pure water treatment unit by a bypass transfer pipe without passing through the reverse osmosis water purification unit, without having to go through the reverse osmosis water purification unit, so that the pure water treatment process can be performed flexibly. Disclosed are a water production apparatus and a kidney dialysis water production method.

In general, hemodialysis, peritoneal dialysis, and kidney transplantation may be used to maintain life for patients with chronic heart failure who have lost kidney function due to various diseases.

Among them, hemodialysis is based on the principle of eliminating endotoxins in the blood of patients by ultrafiltration, diffusion, convection, etc. using a semipermeable membrane. In this principle of hemodialysis, dialysis water that strikes the blood with a semi-permeable membrane interspersed with purity, which allows urinary toxins in the blood to escape into the dialysis water, whereas substances in the dialysis water may enter the blood. Because there is. In this case, if the substances introduced into the blood are harmful to the human body, a serious situation may occur that may interfere with life.

In other words, even a small number of bacteria in the hemodialysis water can easily proliferate in the dialysis water, thereby releasing a large amount of toxic substances, that is, endotoxins. The rapid propagation of these bacteria makes it easier to reach a concentration of hematoma endotoxin sufficient to cause side effects in patients. In addition, endotoxins can migrate from the dialysis water into the bloodstream in both low and high flow dialysis membranes. In particular, in conventional hemodiafiltration, contaminants of dialysis water may enter the bloodstream of the patient.

Thus, for example, high concentrations of endotoxins in dialysis water can have a significant impact on life, and if, for example, low concentrations of endotoxins enter the bloodstream over time, they will continue to develop an inflammatory response over time. This can lead to many complications, infections, amyloidosis, arteriosclerosis or cardiovascular disease.

Therefore, the water quality management of the water constituting the dialysis water is very important, accordingly, it is urgent to develop a kidney dialysis water production apparatus and a kidney dialysis water production method of a new structure that can produce the kidney dialysis water more clean than before.

The object according to the embodiment of the present invention is that the water purified by the first pure water treatment unit can be moved to the second pure water treatment unit by a bypass moving tube without passing through the reverse osmosis water purification unit. It is an object of the present invention to provide an apparatus for producing kidney dialysis water and a method for producing kidney dialysis water, which can continuously carry out pure water treatment operations even when the water purification process of the water purification unit is unnecessary or the reverse osmosis water purification unit fails.

In addition, an object according to an embodiment of the present invention, by providing a pure dialysis water to the patient by treating the water purely in a multi-stage, and thus an apparatus and method for producing kidney dialysis water for improving the reliability of hemodialysis To provide.

In addition, the object according to the embodiment of the present invention, because the device can be cleaned by the cleaning unit, it is possible to prevent the contamination of the water to be treated purely by the configuration of the device, as well as to extend the replacement period of the equipment It is to provide an kidney dialysis water production apparatus and a manufacturing method.

Kidney dialysis water production apparatus according to an embodiment of the present invention, the movement path of the water introduced from the outside, the rear end is the main moving tube equipped with the kidney dialysis machine; A first pure water treatment unit mounted to the main moving tube and configured to primarily process the water introduced into the main moving tube to pure water; A reverse osmosis water purification unit mounted on the main moving tube so as to be located at the rear of the first pure water treatment unit and treating the water having passed through the first pure water treatment unit by a reverse osmosis principle; A second pure water treatment unit mounted on the main moving tube so as to be disposed between the reverse osmosis water purification unit and the kidney dialysis machine, and subsequently purifying the water passing through the reverse osmosis water purification unit; And the main moving tube connecting the first pure water treatment unit and the reverse osmosis water purification unit, and the main moving tube connecting the reverse osmosis water purification unit and the second pure water treatment unit, wherein the water is It may include; bypass mobile pipe to be moved directly without passing through the reverse osmosis water purification unit; by this configuration, the water purified by the first pure water treatment unit without passing through the reverse osmosis water purification unit, bypass transfer pipe Since it can move to a 2nd pure water treatment unit, even if the water purification process of a reverse osmosis water purification unit is unnecessary or a reverse osmosis water purification unit breaks down, the pure water treatment operation of water can be performed continuously.

The kidney dialysis water production apparatus is connected to the main moving pipe in communication with the main mobile pipe is mounted on the washing mobile pipe having a separate circulation path, by supplying the cleaning liquid to the main moving pipe, the first pure water treatment unit, the reverse osmosis It may further comprise a cleaning unit of the Clean In Place Solution (CIP) type for cleaning at least one of the purified water unit, the second pure water treatment unit and the bypass transfer pipe, thereby the water to be treated purely by the configuration of the device This can not only prevent contamination, but also extend the replacement period of the equipment.

The apparatus for producing kidney dialysis water further includes a feed pump unit which is mounted to the front end of the main moving tube prior to the first pure water treatment unit and introduces the water into the main moving tube, wherein the feed pump unit includes: A first feed pump mounted to a main moving tube and configured to adjust the flow rate and pressure of the water; And a second feed pump mounted on the main moving tube to be parallel to the first feed pump, and configured to adjust the flow rate and pressure of the water, wherein the first feed pump and the second feed pump are simultaneously operated and individually driven. This is possible.

