JP5840248B2 - Dialysate production equipment - Google Patents

Description

  The present invention relates to a dialysate manufacturing apparatus.

  Hemodialysis is one of the effective treatments for renal failure patients who have impaired kidney function and cannot excrete urine to regulate water content and remove harmful substances such as urea. Are known.

  In this hemodialysis, blood is extracted from the body using a blood pump, and the dialysate and blood are brought into contact with each other through a dialyzer, thereby utilizing a diffusion phenomenon due to a concentration gradient to remove harmful substances from the body. In addition, after removing water, the blood is returned to the body again (returning blood).

  In recent years, it is known that oxidative stress occurs in dialysis patients during hemodialysis. This is considered to be caused by active oxygen generated during dialysis, and it has been proposed to eliminate this active oxygen to reduce oxidative stress.

  For example, a method for producing a dialysate in which high-concentration hydrogen is dissolved by dissolving hydrogen in purified water (hereinafter referred to as “reverse osmosis water”) treated with a reverse osmosis membrane (RO membrane) is proposed. Has been. By using this dialysate, hydrogen can be reacted with hydroxy radicals in the living body to suppress oxidative stress and inflammatory reaction.

  In addition, conventionally, before the treatment with the reverse osmosis membrane, the raw water is electrolyzed to generate water in which hydrogen used as dialysate preparation water is dissolved (dissolved hydrogen water). (For example, refer to Patent Document 1).

  FIG. 10 is a diagram showing a conventional apparatus for preparing dialysate preparation water. In this dialysate preparation water production apparatus 101, first, raw water (city water) 102 is pressurized by a pressure pump 103, and solids in the raw water 102 are processed by a filter 104 having a pore diameter of 10 to 30 μm.

  Next, after the hardness of the raw water 102 is lowered by the water softening device 105, hypochlorous acid contained in the raw water 102 is removed by the activated carbon treatment device 106. Then, the reduced water (treated water) obtained by electrolysis is stored in the reduced water tank 108 by the electrolyzed water generator 107.

  Next, after the reduced water stored in the reduced water tank 108 was pressurized by the pressurizing pump 109, the reduced water was passed through the reverse osmosis membrane in the reverse osmosis membrane treatment apparatus 110 and passed through the reverse osmosis membrane. Reduced water is stored in the RO tank 111.

  Next, the reduced water sent from the RO tank 111 is sterilized by the UV sterilization lamp 112, and the sterilized reduced water is supplied to the dialysate preparation device 114 through the microfilter 113.

  In the dialysate preparation device 114, the supplied reduced water (that is, the reduced water subjected to the reverse osmosis membrane treatment) and the dialysate stock solution are mixed to prepare a dialysate. Then, this dialysate is supplied to a dialyzer (not shown), and the patient's blood is purified through a dialyzer attached to the dialyzer.

JP 2000-350989 A

  Here, the dissolved hydrogen concentration in the terminal dialysate (that is, the dialysate supplied to the dialyzer and for purifying the patient's blood through the dialyzer) depends on the result of the electrolysis described above and is electrolyzed. Since the amount of water generated varies depending on the water quality, there is a problem that a desired dissolved hydrogen concentration cannot always be obtained even when the same current is applied.

  In addition, for example, when supplying the dialysate, the dissolved hydrogen concentration in the dialysate decreases due to physical impact or the like, and it becomes difficult to maintain the dissolved hydrogen concentration at a constant high concentration. There was a problem.

  Therefore, the terminal dialysate has a problem that a desired dissolved hydrogen concentration is not always obtained.

  Then, this invention is made | formed in view of the above-mentioned problem, and it aims at providing the manufacturing apparatus of the dialysate which can obtain a desired dissolved hydrogen concentration in the dialysate of a terminal.

In order to achieve the above object, the dialysate manufacturing apparatus of the present invention is connected to a hydrogen dissolving apparatus for dissolving hydrogen in water and a hydrogen dissolving apparatus, and performs reverse osmosis membrane treatment on water in which hydrogen is dissolved. A reverse osmosis membrane treatment device, a dialysate preparation device that is connected to the reverse osmosis membrane treatment device and prepares a dialysate mixed with a reverse osmosis water treated by the reverse osmosis membrane treatment device and a dialysis stock solution, and a dialysate preparation device And a dialysis device to which a dialysis fluid is supplied from a dialysis fluid preparation device, a deaeration device for deaeration treatment of the dialysis fluid, and a dialysis device provided after the deaeration treatment A sensor for detecting the dissolved hydrogen concentration of the dialysate, and a control device that is connected to the sensor and the degassing device and controls the degassing pressure when performing degassing processing based on the dissolved hydrogen concentration detected by the sensor. includes, dialyzer, a blood purification apparatus When connected to a dialysate preparation device and blood purifying apparatus, a dialysate prepared in the dialysate preparation device and dialysate inlet passage for introducing the blood purification apparatus
The deaeration device is provided in the dialysate introduction path, and the sensor is provided between the deaeration device and the blood purification device in the dialysate introduction path .

  According to this configuration, even when the dissolved hydrogen concentration in the dialysate is reduced due to the quality of the water to be electrolyzed or the physical impact when supplying the dialysate, the terminal dialysate , A desired dissolved hydrogen concentration (that is, a dissolved hydrogen concentration corresponding to an individual patient) can be obtained.

