JP3669738B2 - Bicarbonate dialysate adjuster for multi-person - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to an apparatus for obtaining a bicarbonate dialysate for use in hemodialysis, and relates to a multi-person bicarbonate dialysate regulator for adjusting dialysate from sodium bicarbonate powder and water.
[0002]
[Prior art]
Today, dialysate used for dialysis is prepared from two types of dialysis agents, one that does not contain sodium bicarbonate (hereinafter referred to as “agent A”) and one that includes sodium bicarbonate (hereinafter referred to as “agent B”). Bicarbonate dialysate is frequently used.
[0003]
The adjustment of the bicarbonate dialysis solution that is normally performed is performed by transferring each liquid of the A agent and B agent adjusted to a predetermined concentration (hereinafter referred to as A solution and B solution) to the dialysate adjusting means, The liquid A, the liquid B, and the water are mixed at a predetermined ratio (usually liquid A: liquid B: water = 1: 1.26: 32.74).
[0004]
Recently, as a B agent, without purchasing a B liquid adjusted to a predetermined concentration, a B powder (hereinafter referred to as B powder) in which only sodium bicarbonate is formulated as a powder is purchased, and sodium bicarbonate dissolving means is used in a dialysis facility. (Hereinafter, referred to as “B powder dissolution means”), a solution that is dissolved and diluted is often used as the B liquid.
[0005]
Dialysis requires a large amount of dialysate, and a large amount of solution B (usually about 5 liters per dialysis per patient) is consumed. In addition, for a large number of patients, it is normal to perform about 5 hours of dialysis treatment twice a day, and some facilities perform dialysis treatment three times a day.
[0006]
Therefore, in order to adjust the B liquid consumed at a time, a very large tank is required. Also, since the B liquid has a problem in stability, Solution B is prepared by dissolving. This B powder dissolving means puts a predetermined amount of water and B powder into a tank of 100 to 300 l, and stirs to a predetermined concentration (often 7 W / V% and sometimes 5.8 W / V%). It is a method of obtaining B liquid.
[0007]
In dialysis of a large number of patients, the number of patients receiving dialysis treatment is not always the same for each dialysis, and it is necessary to change the amount of solution B adjusted at one time. Therefore, in the above-described dissolution method, a large space is required, and nerves are used for measuring the amount of water and B powder for each dissolution, which is a troublesome work.
[0008]
It is advantageous in terms of space saving that the amount of the B liquid to be adjusted at one time is small in the B powder dissolving means. From such a point of view, a sodium bicarbonate continuous dissolution apparatus has been proposed as an apparatus that automatically dissolves B powder at any time during dialysis to obtain a B solution having a predetermined concentration (Japanese Patent Publication No. 1-55893).
[0009]
This continuous dissolution apparatus supplies powder B by powder supply means such as a powder feeder and water by a water supply means to the dilution tank, and controls the powder supply means or water supply means according to the concentration after stirring, By dispensing sodium bicarbonate or water, a liquid B having a predetermined concentration is obtained. The B liquid is transferred from the dilution tank to the storage tank, and the B liquid is supplied from the storage tank to the dialysate adjustment device in the next step. A series of these operations is repeated during dialysis.
[0010]
However, since the dissolution and concentration adjustment are performed in a batch system, the structure and operation are complicated, and a storage tank having a capacity larger than the amount of liquid B adjusted in the dilution tank is required.
[0011]
In recent years, the number of large-scale dialysis facilities has increased, and there has been a demand for B-powder dissolving means that can supply more B solution while reducing the occupied space. In the proposed batch method, as the supply amount of the liquid B is increased, the time required for scale-up, dissolution and concentration adjustment of the dilution tank and the storage tank is limited.
[0012]
In addition, as a technical background of the present invention, the amount of concentrated liquid mixed is adjusted at the time of dialysate adjustment, corresponding to the case where the concentration of concentrated B liquid obtained by dissolving B powder during dialysis changes. A system for adjusting a medical treatment fluid and a cartridge used therefor have been proposed as a liquid mixture having a predetermined concentration by adjustment (Japanese Patent Laid-Open No. 63-194666).
[0013]
This is because water is supplied from a water source to a cartridge inlet containing a sufficient amount of B powder for one dialysis, and the supplied water is dissolved by contact with the B powder. It becomes a concentrated liquid. This concentrated liquid is mixed with water at the mixing point via a flow rate adjusting means provided on the downstream side of the cartridge, and the concentration of the mixed liquid is measured by a measuring means located downstream of the mixing point. According to the measured value, the flow rate adjusting means is controlled to obtain a solution having a predetermined concentration. However, this type of proposal is intended to be applied to a single dialyzer having the function of adjusting dialysate for one patient and the function of a dialyzer.