The first pure water treatment unit may include a media filter mounted to the main moving tube to reduce turbidity of the water and to remove and remove contaminants contained in the water; And a softener filter mounted to the main moving tube and configured to soften the water.

The media filter includes a filter housing forming an appearance; A gravel disposed below in the filter housing; Sand disposed on an upper portion of the grabble; Activated carbon disposed on top of the sand; And anthracite disposed on top of the activated carbon.

The first pure water treatment unit may further include a pre-filter mounted on the main moving tube so as to be disposed at the rear of the softner filter, and filtering a suspended substance of a predetermined size or more contained in the water.

The reverse osmosis water purification unit may include: a reverse osmosis water purification pump mounted on the main moving tube to generate a driving force for moving the water purified by the first pure water treatment unit; And it may include a reverse osmosis water purification unit for treating the water introduced by the reverse osmosis water purification pump by the reverse osmosis principle.

The second pure water treatment unit may include: a storage tank mounted to the main moving tube and configured to store the water subjected to reverse osmosis purification by the reverse osmosis purification unit; A polisher filter mounted to the main moving tube so as to be located at the rear of the storage tank, and removing a ionic component contained in the water by using a resin in which a cation exchange resin and an anion exchange resin are mixed; And a final filter mounted on the main moving tube so as to be positioned at the rear of the polisher filter, and finally filtering a suspended matter of a predetermined size or more contained in the water.

The storage tank may include a tank body in which the water is stored; A heater unit mounted in the tank body to heat the water supplied from the reverse osmosis water purification unit to a predetermined temperature; And an ultraviolet sterilizer mounted in the tank body so as to be partially immersed in the water in the tank body and removing germs in the water by emitting ultraviolet rays.

The final filter may be a filtration filter for filtering a suspended matter having a size of 0.2 micrometer among the suspended matter contained in the water, or a superfiltration filter having a suspended matter having a size of 0.03 micrometer among the suspended matter contained in the water.

The second pure water treatment unit is mounted to the main moving tube so as to be located between the storage tank and the final filter, and generates a driving force for supplying the water of the storage tank to the polisher filter for a time set in an automatic timer. Further comprising a feed pump, the feed pumps may be provided in pairs in parallel to run simultaneously or separately.

At least one of the main moving tube and the bypass moving tube may be provided as a pex pipe made of a crosslinked polyethylene material.

On the other hand, kidney dialysis water production method according to an embodiment of the present invention, the inflow step of introducing external water into the main moving tube; A first pure water treatment step of firstly treating the introduced water by a first pure water treatment unit; A second pure water treatment step of subsequently purifying the water using the second pure water treatment unit; And dialysis of the purified water using the kidney dialysis machine to the patient; dialysis step; and, if the water is reverse osmosis after the first pure water treatment step, the pure water using the reverse osmosis purification unit And further comprising a reverse osmosis water purification step for purifying the treated water by a reverse osmosis principle, when the reverse osmosis water purification step is not executed, the main pure water connecting unit and the reverse osmosis water purification unit are connected. And moving the water to the bypass moving tube connecting the moving tube and the main moving tube connecting the reverse osmosis water purification unit and the second pure water treatment unit. Water purified by the pure water treatment unit may be moved to the second pure water treatment unit by a bypass transfer pipe without passing through the reverse osmosis water purification unit. Therefore, the pure water treatment operation of water can be continuously performed even if, for example, the water purification process of the reverse osmosis water purification unit is unnecessary or the reverse osmosis water purification unit is broken.

The kidney dialysis water production method, by supplying the washing liquid from the washing unit to the main moving tube, the first pure water treatment unit, the reverse osmosis water purification unit, the reverse osmosis unit mounted on the path of the main moving tube as well as the main moving tube It may further comprise a washing step of washing at least one of the pure water treatment unit and the bypass transfer pipe.

In the first pure water treatment step, the turbidity reduction and adsorption removal step of adsorption and removal of taste, odor, color, residual chlorine, residual detergent or residual organic matter contained in the water while lowering the turbidity of the water by the media filter. ; A softening step of softening the water by the softener filter; And a pre-filtering step of filtering the suspended matter of a predetermined size contained in the water by the pre-filter.

The second pure water treatment step may include: storing the reverse osmosis purified water; A supplying step of supplying the water of the storage tank toward the kidney dialysis machine by the operation of the supply tank; Removing the ionic component contained in the water by the polisher filter; And a final filtering step of finally filtering the suspended matter having a predetermined size contained in the water by the final filter.

According to the embodiment of the present invention, since the water purely treated by the first pure water treatment unit can be moved to the second pure water treatment unit by a bypass moving tube without passing through the reverse osmosis water purification unit, for example, the reverse osmosis water purification unit Even if the water purification process is not necessary or the reverse osmosis water purification unit has failed, the pure water treatment operation can be continuously performed.

In addition, according to an embodiment of the present invention, by treating the water purely in multiple stages can provide a clean dialysis water to the patient, thereby improving the reliability of hemodialysis.