  Moreover, since it is set as the structure which detects the dissolved hydrogen concentration of the dialysate just before purifying a patient's blood, it becomes possible to adjust the dissolved hydrogen concentration of the terminal dialysate accurately.

  According to the present invention, a desired dissolved hydrogen concentration can be obtained in the terminal dialysate.

It is a conceptual diagram which shows the structure of the manufacturing apparatus of the dialysate which concerns on the 1st Embodiment of this invention. It is a figure which shows the electrolytic vessel in the electrolyzed water production | generation apparatus of the manufacturing apparatus of the dialysate which concerns on the 1st Embodiment of this invention. It is a figure which shows the dialysis apparatus which concerns on the 1st Embodiment of this invention. It is a flowchart for demonstrating the adjustment method of the dissolved hydrogen concentration by the control apparatus which concerns on the 1st Embodiment of this invention. It is a figure which shows the dialysis apparatus which concerns on the 2nd Embodiment of this invention. It is a flowchart for demonstrating the adjustment method of the dissolved hydrogen concentration by the control apparatus which concerns on the 2nd Embodiment of this invention. It is a figure which shows the modification of the dialysis apparatus which concerns on the 1st Embodiment of this invention. It is a figure which shows the modification of the dialysis apparatus which concerns on the 1st Embodiment of this invention. It is a conceptual diagram which shows the structure of the manufacturing apparatus of the dialysate which concerns on the modification of this invention. It is a conceptual diagram which shows the structure of the manufacturing apparatus of the conventional dialysate.

(First embodiment)
FIG. 1 is a conceptual diagram showing the configuration of a dialysate manufacturing apparatus according to the first embodiment of the present invention. Moreover, FIG. 2 is a figure which shows the electrolytic cell in the electrolyzed water production | generation apparatus of the dialysate manufacturing apparatus based on the 1st Embodiment of this invention.

  The dialysis fluid preparation water production apparatus 1 includes a prefilter 3, a water softening device 4 connected to the prefilter 3, a carbon filter (activated carbon treatment device) 5 connected to the water softening device 4, and a carbon filter 5. Connected to the electrolyzed water generating device 7, the electrolyzed water tank 8 connected to the electrolyzed water generating device 7, the reverse osmosis membrane treatment device 9 connected to the electrolyzed water tank 8, and the reverse osmosis membrane treatment device 9 And an UF (Ultra Filter) module 30.

  The prefilter 3 is for removing impurities (for example, iron rust and sand particles) from the raw water 2 (hard water containing dissolved solids such as calcium ions and magnesium ions which are hardness components).

  The water softening device 4 is for removing the hardness component from the raw water 2 by ion exchange and performing softening water by ion exchange. In the present embodiment, tap water, well water, ground water, or the like can be used as the raw water 2.

  The carbon filter 5 removes residual chlorine, chloramine, organic matter, etc. contained in the raw water from the raw water treated by the water softening device 4 by a physical adsorption action using activated carbon, which is a porous adsorbent. It is for performing the process to perform.

  In addition, a well-known thing can be used as the above-mentioned water softening apparatus 4 and the carbon filter 5. FIG.

  The electrolyzed water generating device 7 functions as a hydrogen dissolving device, and hydrogen used as dialysate preparation water is dissolved by subjecting the raw water 2 treated by the carbon filter 5 to electrolysis. It is for producing water (dissolved hydrogen water).

  Moreover, the electrolyzed water generating apparatus 7 of the present embodiment is characterized in that it includes an electrolytic cell 20 having a solid polymer membrane (solid polymer electrolyte membrane) 10 shown in FIG.

  As shown in FIG. 2, the electrolytic cell 20 is a power supply body that is disposed to face each other with the solid polymer film 10 and the solid polymer film 10 interposed therebetween, and that supplies power to the electrolytic cell 20. An anode 11 and a cathode 12, and a dielectric layer 13 disposed between the solid polymer film 10 and the anode 11 and between the solid polymer film 10 and the cathode 12 are provided.

  As shown in FIG. 2, the anode 11 and the cathode 12 are electrically connected, and the solid polymer film 10, the anode 11, the cathode 12, and the dielectric layer 13 are connected to the electrolytic cell body 15. Housed inside.

  As shown in FIG. 2, the electrolytic cell main body 15 is formed with an introduction path 16 for introducing the raw water 2 to be electrolyzed into the electrolytic cell main body 15.

  Examples of the material of the anode 11 and the cathode 12 include titanium and platinum.

  Moreover, as a material which forms the dielectric material layer 13, titanium, platinum, etc. are mentioned, for example.

The solid polymer film 10 has a role of moving oxonium ions (H ₃ O ⁺ ) generated on the anode 11 side to the cathode 12 side by electrolysis.

  As this solid polymer film 10, for example, a film formed of a fluorine-based resin material having a sulfonic acid group can be suitably used. More specifically, commercially available products such as Nafion (manufactured by DuPont), Flemion (manufactured by Asahi Glass), and Aciplex (manufactured by Asahi Glass) can be suitably used as the solid polymer film 10 in the present invention.