[0014]
[Problems to be solved by the invention]
However, it is difficult to apply the above-described conventional dialysate adjusting device as a device for adjusting dialysate for a large number of patients (multi-person dialysate adjusting device). In particular, there are problems in the following points.
[0015]
In dialysis of a large number of patients, the amount of dialysate consumed per unit time changes as the number of patients receiving treatment during dialysis increases or decreases.
[0016]
In order to cope with this, in the dialysate adjustment device for multiple people, the adjusted dialysate is temporarily stored in a storage tank, the dialysate is transferred from the storage tank to the dialyzer, and the dialysate is adjusted when the dialysate is reduced in the storage tank. A system that restarts and replenishes the storage tank with dialysate is adopted.
[0017]
However, the system has a function of continuously adjusting the dialysate, and in addition, in a dialysate adjuster for a large number of people, the amount of B-end used in one dialysis often changes. If the cartridge is filled with B powder sufficient for one dialysis, application to a dialysate adjustment apparatus for a large number of people is a problem.
[0018]
Furthermore, B liquid (concentrated liquid) is CO₂In the proposed system, the CO generated downstream of the filter₂The degassing means is not considered. However, the CO generated downstream of the filter₂Will flow through the flow rate control means together with the B concentrated liquid, causing a problem in concentration control. The problem is particularly great when large bubbles flow through the flow rate control means.
[0019]
Accordingly, an object of the present invention is to supply sodium bicarbonate powder and water in a dissolution tank to prepare a sodium bicarbonate solution B solution having a required concentration, and dilute the sodium bicarbonate solution as needed to obtain a predetermined concentration of weight. By obtaining a sodium carbonate solution, a large amount of sodium bicarbonate solution can be supplied with a small facility, and additional preparation of sodium bicarbonate solution in a dissolution tank can be easily achieved even during dialysis. An object of the present invention is to provide a bicarbonate dialysate adjusting device.
[0020]
[Means for Solving the Problems]
  A multi-person bicarbonate dialysis fluid adjusting device according to the present invention introduces sodium bicarbonate powder and water, and stirs and mixes them, with the undissolved sodium bicarbonate solution on the filter through the filter. A dissolution tank configured to obtain a sodium bicarbonate solution having a required concentration in the compartment, water supply means having a control valve connected to the dissolution tank, and a communication chamber connected to the compartment of the dissolution tank.With the undissolved sodium bicarbonate solution on the filter in the dissolution tank, the sodium bicarbonate concentrate present at the bottom of the filter is sent directly to the dialysate adjustment unit.It is characterized by comprising sodium bicarbonate solution extraction means and dialysate adjustment means that is connected to the sodium bicarbonate solution extraction means so that a sodium bicarbonate solution of a required concentration is directly sent.
[0021]
In this case, the dialysate adjusting means is provided with a sodium bicarbonate liquid control means and a concentration measuring means in the sodium bicarbonate liquid taking out means, and the sodium bicarbonate liquid taking out means according to the concentration measured value by the concentration measuring means. Combined with water supply means equipped with water control means for adjusting the concentration of sodium bicarbonate solution, and further combined with means for supplying dialysate not containing sodium bicarbonate solution to adjust the dialysate, and obtained dialysis A predetermined amount of liquid can be stored in the storage tank.
[0022]
The dialysate adjusting means mixes a predetermined amount of dialysate not containing sodium bicarbonate with a predetermined amount of water supplied from the sodium bicarbonate solution supplied from the sodium bicarbonate solution extraction means and water supply means. It can introduce | transduce into a tank, it can also comprise so that the dialysate may be adjusted and the predetermined amount of the obtained dialysate may be stored in a storage tank.
[0023]
On the other hand, the dissolution tank defines a compartment for obtaining a sodium bicarbonate solution having a required concentration through a filter at the bottom thereof, and a stirring means is provided above the filter, and an upper limit level setter and a lower limit are further provided above the filter. A level setting device may be provided.
[0024]
Further, the stirring means can be constituted by means for rotating a screw, transmitting ultrasonic waves, and circulating liquid using a pump.
[0025]
Furthermore, a water supply means having a control valve is connected to the dissolution chamber in which a compartment for obtaining a sodium bicarbonate solution having a required concentration is obtained through a filter, and further connected to the compartment through a pump. A branch water supply unit that communicates with a discharge unit serving as a stirring unit disposed above the filter may be provided.