In addition, according to the embodiment of the present invention, since the device can be cleaned by the cleaning unit, it is possible to prevent contamination of the water to be treated purely by the configuration of the device, as well as to extend the replacement period of the equipment.

1 is a view schematically showing the configuration of the apparatus for producing kidney dialysis water according to the first embodiment of the present invention.
FIG. 2 is a diagram schematically illustrating an internal configuration of the media filter illustrated in FIG. 1.
FIG. 3 is a diagram schematically illustrating an internal configuration of the polisher filter illustrated in FIG. 1.
Figure 4 is a flow chart of the kidney dialysis water preparation method according to a first embodiment of the present invention.
5 is a flowchart detailing the flowchart of FIG. 4.
6 is a view showing a schematic configuration of a device for producing kidney dialysis water according to a second embodiment of the present invention.
7 is a view showing a schematic configuration of the kidney dialysis water production apparatus according to a third embodiment of the present invention.
8 is a view showing a schematic configuration of the kidney dialysis water production apparatus according to a fourth embodiment of the present invention.

Hereinafter, configurations and applications according to embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The following description is one of several aspects of the patentable invention and the following description forms part of the detailed description of the invention.

1 is a view schematically showing the configuration of the kidney dialysis water production apparatus according to a first embodiment of the present invention, Figure 2 is a diagram showing the internal configuration of the media filter shown in Figure 1, Figure 3 FIG. 1 is a diagram schematically showing an internal configuration of the polisher filter shown in FIG. 1.

As shown in the drawing, the kidney dialysis water production apparatus 100 according to the first embodiment of the present invention forms a movement path of water introduced from the outside, the rear end of the main moving pipe 120 is equipped with the kidney dialysis machine 110 ), A feed pump unit 130 that maintains and regulates the amount and pressure of water introduced from the outside, a first pure water treatment unit 140 for firstly purifying water passing through the feed pump unit 130, and 1 Reverse osmosis water purification unit 150 for purifying water that has passed through the pure water treatment unit 140 using the reverse osmosis principle, and water that has passed through the reverse osmosis water purification unit 150 is subsequently purified. The second pure water treatment unit 160 and the water passing through the first pure water treatment unit 140 may be directly supplied to the second pure water treatment unit 160 without passing through the reverse osmosis water purification unit 150. Bypass moving tube 190 separately connected to 120 It may include a cleaning unit 195 for cleaning the above-mentioned configuration.

With this configuration, the water introduced from the outside is preferentially purified by the first pure water treatment unit 140 and then optionally reverse osmosis by the reverse osmosis water purification unit 150, followed by the second pure water treatment unit. Subsequently, pure water is processed by the 160 to provide clean dialysis water to the body through the kidney dialysis machine 110.

In addition, it is possible to clean the above-described components with the cleaning liquid of the cleaning unit 195, so that the pure water treatment operation for the water can be performed in a clean environment, thereby improving the pure water treatment efficiency of the water as well as improving the life of the device. Can be extended.

Referring to each configuration, first, the main moving tube 120 of the present embodiment, as well as forming the movement path of the water flowing from the outside as well as the respective components are mounted in one configuration is pure water or reverse osmosis purified water in the following configuration It can be moved to the configuration of. The main moving pipe 120 is equipped with a plurality of valves can not only turn on / off the flow of water, but also can adjust the flow rate and pressure of the water.

Here, the plurality of valves are composed of a sample valve 123, a needle valve 124, a check valve 125 or a three-piece ball valve 126, these valves, as shown in FIG. Can be provided on the path of 120 to determine the flow rate, pressure or direction of the water.

In addition, although not shown in the main moving tube 120, a pressure gauge for measuring the pressure, an electrical conductivity meter for measuring the electrical conductivity, a resistivity measuring the specific resistance, a level control sensor for adjusting the water level, a water level meter for measuring the water level, A flow meter for measuring the flow rate, a low pressure switch for applying a low pressure, a high pressure switch for applying a high pressure, a thermometer for measuring the temperature and the like can be mounted.

The main moving tube 120 of the present embodiment does not form only one path, but serves to split the flowing water by branching or rejoining or vice versa. Referring to FIG. 1, the main moving tube 120 to which the feed pump unit 130 to be described later is mounted has a structure in which it is divided into two parts and then jointed again.

The main moving tube 120 of the present embodiment may be provided with a pex pipe made of a crosslinkable polyethylene material, and thus, excellent flexibility and easy installation may be expected, as well as excellent durability and corrosion resistance. However, the material of the main moving tube 120 is not limited thereto, and may be provided of other materials, for example, stainless steel.

On the other hand, the feed pump unit 130 of the present embodiment, as shown in Figure 1, the first feed pump 131 and the first feed pump (131) mounted on the main moving pipe 120 to adjust the flow rate and pressure of water ( It may be provided with a second feed pump 132 mounted on the main moving pipe 120 to adjust the flow rate and pressure of the water so as to be parallel to the 131.