In the electrolysis in the electrolyzed water generating apparatus 7 using such a solid polymer membrane 10, the following reactions occur on the anode 11 side and the cathode 12 side, respectively.
Anode side: 6H ₂ O → 4H ₃ O ⁺ + O ₂ + 4e ⁻
Cathode side: 4H ₃ O ⁺ + 4e ⁻ → 2H ₂ + 4H ₂ O

That is, in the present embodiment, oxonium ions (H ₃ O ⁺ ) are used as the hydrogen generation raw material in the cathode 12, and OH ⁻ ions are not generated during the electrolysis process in the electrolyzed water generation device 7. Therefore, even when electrolysis is performed at a high current value in order to increase the amount of dissolved hydrogen, the pH of the treated water does not change.

  Therefore, there is no inconvenience that the dissolved hydrogen concentration of treated water is suppressed due to the upper limit value of pH, and electrolysis is performed at a desired high current value to improve the dissolved hydrogen concentration of treated water. It becomes possible to make it. As a result, it is possible to obtain treated water having a necessary dissolved hydrogen concentration.

In addition, water is electrolyzed using the solid polymer membrane 10, and no OH ^- ion is generated on the cathode side during electrolysis, so reverse osmosis is performed using the electrical conductivity of reverse osmosis water. It becomes possible to accurately evaluate a decrease in the ability to remove impurities in the membrane processing apparatus 9 (deterioration of the reverse osmosis membrane processing apparatus 9).

  And the treated water (dissolved hydrogen water) 17 produced | generated by the above-mentioned electrolysis process is sent to the electrolyzed water tank 8 connected to the electrolyzed water production | generation apparatus 7 by the water supply path 18 formed in the cathode side of the electrolytic cell main body 15. FIG. Sent. In addition, the dissolved oxygen water 19 generated on the anode side by the electrolysis treatment is discharged to the outside through the drainage channel 21 formed on the anode side of the electrolytic cell body 15.

  The electrolyzed water tank 8 is for storing the dissolved hydrogen water generated by the electrolyzed water generator 7.

  The reverse osmosis membrane treatment device 9 is configured to prevent a phenomenon (osmosis) in which water moves from a low-concentration solution to a high-concentration solution when there are solutions having different concentrations at the semipermeable membrane as a boundary. By applying pressure to the water, the water is transferred from the high-concentration side solution to the low-concentration side solution to obtain water permeated to the low-concentration side (reverse osmosis membrane treatment).

  And since this reverse osmosis membrane treatment device 9 can further remove impurities such as trace metals from the raw water obtained by the above-described series of treatments, the water quality standard defined in ISO 13959 (dialysis water standard) It is possible to obtain water that satisfies the conditions (reverse osmosis water).

  As shown in FIG. 1, the reverse osmosis membrane treatment device 9 includes a reverse osmosis membrane 36 that performs the above-mentioned reverse osmosis membrane treatment on the dissolved hydrogen water produced by the electrolyzed water production device 7, and a reverse osmosis membrane treatment. A reverse osmosis water tank 37 is provided for storing the reverse osmosis water made.

  The UF module 30 is for performing a process of removing bacteria and microorganisms contained in the reverse osmosis water 25.

  As shown in FIG. 1, the dialysate preparation device 26 is connected to the UF module 30, and the reverse osmosis water 25 that has been processed by the UF module 30 is supplied to the dialysate preparation device 26. The

  In the dialysate preparation device 26, a dialysate 27 is prepared by mixing the supplied reverse osmosis water 25 and the dialysate stock solution, and this dialysate 27 is supplied to the dialyzer 40 connected to the dialysate preparation device 26. The blood of the patient 50 is purified. That is, the dialysate preparation device 26 also functions as a dialysate supply device that supplies the prepared dialysate 27 to the dialyzer 40.

  FIG. 3 is a diagram showing a dialysis apparatus according to the first embodiment of the present invention. As shown in FIG. 3, the dialysis device 40 is connected to the blood circuit 49 including the arterial blood circuit 44 and the venous blood circuit 45, and the arterial blood circuit 44 and the venous blood circuit 45, and flows through the blood circuit 49. And a dialyzer 43 which is a blood purification device for purifying blood.

  The dialyzer 40 is connected to the dialysate preparation device 26 and the dialyzer 43, and is connected to the dialysate introduction path 41 and the dialyzer 43 for introducing the dialysate 27 prepared in the dialysate preparation device 26 into the dialyzer 43. And a dialysate discharge passage 42 for discharging the dialysate 27 introduced into the dialyzer 43 together with the waste in the blood.

  The dialysis device 40 further includes a blood circulation pump 46 provided in the arterial blood circuit 44, a bubble removing device 47, and a bubble removing device 48 provided in the venous blood circuit 45.

  The dialyzer 43 is connected to the dialysate introduction path 41, the dialysate discharge path 42, the arterial blood circuit 44, and the venous blood circuit 45 via connectors (couplers) 51 to 54 shown in FIG. . The dialyzer 43 is configured to be detachably attached to these connectors 51 to 54.

  In this embodiment, when the pump 46 is driven in a state where the patient 50 is punctured with an arterial puncture needle and a vein puncture needle (both not shown), the blood of the patient 50 is removed by the bubble removing device 47. In addition to defoaming, the blood is sent to the dialyzer 43 through the arterial blood circuit 44, and the blood is purified by the dialyzer 43.