[0026]
[Action]
According to the multi-person bicarbonate dialysis fluid adjusting device according to the present invention, the B powder is continuously dissolved in water, and the sodium bicarbonate solution (hereinafter referred to as B fluid) obtained thereby is dialyzed fluid adjusting means. And is diluted with water by the dialysate adjusting means to obtain a sodium bicarbonate solution having a predetermined concentration, and is mixed with a dialysate not containing sodium bicarbonate (hereinafter referred to as “A solution”), each having a predetermined mixing ratio. The dialysis solution consisting of can be adjusted.
[0027]
In addition, according to the present invention, a large amount of B powder is dissolved over a long period of time by adding the B powder to the dissolution tank as needed, and the B liquid is smoothly supplied to at least one dialysate adjusting means. Adjustment of dialysate can be achieved smoothly.
[0028]
Furthermore, it is not necessary to measure the B powder corresponding to the B liquid expected to be consumed during dialysis before the start of dialysis, and an appropriate amount can be added, and additional B powder can be added at any time during dialysis. Is possible.
[0029]
Therefore, according to the present invention, the structure and operation are simplified, and a large amount of B liquid can be supplied, compared to a structure in which dissolution of B powder and adjustment of B liquid are repeated by a batch method. It becomes.
[0030]
【Example】
Next, an embodiment of a multi-person bicarbonate dialysis solution adjusting device according to the present invention will be described in detail with reference to the accompanying drawings.
[0031]
Example 1
FIG. 1 is a schematic system diagram showing an embodiment of the device of the present invention. In FIG. 1, reference numeral 10 indicates a dissolution tank, and sodium bicarbonate (NaHCO 3) is added to the dissolution tank 10._Three) Only powdered B powder (PB) and water (W) are supplied. In this case, an appropriate amount of B powder (PB) is introduced through the opening 12. The opening is usually provided with an open / close lid. Water (W) is introduced through a control valve 18 through a water supply line 16 communicating with a water supply source 14 such as an RO unit, and when the water level reaches a predetermined level in the dissolution tank 10, an upper limit level detector 20a. Thus, this state is detected, and the control valve 18 is closed by the detection operation of the upper limit level detector 20a to complete the water supply. In addition, although the temperature of the water used in this case can obtain B liquid of a required density | concentration by sufficient stirring even if it is 10 degreeC, in order to make a dissolution rate or control easy, it is 20-30 like usual. It is preferable to set the water temperature to ° C.
[0032]
Further, the dissolution tank 10 is provided with a stirring means 22, and by operating the stirring means 22, the dissolution of the B powder supplied to the dissolution tank 10 is promoted. In addition, as the stirring means 22, means utilizing rotation of a screw, transmission of ultrasonic waves, liquid circulation by a pump, or the like can be used.
[0033]
However, when the B powder of the dialysis agent AF-2P (manufactured by Fuso Yakuhin Kogyo Co., Ltd.) currently in circulation is observed with an electron microscope, there are many particles having a size of 100 μm or less. Therefore, a filter 24 that does not allow these B powders to pass to the extent that there is no practical problem is provided in the dissolution tank 10 as appropriate. Therefore, the filter 24 does not have a large opening, and when water is supplied from the upper part of the filter 24, the air in the compartment 26 defined by the filter 24 can hardly escape.
[0034]
Therefore, an exhaust line 30 provided with a degassing means 28 is provided outside the dissolution tank 10 so as to communicate the compartment 26 with a position above a predetermined water level. As this degassing means 28, an electromagnetic control valve, a pump or the like is usually used, but it is preferable to quickly release air in the compartment 26 using a pump. Accordingly, for example, by operating the agitation means 22 and then operating the degassing means 28, air is released from the exhaust line 30 and the B liquid flows into the compartment 26.
[0035]
The B liquid staying in the compartment 26 in this way is configured to be appropriately sent to the dialysate adjusting means 40 via the B liquid extraction line 32. In this case, the B concentrated liquid is replenished into the compartment 26 through the filter 24 by appropriately operating the stirring means 22 in accordance with the extraction of the B concentrated liquid in the compartment 26.
[0036]
When the B liquid is consumed in the dialysate adjusting means 40, the B liquid staying in the compartment 26 of the dissolution tank 10 is taken out, and the water level in the dissolution tank 10 is lowered to the set level of the lower limit level detector 20b, Under the action of the lower limit level detector 20b, the control valve 18 is opened to supply water into the dissolution tank 10 from the water supply line 16. Next, when the water level in the dissolution tank 10 rises to the set level of the upper limit level detector 20a, the control valve 18 is closed under the action of the upper limit level detector 20a to complete the water supply.