In the present embodiment, the first feed pump 131 and the second feed pump 132 may be operated at the same time as well as alternately. When the first feed pump 131 and the second feed pump 132 are left at rest for a long time, microorganisms may propagate in the water accumulated in the feed pumps 131 and 132. By alternately operating the 131 and the second feed pump 132, not only problems such as microbial propagation can be prevented, but also when one feed pump 131 or 132 fails, the other feed pump 131 or 132 ), The external water inflow can be smoothly performed.

On the other hand, the first pure water treatment unit 140 of the present embodiment is a configuration for treating the water introduced by the feed pump unit 130, the pure water, as shown in Figure 1, not only reduce the turbidity of the water, but also the organic matter of the water A media filter 141 for adsorbing and removing the back light, a softener filter 148 for softening the water by removing the hardness material contained in the water, and a floating material having a predetermined size or more. It may include a pre-filter 149 for further filtering.

Each of these filters will be described. First, the media filter 141 of the present embodiment includes a filter housing 142 that forms an internal space for filtering, and a grabble 143 disposed at a lower end of the filter housing 142. , gravel, sand 144 disposed on top of the gravel 143, activated carbon 145 disposed on the top of the sand 144, and activated carbon 145 disposed on the top of the sand 144. Anthracite (146).

Here, the grabble 143, the sand 144, and the anthracite 146 may reduce turbidity of water, and the water introduced into the media filter 141 through the main moving pipe 120 may include the grabble 143, Passing through the sand 144 and anthracite 146 can filter over 20 microns of suspended solids, thereby lowering the turbidity of the water.

In addition, the activated carbon 145 of the media filter 141 may adsorb and remove tastes, odors, colors, residual chlorine, residual detergents, and some organic substances contained in water. In other words, the activated carbon 145 may not only remove organic organic matters such as synthetic organic materials, chlorine sterilization by-products such as THM, or humus, which is a cause of these by-products, but also reduce the performance of the ion exchange resin during pure water treatment. It is possible to improve the efficiency of pure water treatment by taking care of the removal of organic substances such as residual chlorine, which have a great effect.

The softener filter 148 of the present embodiment is a filter for softening water by removing hard materials dissolved in water and heavy metals such as calcium, magnesium, sodium, and the like, and filtering the softner filter 148. By this, the pure water treatment efficiency of water can be improved.

In addition, the pre-filter 149 of the present embodiment includes suspended substances having a predetermined size before the purified water is introduced into the reverse osmosis water purification unit 150 through the aforementioned filters 141 and 148. For example, by filtering the suspended matter of 5 micrometers once more, high-purity pure water may be introduced into the reverse osmosis water purification unit 150.

As described above, the first pure water treatment unit 140 of the present embodiment may remove impurities through the plurality of filters 141, 148, and 149, and then introduce water into the reverse osmosis water purification unit 150. When the reverse osmosis process of the reverse osmosis water purification unit 150 is in progress, the reverse osmosis membrane may be protected, and the device life may be extended.

Meanwhile, referring to FIG. 1, water may move from the feed pump unit 130 to the prefilter 149 via the media filter 141 and the softener filter 148, but may have passed through the feed pump unit 130. Water may flow into the pre-filter 149 directly after passing through the separately opened moving pipe (120a). This may be performed when the purity of the water flowing into the main moving pipe 120 is high, and as will be described later, since the pure water treatment process will be performed by the second pure water treatment unit 160, the water to be treated with reverse osmosis water may be filtered. It can be moved directly to the pre-filter 149 without passing through the 141, 148.

Meanwhile, as shown in FIG. 1, the reverse osmosis water purification unit 150 according to the first embodiment of the present invention is mounted on the main moving tube 120 and treated with pure water by the first pure water treatment unit 140. Reverse osmosis water purification pump 151 for generating a driving force for moving the reverse osmosis water purification pump 151, and reverse osmosis water purification unit 153 for water purification by the reverse osmosis principle.

The reverse osmosis water purification unit 150 may have a circulation structure, as shown in FIG. 1, whereby the reverse osmosis purified water may be circulated by the circulation movement pipe 120b to receive the reverse osmosis purified water again. . In addition, the discharge unit 155 is connected to the above-described circulation movement pipe 120b to discharge the water of the reverse osmosis water purification unit 150 to the outside as necessary.

The reverse osmosis water purification unit 153 of the present embodiment is configured to reverse osmosis water purification using the opposite principle of osmosis. In other words, the osmotic phenomenon is a phenomenon in which a low concentration of solvent moves to a high concentration solution with a semi-permeable membrane interposed therebetween. When the chemical potentials of both solvents are the same, the movement of the solvent is stopped and the osmotic pressure difference is generated as much as the head pox difference. At this time, when the pressure of the osmotic pressure difference or more is applied to the high concentration solution side, the solvent on the high concentration solution side flows back to the low concentration solution side as opposed to the osmotic phenomenon is called reverse osmosis phenomenon. In other words, in this embodiment, the water introduced into the reverse osmosis water purification unit 153 may be reverse osmosis purified water by using the reverse osmosis phenomenon.

On the other hand, the second pure water treatment unit 160 of the present embodiment, after purely treating the reverse osmosis purified water by the reverse osmosis purification unit 150 once more, and sends the purified water to the kidney dialysis machine 110. Play a role.