  Next, the blood purified by the dialyzer 43 is defoamed by the bubble removing device 48 and returns to the body of the patient 50 through the venous blood circuit 45.

  A plurality of hollow fibers having a predetermined inner diameter (for example, 200 μm) are accommodated inside the dialyzer 43, and the inside of the hollow fiber becomes a blood flow path, and the outer peripheral surface of the hollow fiber and the dialyzer 43 A passage for the dialysate 27 is formed between the inner peripheral surface of the housing portion.

  In addition, the hollow fiber is formed with a large number of minute holes penetrating the outer peripheral surface and the inner peripheral surface, and the wall of the hollow fiber is a semipermeable membrane. Such impurities are transmitted through the dialysate 27.

  Further, when a large amount of dissolved gas is present in the dialysate 27, bubbles are accumulated in the dialyzer 43, and the holes formed in the hollow fiber are blocked by the bubbles, resulting in a decrease in blood purification efficiency by the dialyzer 43. Therefore, in order to avoid the occurrence of such inconvenience, in this embodiment, a deaeration device 55 is provided in the dialysis device 40 as shown in FIG.

  The deaerator 55 performs a deaeration process for removing excess dissolved gas in the dialysate 27 before passing the dialysate 27 through the dialyzer 43. As shown in FIG. 40 is provided in the dialysate introduction path 41.

  As shown in FIG. 1, the deaeration device 55 includes a membrane module 56 and a pump 57 connected to the membrane module 56.

  The membrane module 56 has a function of separating the dissolved gas in the dialysate 27, and has a large number of hollow fibers formed of hydrophilic membranes and having pores formed therein. Accordingly, the dialysate 27 supplied to the inside of the hollow fiber can move from the inside of the hollow fiber through the hollow fiber wall to the outside of the hollow fiber, but is included in the dialysate 27. The gas cannot pass through the wall of the hollow fiber, but is drawn out by the pump 57 connected to the membrane module 56 and discharged from the inside of the hollow fiber to the outside of the membrane module 56, and the excess in the dialysate 27. Dissolved gas is removed.

  Here, as described above, in the above conventional dialysate manufacturing apparatus, the terminal dialysate (the dialysate supplied to the dialyzer and purifying the patient's blood through the dialyzer) is not always desired. There was a problem that the dissolved hydrogen concentration was not obtained.

  Therefore, in the present embodiment, the feedback control using the sensor is used to control the deaeration pressure when the deaeration device 55 performs the deaeration so as to make up for the dissolved hydrogen deficient in the terminal dialysate 27. Thus, the dissolved hydrogen concentration in the terminal dialysate 27 is maintained at a desired concentration.

  More specifically, as shown in FIG. 1, the dialysate manufacturing apparatus 1 in this embodiment includes a sensor 60 for detecting the dissolved hydrogen concentration of the dialysate 27, and the dissolved hydrogen concentration detected by the sensor 60. And a control device 32 for controlling the deaeration pressure when the deaeration device 55 performs the deaeration.

  The control device 32 functions as a dissolved hydrogen concentration adjusting device for adjusting the dissolved hydrogen concentration in the dialysate 27.

  The sensor 60 detects the dissolved hydrogen concentration of the dialysate 27 after the deaeration treatment, and is a dialysate introduction path 41 in the dialyzer 40 as shown in FIG. It is provided on the downstream side (that is, between the deaerator 55 and the dialyzer 43 in the dialysate introduction path 41). The sensor 60 is not particularly limited as long as it can detect the dissolved hydrogen concentration. For example, a dissolved hydrogen electrode using a diaphragm type polarograph method (trade name: dissolved hydrogen concentration meter DH-35A, manufactured by Toa DKK Corporation) is used. Can be used.

  In addition, the control device 32 is connected to the sensor 60 and determines the deaeration pressure when the deaeration device 55 performs the deaeration, the deaeration pressure determination unit 33, the deaeration pressure determination unit 33, and the pump 57 of the deaeration device 55. Is connected to the rotational speed control means 34 for controlling the rotational speed of the motor in the pump 57, and to the deaeration determining means 33, and the dissolved hydrogen concentration target value (for example, the dissolved hydrogen concentration corresponding to the individual patient 50). Storage means 35 for storing target value data.

  Next, a method for adjusting the dissolved hydrogen concentration by the sensor 60 and the control device 32 will be described.

  FIG. 4 is a flowchart for explaining a method for adjusting the dissolved hydrogen concentration by the control device according to the first embodiment of the present invention.

  In the present embodiment, the measurement of the dissolved hydrogen concentration in the dialysate 27 is performed before the patient 50 is dialyzed.

  More specifically, first, the sensor 60 is connected to the terminal dialysate (the dialysate supplied from the dialysate preparation device 26 to the dialyzer 40 through the dialyzer 43 when dialyzing the patient 50. The dissolved hydrogen concentration of the dialysis fluid 27 for purifying the blood of the patient 50 is detected (step S1).

  Next, the dissolved hydrogen concentration data detected by the sensor 60 is transmitted to the degassing pressure determining means 33 (step S2).

  Next, the degassing pressure determination means 33 reads data relating to the target value of the dissolved hydrogen concentration stored in the storage means 35 (step S3).