[0037]
In the state where the B powder is sufficiently present in the dissolution tank 10 and the dissolution of the B powder is promoted by stirring, the liquid B fed to the dialysate adjusting means 40 is a concentrated liquid having a substantially saturated concentration. However, it is not necessary to feed the dialysate adjusting means 40 as a substantially saturated B liquid, and a low concentration of B in a range that does not hinder the normal dialysate adjustment by the dialysate adjusting means 40. It can be sent as a liquid.
[0038]
B liquid is CO₂Is easily released, and a large amount of B powder dissolves and the B concentrated liquid is consumed.₂As a result, CO₂Becomes a large bubble and flows out to the liquid take-out line 32, which hinders the adjustment of the B liquid. Therefore, in the present embodiment, the degassing means 28 is operated as appropriate, and the CO in the compartment 26 is₂To the outside of the dissolution tank 10, and a large amount of CO₂Is configured not to leak.
[0039]
In addition, the B powder in the dissolution tank 10 decreases with the consumption of the B liquid. By adding the B powder to the dissolution tank 10 as needed, a large amount of B liquid can be continuously adjusted over a long period of time. Supply can be made. In addition, although B powder | flour injection | throwing-in to the dissolution tank 10 can also be performed with other powder feeders etc., you may be made to perform B powder | flour injection | pouring operation | work manually.
[0040]
That is, in this embodiment, the B powder to be charged into the dissolution tank 10 does not need to be metered in and can be additionally charged even during dialysis. Rather, there is no problem in performing this work manually.
[0041]
As described above, the B liquid is sent to the dialysate adjusting means 40 via the B liquid take-out line 32, but the water is further sent via the water supply line 34 communicating with the water supply source 14. It is configured. And in the dialysate adjustment means 40, dialysate is adjusted for many patients. The configuration of the dialysate adjusting means 40 will be described later.
[0042]
Example 2
FIG. 2 is a schematic system diagram showing another embodiment of the device of the present invention. In FIG. 2, for convenience of explanation, the same components as those in the embodiment shown in FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted.
[0043]
That is, in the embodiment shown in FIG. 2, the water supply to the dissolution tank 10 is performed by the water supply line 16 that is connected to the bottom compartment 26 defined by the filter 24 via the control valve 18. In this case, a branch water supply line 36 is connected in communication with the compartment 26, the tip of the branch water supply line 36 is branched into two, and one branch flow path 38a is formed above the compartment 26 (for example, the filter 24). The other branch flow path 38b is positioned at the lower part (for example, the bottom part) of the compartment 26. Furthermore, the dissolution tank 10 is provided with an upper limit level detector 20a and a lower limit level detector 20b, and water is supplied through the water supply line 16 to the set level.
[0044]
Further, the branch water supply line 36 is connected to the liquid feed pump 42 to form a discharge line 44, and this discharge line 44 is placed in the B end (PB) fed to the upper side of the filter 24 of the dissolution tank 10. It is arranged so as to communicate with the buried discharge means 46.
[0045]
In this embodiment, the dissolution of the B powder (PB) in the dissolution tank 10 is performed from the branch flow paths 38a and 38b of the branch water supply line 36 by driving the pump 42 provided in the discharge line 44. This is facilitated by sucking the liquid inside and discharging the liquid from the discharge means 46 via the discharge line 44.
[0046]
However, a specific configuration of the discharge means 90 is as shown in FIG. In FIG. 5, the discharge means 46 inserts and arranges a discharge pipe 48 that forms the tip of the discharge line 44 while supporting the center of the filter 24, and forms a liquid collection chamber 50 on the outer periphery of the insert tip. Thus, the rotor 52 is rotatably mounted. Further, on the outer peripheral portion of the rotor 52, jet pipes 54 and 54 extending radially with the discharge pipe 48 as a center are connected symmetrically. Reference numeral 51 denotes a through hole for communicating with the liquid collecting chamber 50 provided in the discharge pipe 48, 53 denotes a stopper for preventing the rotor 52 from dropping off, and 55 denotes the injection pipe 54. The injection hole provided in is shown.