As shown in FIG. 1, the second pure water treatment unit 160 includes a storage tank 170 for storing the water reversely purified by the reverse osmosis purification unit 150 and a storage tank 170. A feed pump 180 for supplying the stored water to the kidney dialysis machine 110, a polisher filter 181 disposed at the rear of the feed pump 180 to remove ions contained in the water, and a polisher filter A final filter 185 may be provided at the rear of 181 to finally filter the water passing through the polisher filter 181.

Referring to each configuration, first of all, the storage tank 170 of the present embodiment is mounted in the tank main body 171 and the tank main body 171 in which water moved from the reverse osmosis water purification unit 150 is stored, and thus the tank main body. A heater unit 172 for applying heat to the water stored in the 171, an air filter (173, air filter) mounted on the tank main body 171 to filter the outside air into the tank main body 171, and the tank It may include a level control system 175 for adjusting the water level by sensing the water level stored in the main body 171, and an ultraviolet sterilizer 174 for extinguishing the bacteria in the water by ultraviolet light.

In the above configuration, the heater unit 172 of the present embodiment serves to disinfect the tank body 171 or the main moving tube 120 connected to the tank body 171 by providing heat of a predetermined temperature. That is, by transferring high temperature heat, bacteria in the tank body 171 and the main moving tube 120 may be removed, thereby improving the purity of the water stored in the tank body 171.

In addition, the ultraviolet sterilizer 174 is provided in a lamp shape in which a predetermined portion is immersed in the water in the tank main body 171, and by dissipating ultraviolet rays, it is possible to eradicate bacteria and the like contained in the water.

As shown in FIG. 1, the polisher filter 181 of the present exemplary embodiment includes a resin 183, which is accommodated in the polisher housing 182 and the polisher housing 182 and mixed with a cation exchange resin and an anion exchange resin. resin). Here, the resin 183 may remove the ionic component from the water flowing into the polisher housing 182. In detail, the removal rate of the ionic component in the reverse osmosis water purification unit 150 described above is in units of percent (one hundredth), but in the polisher filter 181, the removal of the ionic component in ppm (one hundred thousandths) is calculated. This can further improve the pure water treatment efficiency of water.

The final filter 185 of the present embodiment is a configuration for finally filtering the water sterilized and disinfected by the storage tank 170. The final filter 185 of the present embodiment can remove the suspended matter of the killed bacteria. . That is, according to the operation of the storage tank 170 described above, the bacteria are killed and the killed bacteria may be contained in water and moved to the final filter 185, where the final filter 185 is small in size, for example, 0.2. By filtering the suspended matter of the micrometer so that clean water can be delivered to the kidney dialysis machine 110 to be described later.

On the other hand, as described above, in the kidney dialysis water production apparatus 100 of the present embodiment, the water passed through the first pure water treatment unit 140 does not go through the reverse osmosis water purification unit 150, the second pure water treatment unit 160. It may further include a bypass moving pipe 190 that is separately connected to the main moving pipe 120 to be supplied directly to).

Referring to FIG. 1, the bypass moving pipe 190 of the present embodiment includes a main moving pipe 120 connecting the first pure water treatment unit 140 and the reverse osmosis water purification unit 150, and a reverse osmosis water purification unit 150. And a main moving tube 120 connecting the second pure water treatment unit 160 so that the water passing through the first pure water treatment unit 140 does not pass through the reverse osmosis water purification unit 150 and immediately passes through the second pure water. May be moved to the processing unit 160.

Therefore, the pure water treatment efficiency of the first pure water treatment unit 140 is excellent, or the reverse osmosis water purification unit 150 is broken so that the reverse osmosis water purification unit 150 does not have to go through the reverse osmosis water purification unit 150. If the water should not be sent to the water, the water that has passed through the first pure water treatment unit 140 may be directly sent to the second pure water treatment unit 160, so that the pure water treatment process of the water may be continuously performed.

On the other hand, the washing unit 195 of the present embodiment is provided on the path of the washing movement pipe 196 connected in communication with the main movement pipe 120, the components connected on the path of the main movement pipe 120 as well as the main movement pipe 120 That is, the first pure water treatment unit 140, the reverse osmosis water purification unit 150, the second pure water treatment unit 160 and the bypass moving tube 190 of the present embodiment is responsible for washing. The cleaning unit 195 may be provided as a clean in place solution type, and thus the cleaning operation of the entire equipment may be efficiently and reliably performed.

Referring to FIG. 1, one end of the washing moving tube 196 in which the washing unit 195 of the present embodiment is mounted is connected to an inlet portion of the main moving tube 120, and the other end thereof is the reverse osmosis water purification unit 150 and the second. It is connected to a portion of the main moving pipe 120 connecting the pure water treatment unit 160.

Therefore, when water does not flow into the main moving tube 120 described above, the washing unit 195 may send the washing liquid contained therein to the inlet region of the main moving tube 120 through the washing moving tube, and the washing liquid may be the main moving tube ( 120 may be used to perform cleaning operations on a number of components coupled thereto. On the other hand, the washing unit 195 may be connected by a discharge unit 155 provided in the reverse osmosis water purification unit 150 and a separate moving tube 197, and may discharge the washing liquid after the washing process to the outside.