Next, the degassing pressure determination unit 33 compares the dissolved hydrogen concentration value C ₁ detected by the sensor 60 with the target value C of the dissolved hydrogen concentration read from the storage unit 35. That is, the degassing pressure determination means 33 determines whether or not the dissolved hydrogen concentration value C ₁ detected by the sensor 60 is smaller than the target value C of the dissolved hydrogen concentration read from the storage means 35 (that is, C ₁ <C). Is determined (step S4).

Then, the degassing pressure determination means 33 is dissolved when the dissolved hydrogen concentration value C ₁ detected by the sensor 60 is smaller than the target value C of the dissolved hydrogen concentration read from the storage means 35 (that is, C ₁ <C). It is determined that the hydrogen concentration is insufficient (decreased), and the deaeration pressure of the deaeration process by the deaerator 55 is determined so that the dissolved hydrogen concentration of the terminal dialysate 27 becomes the target value C (step S5). .

  Then, the degassing pressure determining unit 33 transmits a signal related to the determined degassing pressure to the storage unit 35, and the storage unit 35 stores data regarding the determined degassing pressure (step S6).

  Next, when dialysis is performed on the patient 50, the deaeration determining unit 33 reads the data relating to the determined deaeration stored in the storage unit 35 (step S7).

  Next, the degassing pressure determining means 33 transmits a signal related to the determined degassing pressure to the rotation speed control means 34 for controlling the rotation speed of the motor in the pump 57 (step S8).

  Next, the rotation speed control means 34 controls the rotation speed of the motor in the pump 57 with the rotation speed based on the input signal related to degassing pressure (that is, corresponding to the determined degassing pressure). Then, the deaeration process is performed so that the dissolved hydrogen concentration of the dialysate 27 becomes the target value C (step S9).

  That is, if the number of rotations of the motor in the pump 57 is controlled so that the degassing pressure in the degassing process is lowered, the amount of hydrogen degassed by the degassing device 55 is reduced, so that the dissolved hydrogen concentration in the terminal dialysate 27 is reduced. As a result, the dissolved hydrogen concentration is increased in the dialysate 27 at the end, and a desired dissolved hydrogen concentration can be obtained.

On the other hand, when the value C ₁ of the dissolved hydrogen concentration detected by the sensor 60 is equal to or higher than the target value C of the dissolved hydrogen concentration read from the storage unit 35 (ie, C ₁ ≧ C), the degassing pressure determining unit 33 Judge that the concentration is not insufficient. In this case, the process of step S5-step S9 mentioned above is not performed.

  As described above, in the present embodiment, the sensor 60 for detecting the dissolved hydrogen concentration of the dialysate 27 and the hydrogen deaeration process by the deaerator 55 based on the dissolved hydrogen concentration detected by the sensor 60. A control device 32 is provided for controlling the deaeration pressure (ie, degassing treatment of dissolved gas containing hydrogen).

  Therefore, even if the dissolved hydrogen concentration in the dialysate is reduced due to the quality of water to be electrolyzed, the physical impact at the time of supplying the dialysate, etc., the end dialysate 27 has a desired value. The dissolved hydrogen concentration (that is, the dissolved hydrogen concentration corresponding to the individual patient 50) can be obtained.

  Moreover, since it is set as the structure which detects the dissolved hydrogen concentration of the dialysate 27 just before purifying the blood of the patient 50, it becomes possible to adjust the dissolved hydrogen concentration of the terminal dialysate 27 with high precision.

(Second Embodiment)
Next, a second embodiment of the present invention will be described. FIG. 5 is a diagram showing a dialysis apparatus according to the second embodiment of the present invention. Note that the same components as those in the first embodiment are denoted by the same reference numerals, and description thereof is omitted. The overall configuration of the dialysate manufacturing apparatus is the same as in the case of the first embodiment described above, and a detailed description thereof will be omitted here.

  In the present embodiment, as shown in FIG. 5, the dialysate branch path 71 is provided by branching from the dialysate introduction path 41 described above, and the sensor 60 in the first embodiment described above is connected to the dialysate branch path. 71 is characterized by being provided.

  In this embodiment as well, as in the case of the first embodiment described above, the feedback control using the sensor 60 is used to deaerate so as to make up for the lack of dissolved hydrogen in the terminal dialysate 27. By controlling the degassing pressure when degassing is performed by the device 55, the dissolved hydrogen concentration in the terminal dialysate 27 is maintained at a desired concentration.

  Next, a method for adjusting the dissolved hydrogen concentration by the sensor 60 and the control device 32 will be described.

  FIG. 6 is a flowchart for explaining a method of adjusting the dissolved hydrogen concentration by the control device according to the second embodiment of the present invention.

  In the present embodiment, unlike the case of the first embodiment described above, the measurement of the dissolved hydrogen concentration in the dialysate 27 is performed when dialysis is performed on the patient 50.

  More specifically, first, the sensor 60 is connected to the terminal dialysate (the dialysate supplied from the dialysate preparation device 26 to the dialyzer 40 through the dialyzer 43 when dialyzing the patient 50. In order to purify the blood of the patient 50, the dissolved hydrogen concentration of the dialysis fluid) 27 is detected (step S11).

  Unlike the case of the first embodiment, when dialysis is performed on the patient 50, the dissolved hydrogen concentration in the dialysate 27 is measured. Therefore, it is used for measuring the dissolved hydrogen concentration from the viewpoint of hygiene management. As shown in FIG. 5, the dialysate 27 is discharged to the outside through the dialysate discharge path 72 connected to the dialysate branch path 71.

  Next, the dissolved hydrogen concentration data detected by the sensor 60 is transmitted to the degassing pressure determining means 33 (step S12).

  Next, the degassing pressure determination means 33 reads data relating to the target value of the dissolved hydrogen concentration stored in the storage means 35 (step S13).

Next, the degassing pressure determination unit 33 compares the dissolved hydrogen concentration value C ₁ detected by the sensor 60 with the target value C of the dissolved hydrogen concentration read from the storage unit 35. That is, the degassing pressure determination means 33 determines whether or not the dissolved hydrogen concentration value C ₁ detected by the sensor 60 is smaller than the target value C of the dissolved hydrogen concentration read from the storage means 35 (that is, C ₁ <C). Is determined (step S14).

Then, the degassing pressure determination means 33 is dissolved when the dissolved hydrogen concentration value C ₁ detected by the sensor 60 is smaller than the target value C of the dissolved hydrogen concentration read from the storage means 35 (that is, C ₁ <C). It is determined that the hydrogen concentration is insufficient (decreased), and the deaeration pressure of the deaeration process by the deaerator 55 is determined so that the dissolved hydrogen concentration of the terminal dialysate 27 becomes the target value C (step S15). .

  Next, the degassing pressure determining means 33 transmits a signal related to the determined degassing pressure to the rotation speed control means 34 for controlling the rotation speed of the motor in the pump 57 (step S16).

  Next, the rotation speed control means 34 controls the rotation speed of the motor in the pump 57 with the rotation speed based on the input signal related to degassing pressure (that is, corresponding to the determined degassing pressure). The deaeration process is performed so that the dissolved hydrogen concentration of the dialysate 27 becomes the target value C (step S17).

On the other hand, when the value C ₁ of the dissolved hydrogen concentration detected by the sensor 60 is equal to or higher than the target value C of the dissolved hydrogen concentration read from the storage unit 35 (ie, C ₁ ≧ C), the degassing pressure determining unit 33 Judge that the concentration is not insufficient. In this case, the process of step S15-step S17 mentioned above is not performed.

  As described above, in the present embodiment, the sensor 60 for detecting the dissolved hydrogen concentration of the dialysate 27 and the hydrogen deaeration process by the deaerator 55 based on the dissolved hydrogen concentration detected by the sensor 60. There is provided a control device 32 for controlling the deaeration pressure when performing.

  Therefore, as in the case of the first embodiment described above, the dissolved hydrogen concentration in the dialysate decreases due to the water quality to be electrolyzed, the physical impact when supplying the dialysate, etc. Even so, the desired dissolved hydrogen concentration (that is, the dissolved hydrogen concentration corresponding to the individual patient 50) can be obtained in the terminal dialysate 27.

  Moreover, since it is set as the structure which detects the dissolved hydrogen concentration of the dialysate 27 just before purifying the blood of the patient 50, it becomes possible to adjust the dissolved hydrogen concentration of the terminal dialysate 27 with high precision.

  Furthermore, unlike the first embodiment, the dissolved hydrogen concentration in the dialysate 27 can be adjusted simultaneously with dialysis of the patient 50 (ie, in real time).

  In addition, you may change the said embodiment as follows.

  In the first embodiment, the sensor 60 is provided in the dialysate introduction path 41 of the dialyzer 40. However, before the patient 50 is dialyzed, the dissolved hydrogen concentration in the dialysate 27 is measured. The sensor 60 may be provided at any position as long as it can be used.

  More specifically, for example, as shown in FIG. 7, a sensor 60 may be provided in the dialysate discharge path 42 in the dialyzer 40. Further, before dialyzing the patient 50, the dialyzer 43 is unnecessary, and as described above, the dialyzer 43 is detachably attached to the connectors 51 to 54, and as shown in FIG. After detaching the dialyzer 43, the sensor 60 is connected to the dialysate introduction path 41 and the dialysate discharge path 42 via the connectors 51 and 52 instead of the dialyzer 43 (that is, the sensor 60 is connected to the dialysate 42). It is good also as a structure provided between the liquid introduction path 41 and the dialysate discharge path 42).

  Moreover, in the said embodiment, although it was set as the structure which uses the electrolyzed water production | generation apparatus 7 as a hydrogen dissolution apparatus and dissolves hydrogen, it can melt | dissolve hydrogen with respect to the raw | natural water 2 processed with the carbon filter 5. FIG. Any configuration is possible as long as it is possible.

  For example, hydrogen may be dissolved by bringing hydrogen gas into contact with the raw water 2 treated by the carbon filter 5.

  More specifically, as a hydrogen dissolving apparatus, a hollow fiber is formed using a membrane module including a sleeve to which hydrogen gas is supplied and a hollow fiber disposed inside the sleeve and having a plurality of holes formed therein. A method of bringing hydrogen gas into contact with the raw water 2 treated by the carbon filter 5 through the formed holes can be employed.