Meanwhile, hereinafter, a method for manufacturing the kidney dialysis water production apparatus 100 having such a configuration will be described with reference to FIGS. 4 and 5.

Figure 4 is a flow chart of the kidney dialysis water preparation method according to a first embodiment of the present invention, Figure 5 is a flow chart in detail the flow chart of FIG.

As shown in Figure 4, the method for producing kidney dialysis water according to the first embodiment of the present invention, the inflow step (S100) for introducing external water into the main moving pipe 120 by the feed pump unit 130 and The first pure water treatment step (S200) for firstly purifying the introduced water by the first pure water treatment unit 140, and the second pure water treatment for the subsequent water treatment using the second pure water treatment unit 160 It may include a dialysis step (S600) for diagnosing the pure water to the patient using the pure water treatment step (S500) and the kidney dialysis machine (110).

However, the kidney dialysis water preparation method of the present embodiment may further include a reverse osmosis water purification step (S300) between the first pure water treatment step (S200) and the second pure water treatment step (S500) when reverse osmosis water purification is required. On the contrary, when the reverse osmosis water purification is not required or is impossible due to the failure of the reverse osmosis water purification unit 150, the bypass moving tube 190 as a step between the first pure water treatment step S200 and the second pure water treatment step S500. It may further include a bypass movement step (S400) for moving the water passing through the first pure water treatment unit 140 to the second pure water treatment unit 160 using.

Each step will be described in detail. First, the inflow step S100 of the present embodiment is performed by the feed pump unit 130 having two feed pumps 131 and 132 as described above. Therefore, not only the two feed pumps 131 and 132 may be operated to adjust the inflow and pressure of water, but also only one of the two feed pumps 131 and 132 may be operated. Can be.

On the other hand, the first pure water treatment step (S200) of the present embodiment, as shown in Figure 5, not only reduces the turbidity of the water by the media filter 141, but also taste, smell, color, residual chlorine contained in the water , The turbidity reduction and adsorption removal step (S210) for adsorption removal of residual detergent or residual organic matter, the softening step (S220) for softening the water by the softener filter 148, and the prefilter 149 It may include a pre-filtering step (S230) of filtering the suspended substances, for example, 5 micrometers of suspended substances once more.

By the first pure water treatment step (S200) of this configuration, the water may be first purely treated and then supplied to the second pure water treatment unit 160 by the reverse osmosis water purification unit 150 or the bypass moving tube 190. .

Reverse osmosis water purification step (S300) of the present embodiment, by improving the purity of the water by the reverse osmosis water purification of the first pure water treated.

On the other hand, the second pure water treatment step (S500) of the present embodiment, the storage step of storing the water in the storage tank 170 and then heated to sterilize the water (S510) and the storage by the operation of the supply filter 180 Supply step (S520) for supplying the water of the tank 170 in the direction of the kidney dialysis machine 110, the ion component removal step (S530) for removing the ions contained in the water by the polisher filter 181, and finally As a result it may include a final filtering step (S540) for removing the suspended solids of a predetermined size contained in the water, for example, suspended matter of 0.2 micrometers or more dead.

On the other hand, kidney dialysis water manufacturing method of the present embodiment may further include a washing step (S700) for washing the above-described components. In the washing step (S700) of the present embodiment, the washing liquid is supplied from the washing unit 195 to the main moving tube 120 through the washing moving tube 196, and the supplied washing liquid is mounted on the path of the main moving tube 120. The washing process may be performed while passing through the first pure water treatment unit 140, the reverse osmosis water purification unit 150, the second pure water treatment unit 160, and the bypass moving tube 190. This not only improves the pure water treatment efficiency, but also extends the life of the equipment.

As described above, according to the first embodiment of the present invention, the water purified by the first pure water treatment unit 140 is discharged by the bypass moving tube 190 without passing through the reverse osmosis water purification unit 150. 2 can be moved to the pure water treatment unit 160, so that even if the water purification process of the reverse osmosis water purification unit 150 is unnecessary or the reverse osmosis water purification unit 150 is broken, it is possible to continuously perform the pure water treatment operation of water. have.

In addition, by purely treating the water in multiple stages, it is possible to provide clean dialysis water to the patient, thereby improving the reliability of hemodialysis, and also to clean the device by the cleaning unit 195. This will not only prevent contamination of the water to be treated, but also extend the replacement period of the equipment.

On the other hand, with reference to the accompanying drawings will be described for the apparatus for producing kidney dialysis water according to a second embodiment of the present invention. However, the same description as that described in the apparatus for manufacturing kidney dialysis water according to the first embodiment of the present invention will be omitted.

6 is a view showing a schematic configuration of a device for producing kidney dialysis water according to a second embodiment of the present invention.

As shown in this, the kidney dialysis water production apparatus 200 of the second embodiment of the present invention, similar to the kidney dialysis water production apparatus 100 (see FIG. 1) of the first embodiment described above, the feed pump unit 230 , A storage tank including the first pure water treatment unit 240, the reverse osmosis water purification unit 250, the second pure water treatment unit 260, and the bypass transfer pipe 290, but which the second pure water treatment unit 260 includes. There is a slight difference in 270.