  Moreover, the structure which keeps the dissolved hydrogen concentration in the raw | natural water 2 processed by the carbon filter 5 at a desired high density | concentration by pressurizing the raw | natural water 2 which hydrogen gas melt | dissolved, and raising the density | concentration of the hydrogen gas contained in the raw | natural water 2 It is good.

  More specifically, as shown in FIG. 9, the dialysate production apparatus 80 is connected to the carbon filter 5 instead of the electrolyzed water generating apparatus 7 shown in FIG. A hydrogen gas pressurizing device 85 having a module 81 and a pressurizing tank 82 which is connected to the membrane module 81 and dissolves hydrogen in the raw water 2 by pressurizing hydrogen gas is provided.

  The hydrogen gas pressurizing device 85 includes a pressure adjusting valve 84 connected to the pressurizing tank 82. By controlling the pressure adjusting valve 84, the hydrogen gas pressurizing device 85 is used when pressurizing hydrogen with the pressurizing tank 82. The pressure is controlled.

  Further, in the present modification, as in the case of the second embodiment described above, the dialysate branch path 71 is branched from the dialysate introduction path 41 and the sensor 60 is provided in the dialysate branch path 71. It is good also as a structure. Moreover, it is good also as a structure which provides the sensor 60 in the dialysate discharge path 42 in the dialyzer 40 similarly to the structure demonstrated in the above-mentioned FIG. 7, FIG. 8, instead of the dialyzer 43, via the connectors 51 and 52, The sensor 60 may be connected to the dialysate introduction path 41 and the dialysate discharge path 42.

  Furthermore, the structure which dissolves hydrogen with respect to the raw | natural water 2 processed by the carbon filter 5 by performing electrolysis using the electrolyzed water generating apparatus provided with the ion exchange membrane instead of the solid polymer membrane. It is good.

  In the above embodiment, one dialysis device 40 is connected to one dialysis fluid preparation device 26, but a plurality of dialysis devices 40 are connected to one dialysis fluid preparation device 26. It is good also as composition to do.

  In this case, each dialysis device 40 is provided with the above-described deaeration device 55 and sensor 60, and a control device 32 connected to the deaeration device 55 and sensor 60 is provided. Based on the dissolved hydrogen concentration, the control device 32 controls the degassing process of hydrogen by the degassing device 55.

  With such a configuration, a desired dissolved hydrogen concentration can be obtained in the dialysate 27 at the end of each dialyzer 40 by one dialysate preparation device 26.

  As described above, the present invention is particularly useful for an apparatus for producing a dialysis solution in which hydrogen is dissolved.

DESCRIPTION OF SYMBOLS 1 Dialysate manufacturing apparatus 2 Raw water 3 Pre-filter 4 Water softening device 5 Carbon filter 7 Electrolyzed water production device (hydrogen dissolving device)
DESCRIPTION OF SYMBOLS 8 Electrolyzed water tank 9 Reverse osmosis membrane processing apparatus 10 Solid polymer membrane 11 Anode 12 Cathode 13 Dielectric layer 15 Electrolyzer main body 16 Introductory path 17 Treated water 18 Water supply path 19 Dissolved oxygen water 20 Electrolytic tank 21 Drainage path 26 Dialysate preparation Device 27 Dialysate 32 Control device 33 Degassing pressure determining means 34 Rotational speed control means 35 Storage means 36 Reverse osmosis membrane 37 Reverse osmosis water tank 40 Dialyzer 41 Dialysate introduction path 43 Dialyzer (blood purification device)
44 Arterial Blood Circuit 45 Venous Blood Circuit 50 Patient 55 Deaerator 56 Membrane Module 57 Pump 60 Sensor 71 Dialysate Branch 72 72 Dialysate Discharge Channel 80 Dialysate Manufacture Device 81 Membrane Module 82 Pressure Tank 84 Pressure Control Valve 85 Hydrogen gas pressurizer

Claims (8)