That is, the storage tank 170 (see FIG. 1) of the first embodiment described above is sterilized by heating the water stored by the heating principle, but the storage tank 270 of the second embodiment is not equipped with a separate heater unit, but It serves to store the water purified by the reverse osmosis purification unit 250.

However, the storage tank 270 of the present embodiment is also equipped with an ultraviolet sterilizer 274, an air filter 273, and the like, which not only can sterilize water but also introduce clean air into the storage tank 270. Can be.

On the other hand, with reference to the accompanying drawings will be described for the kidney dialysis water production apparatus according to a third embodiment of the present invention. However, the same description as in the kidney dialysis water production apparatus according to the above embodiments of the present invention will be omitted.

7 is a view showing a schematic configuration of the kidney dialysis water production apparatus according to a third embodiment of the present invention.

As shown therein, the kidney dialysis water production apparatus 300 according to the third embodiment of the present invention is substantially similar to the kidney dialysis water production apparatus 100 (refer to FIG. 1) of the first embodiment described above. There is a slight difference in the filter 385.

That is, while the final filter 185 (see FIG. 1) of the first embodiment described above is provided as a filtration filter for removing suspended matter of 0.2 micrometer or more, the final filter 385 of this embodiment can remove suspended matter of 0.03 micrometer or more. Can be provided with a superfiltration filter.

Therefore, the purity of the water finally supplied to the kidney dialysis machine 310 can be further improved, thereby improving the reliability of hemodialysis.

On the other hand, with reference to the accompanying drawings will be described for the kidney dialysis water production apparatus according to a fourth embodiment of the present invention. However, the same description as in the kidney dialysis water production apparatus according to the above embodiments of the present invention will be omitted.

8 is a view showing a schematic configuration of the kidney dialysis water production apparatus according to a fourth embodiment of the present invention.

As shown therein, the kidney dialysis water production apparatus 400 according to the fourth embodiment of the present invention is substantially similar to the kidney dialysis water production apparatus 200 (refer to FIG. 6) of the second embodiment described above. There is a difference in the filter 485.

That is, the final filter 485 of the present embodiment may be provided as an ultrafiltration filter similarly to the final filter 385 (see FIG. 7) of the third embodiment, thereby further improving the purity of water supplied to the kidney dialysis machine. It can thereby improve the reliability of hemodialysis.

In the present invention as described above has been described by the specific embodiments, such as specific components and limited embodiments and drawings, but this is provided to help a more general understanding of the present invention, the present invention is not limited to the above embodiments. For those skilled in the art, various modifications and variations are possible from these descriptions. Therefore, the spirit of the present invention should not be limited to the described embodiments, and all of the equivalents and equivalents of the claims, as well as the following claims, will fall within the scope of the present invention. .

100: kidney dialysis water production apparatus 110: kidney dialysis machine
120: moving tube 130: feed pump unit
140: first pure water processing unit 141: media filter
148: softener filter 149: pre-filter
150: reverse osmosis water purification unit 160: second pure water treatment unit
170: storage tank 180: feed pump
181: polisher filter 185: final filter
190: bypass transfer pipe 195: cleaning unit

Claims (16)

It forms a movement path of water introduced from the outside, the rear end of the main moving tube is equipped with a kidney dialysis machine;
A first pure water treatment unit mounted to the main moving tube and configured to primarily process the water introduced into the main moving tube to pure water;
A reverse osmosis water purification unit mounted on the main moving tube so as to be located at the rear of the first pure water treatment unit and treating the water having passed through the first pure water treatment unit by a reverse osmosis principle;
A second pure water treatment unit mounted on the main moving tube so as to be disposed between the reverse osmosis water purification unit and the kidney dialysis machine, and subsequently purifying the water passing through the reverse osmosis water purification unit; And
The main moving tube connecting the first pure water treatment unit and the reverse osmosis water purification unit and the main moving tube connecting the reverse osmosis water purification unit and the second pure water treatment unit are connected so that the water is reverse osmosis according to a setting. Bypass moving pipe to move directly without passing through the water purification unit;
Kidney dialysis water production apparatus comprising a.
The method of claim 1,
The main moving tube, the first pure water treatment unit, the reverse osmosis water purification unit, and the second pure water treatment are connected to the main moving tube and installed in a washing moving tube having a separate circulation path, and supplying a washing liquid to the main moving tube. Kidney dialysis water production apparatus further comprises a cleaning unit of the Clean In Place Solution (CIP) type for cleaning at least one of the unit and the bypass transfer pipe.
The method of claim 1,
It is attached to the front end of the main moving pipe prior to the first pure water treatment unit, further comprising a feed pump unit for introducing the water into the main moving pipe,
The feed pump unit,
A first feed pump mounted to the main moving pipe and configured to adjust the flow rate and pressure of the water; And
A second feed pump mounted on the main moving pipe to be parallel to the first feed pump, and configured to adjust the flow rate and pressure of the water,
The first feed pump and the second feed pump is kidney dialysis water production apparatus capable of simultaneous operation and individual drive.
The method of claim 1,
The first pure water treatment unit,
A media filter mounted to the main moving tube and configured to reduce turbidity of the water and adsorb and remove contaminants contained in the water; And
Elongated dialysis water production apparatus mounted to the main moving tube, including a softener filter (softener filter) for softening the water.
The method of claim 4, wherein
The media filter,
A filter housing forming an appearance;
A gravel disposed below in the filter housing;
Sand disposed on an upper portion of the grabble;
Activated carbon disposed on top of the sand; And
Kidney dialysis water production apparatus comprising anthracite disposed on top of the activated carbon.
The method of claim 4, wherein
The first pure water treatment unit,
And a pre-filter mounted on the main moving tube so as to be disposed at the rear of the softner filter, the pre-filter for filtering a floating material of a predetermined size or more contained in the water.
The method of claim 1,
The reverse osmosis water purification unit,
A reverse osmosis water purification pump mounted on the main moving tube to generate a driving force for moving the water treated by the first pure water treatment unit; And
Kidney dialysis water production apparatus comprising a reverse osmosis water purification unit for water treatment by the reverse osmosis principle of the water introduced by the reverse osmosis water purification pump.
The method of claim 1,
The second pure water treatment unit,
A storage tank mounted to the main moving tube and configured to store the water subjected to reverse osmosis purification by the reverse osmosis purification unit;
A polisher filter mounted to the main moving tube so as to be located at the rear of the storage tank, and removing a ionic component contained in the water by using a resin in which a cation exchange resin and an anion exchange resin are mixed; And
And a final filter mounted on the main moving tube so as to be located at the rear of the polisher filter and finally filtering a floating material having a predetermined size or more contained in the water.
The method of claim 8,
The storage tank,
A tank body in which the water is stored;
A heater unit mounted in the tank body to heat the water supplied from the reverse osmosis water purification unit to a predetermined temperature; And
An apparatus for producing kidney dialysis water, further comprising an ultraviolet sterilizer mounted in the tank body so as to be partially immersed in the water in the tank body and removing bacteria in the water by emitting ultraviolet rays.
The method of claim 8,
The final filter is a filtration filter for filtering a suspended matter having a size of 0.2 micrometers of the suspended solids contained in the water, or an ultrafiltration filter which is a superfiltration filter having a suspended matter having a size of 0.03 micrometers of the suspended solids contained in the water. Manufacturing device.
The method of claim 8,
The second pure water treatment unit,
A supply pump mounted to the main moving tube to be positioned between the storage tank and the final filter and generating a driving force for supplying the water of the storage tank to the polisher filter for a time set in an automatic timer,
The feed pump is provided in a pair in a parallel structure kidney dialysis water production apparatus that is simultaneously operated or individually operated.
The method of claim 1,
At least one of the main moving pipe and the bypass moving pipe is a kidney dialysis water production apparatus is provided with a pex pipe (pex pipe) made of crosslinked polyethylene.
In the kidney dialysis water production method of the kidney dialysis water production apparatus according to any one of claims 1 to 12,
An inflow step of introducing external water into the main moving pipe;
A first pure water treatment step of firstly treating the introduced water by a first pure water treatment unit;
A second pure water treatment step of subsequently purifying the water using the second pure water treatment unit; And
Dialysis step of diagnosing the purely treated water to the patient using the kidney dialysis machine; and
In the case of reverse osmosis purification of the water after the first pure water treatment step, further comprising a reverse osmosis purification step of water purification by the reverse osmosis principle of the pure water treated using the reverse osmosis purification unit,
When the reverse osmosis water purification step is not executed, the main movement pipe connecting the first pure water treatment unit and the reverse osmosis water purification unit and the main movement pipe connecting the reverse osmosis water purification unit and the second pure water treatment unit The step of moving the water to the bypass moving pipe to connect, the kidney dialysis water production method further comprising a bypass movement step.
The method of claim 13,
By supplying the washing liquid from the washing unit to the main moving tube, the first pure water treatment unit, the reverse osmosis water purification unit, the second pure water treatment unit and the bypass mounted on the path of the main moving tube as well as the main moving tube. Kidney dialysis water production method further comprising a washing step of washing at least one of the moving tube.
The method of claim 13,
The first pure water treatment unit performing the first pure water step includes: a media filter for lowering turbidity of the water and adsorbing and removing contaminants contained in the water; a softener filter for softening the water; and Includes a pre-filter for filtering over a certain amount of suspended solids,
The first pure water treatment step,
Turbidity reduction and adsorption removal step of adsorbing and removing the taste, smell, color, residual chlorine, residual detergent or residual organic matter contained in the water while reducing the turbidity of the water by the media filter;
A softening step of softening the water by the softener filter; And
And a pre-filtering step of filtering the suspended matter contained in the water by the pre-filter.
The method of claim 14,
The second pure water treatment step,
Storing the reverse osmosis purified water;
A supplying step of supplying the water of the storage tank toward the kidney dialysis machine by the operation of the supply tank;
Removing the ionic component contained in the water by the polisher filter; And
And a final filtering step of finally filtering the suspended matter of a predetermined size contained in the water by the final filter.

Images