A hydrogen dissolution apparatus for dissolving hydrogen in water;
A reverse osmosis membrane treatment device connected to the hydrogen dissolution device and performing a reverse osmosis membrane treatment on the water in which the hydrogen is dissolved;
A dialysis fluid preparation device that is connected to the reverse osmosis membrane treatment device and prepares a dialysis fluid obtained by mixing reverse osmosis water treated by the reverse osmosis membrane treatment device and a dialysis stock solution;
A dialysis device connected to the dialysis fluid preparation device and supplied with the dialysis fluid from the dialysis fluid preparation device;
A degassing device provided in the dialysis device for performing degassing of the dialysate;
A sensor provided in the dialysis device for detecting a dissolved hydrogen concentration of the dialysate after the deaeration treatment;
A controller that is connected to the sensor and the degassing device, and that controls degassing pressure when performing the degassing process based on the dissolved hydrogen concentration detected by the sensor ;
The dialysis machine
A blood purification device;
A dialysate introduction path connected to the dialysate preparation device and the blood purification device and for introducing the dialysate prepared in the dialysate preparation device into the blood purification device;
With
The deaeration device is provided in the dialysate introduction path,
The dialysis fluid manufacturing apparatus , wherein the sensor is provided between the deaeration device and the blood purification device in the dialysis fluid introduction path . The deaeration device includes:
A membrane module for separating dissolved gas in the dialysate;
A pump connected to the membrane module and having a motor,
The controller is
A deaeration determining means connected to the sensor for determining a deaeration when performing the deaeration process;
A rotational speed control means connected to the degassing pressure determining means and the pump, and controlling the rotational speed of the motor;
Storage means connected to the degassing pressure determination means, and storing data of a target value of the dissolved hydrogen concentration,
The degassing pressure determining means compares the value of the dissolved hydrogen concentration detected by the sensor with a target value of the dissolved hydrogen concentration stored in the storage means, and determines the degassing pressure based on the comparison result. Decide
The dialysate manufacturing apparatus according to claim 1, wherein the rotation speed control means controls the rotation speed of the motor based on the degassing pressure determined by the degassing pressure determining means.   When the value of the dissolved hydrogen concentration detected by the sensor is smaller than the target value of the dissolved hydrogen concentration stored in the storage unit, the degassing pressure determining unit determines the dissolved hydrogen concentration of the dialysate as the target value. The apparatus for producing a dialysis fluid according to claim 2, wherein the deaeration pressure at the time of performing the deaeration process is determined. A hydrogen dissolution apparatus for dissolving hydrogen in water;
A reverse osmosis membrane treatment device connected to the hydrogen dissolution device and performing a reverse osmosis membrane treatment on the water in which the hydrogen is dissolved;
A dialysis fluid preparation device that is connected to the reverse osmosis membrane treatment device and prepares a dialysis fluid obtained by mixing reverse osmosis water treated by the reverse osmosis membrane treatment device and a dialysis stock solution;
A dialysis device connected to the dialysis fluid preparation device and supplied with the dialysis fluid from the dialysis fluid preparation device;
A degassing device provided in the dialysis device for performing degassing of the dialysate;
A sensor provided in the dialysis device for detecting a dissolved hydrogen concentration of the dialysate after the deaeration treatment;
A control device connected to the sensor and the degassing device and controlling degassing pressure when performing the degassing process based on the dissolved hydrogen concentration detected by the sensor;
With
The dialysis machine
A blood purification device;
Connected to the dialysate preparation device and the blood purification device, connected to the dialysate introduction path for introducing the dialysate prepared in the dialysate preparation device into the blood purification device, the blood purification device, A dialysate discharge path for discharging the dialysate introduced into the blood purification apparatus,
The deaeration device is provided in the dialysate introduction path,
The sensor apparatus for producing a析液Toru characterized in that provided in the dialysate discharge line. A hydrogen dissolution apparatus for dissolving hydrogen in water;
A reverse osmosis membrane treatment device connected to the hydrogen dissolution device and performing a reverse osmosis membrane treatment on the water in which the hydrogen is dissolved;
A dialysis fluid preparation device that is connected to the reverse osmosis membrane treatment device and prepares a dialysis fluid obtained by mixing reverse osmosis water treated by the reverse osmosis membrane treatment device and a dialysis stock solution;
A dialysis device connected to the dialysis fluid preparation device and supplied with the dialysis fluid from the dialysis fluid preparation device;
A degassing device provided in the dialysis device for performing degassing of the dialysate;
A sensor provided in the dialysis device for detecting a dissolved hydrogen concentration of the dialysate after the deaeration treatment;
A control device connected to the sensor and the degassing device and controlling degassing pressure when performing the degassing process based on the dissolved hydrogen concentration detected by the sensor;
With
The dialysis machine
A dialysate introduction path connected to the dialysate preparation device and the sensor and introducing the dialysate prepared in the dialysate preparation device into the sensor;
The degasser apparatus for producing析液Toru characterized in that provided in the dialysate inlet passage. A hydrogen dissolution apparatus for dissolving hydrogen in water;
A reverse osmosis membrane treatment device connected to the hydrogen dissolution device and performing a reverse osmosis membrane treatment on the water in which the hydrogen is dissolved;
A dialysis fluid preparation device that is connected to the reverse osmosis membrane treatment device and prepares a dialysis fluid obtained by mixing reverse osmosis water treated by the reverse osmosis membrane treatment device and a dialysis stock solution;
A dialysis device connected to the dialysis fluid preparation device and supplied with the dialysis fluid from the dialysis fluid preparation device;
A degassing device provided in the dialysis device for performing degassing of the dialysate;
A sensor provided in the dialysis device for detecting a dissolved hydrogen concentration of the dialysate after the deaeration treatment;
A control device connected to the sensor and the degassing device and controlling degassing pressure when performing the degassing process based on the dissolved hydrogen concentration detected by the sensor;
With
The dialysis machine
A blood purification device;
A dialysate introduction path connected to the dialysate preparation device and the blood purification device, for introducing the dialysate prepared in the dialysate preparation device into the blood purification device;
And a dialysate branch path provided by branching from the dialysate introduction path,
The deaeration device is provided in the dialysate introduction path,
The sensor, the dialysate branch line production apparatus in magnetic析液you and being provided on. The dialysis solution according to any one of claims 1 to 6 , wherein the hydrogen dissolving device is an electrolyzed water generating device that performs electrolysis treatment of the water using a solid polymer membrane. manufacturing device. The hydrogen dissolving device is a hydrogen gas pressurizing device that dissolves the hydrogen in the water by bringing hydrogen gas into contact with the water and pressurizing the hydrogen gas. The dialysate manufacturing apparatus according to any one of 6 .

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