[0047]
In the discharge means 46 configured as described above, the liquid whose pressure has been increased by driving the pump 42 flows into the liquid collection chamber 50 of the rotor 52 from the through hole 51 provided in the discharge pipe 48, and further, the discharge hole of the discharge vip 54. As the liquid is ejected from 55 toward the B powder (PB) in the dissolution tank 10, the dissolution of the B powder is promoted.
[0048]
In this case, when the amount of B powder in the dissolution tank 10 is reduced and the resistance to liquid ejection is reduced, the injection hole 55 is arranged so that the rotor 52 is rotated by the reaction force of the jet flow, It is preferable to provide the injection hole 55 so as to be directed obliquely downward so that the liquid is smoothly ejected toward the B end remaining on the filter 24.
[0049]
The B liquid obtained by dissolving the B powder passes through the filter 24 and flows into the compartment 26. As a result, the B liquid is circulated in the dissolution tank 10 by driving the pump 42, and the water in the compartment 26 at the start of operation is replaced with the B liquid.
[0050]
The B liquid thus obtained is appropriately fed to the dialysate adjusting means 40 via the B liquid take-out line 32 as in the above-described embodiment.
[0051]
When the liquid level in the dissolution tank 10 decreases to the set level of the lower limit level detector 20b with the consumption of the liquid B, the control valve 18 is opened and water supply is started from the water supply line 16, and the dissolution tank 10 When the liquid level reaches the set level of the upper limit level detector 20a, the control valve 18 is closed and the additional water supply is stopped.
[0052]
One branch flow path 38a on the suction side when the pump 42 is driven is opened near the filter 24 at a position higher than the opening to the dissolution tank 10 of the B liquid extraction line 32, and the other branch flow The path 38 b is connected to the bottom of the dissolution tank 10. Accordingly, the liquid is sucked from both the upper and lower parts of the compartment 26 by the driving of the pump 42, and the CO generated in the compartment 26 is₂Most of the water is sucked into the discharge line 44. As a result, a large amount of CO is discharged into the B liquid take-out line 32.₂Will not flow.
[0053]
That is, the function of the agitation means 22 and the degassing means 28 described in the embodiment of FIG. 1 is made by one pump by opening one branch flow path 38a on the suction side of the pump 42 in the upper part of the compartment 26. 42 can also be used.
[0054]
According to the B-powder dissolving means constituted by the dissolving tank 10 in the above-described embodiment, it is not necessary to measure the amount of B-powder charged into the dissolving tank 10, so that it is not a troublesome operation, and it is necessary at any time during dialysis. The B powder can be additionally charged, and since the B liquid can be normally supplied as a concentrated liquid, the dissolution tank 10 can be made small.
[0055]
Furthermore, in this embodiment, the B powder is not dissolved by a batch method, but the B powder is dissolved and the B liquid is always prepared in the dissolution tank 10 during dialysis, and the B liquid can be appropriately supplied. In addition to the need for a special structure and operation, it does not require a large storage tank for storing the B liquid in addition to the dissolution tank 10, so that it can be made compact and a large amount of B liquid can be supplied. Is possible.
[0056]
Next, the configuration of the dialysate adjusting means 40 in the first and second embodiments will be described.
[0057]
3 and 4 are system diagrams showing a schematic configuration of the dialysate adjusting means 40. FIG. Although not shown, these dialysate adjusting means 40 are additionally set with functions provided in a conventional multi-person dialysate adjusting apparatus such as a heating means, a concentration measuring means, a degassing means, and a pump as appropriate. Of course you can.
[0058]
Dialysate adjustment means (part 1)
First, in the dialysate adjusting means 40 shown in FIG. 3, the B liquid take-out line 32 introduced from the outside is provided with a B liquid control means 60 comprising a metering pump or the like, and a B liquid concentration measuring means 62 comprising a conductivity meter or the like. And the B liquid control means 60 is driven to lead the B liquid to the B liquid extraction line 32 from the compartment 26 (see FIGS. 1 and 2), and the concentration of the B liquid is measured by the B liquid concentration. Measure by means 62. On the other hand, the water supply line 34 introduced from the outside is provided with water control means 64 comprising a metering pump or the like, and the B liquid extraction line 32 downstream from the B liquid concentration measuring means 62 is connected and arranged downstream thereof.
[0059]
Accordingly, at the junction 35 between the water supply line 34 and the B liquid take-out line 32, the B liquid control means 60 and the B liquid control means 60 and the need are sequentially determined according to the concentration of the B liquid measured by the B liquid concentration measuring means 62. The water control means 64 is adjusted to adjust the B liquid flow rate from the B liquid extraction line 32 and the water supply flow rate from the water supply line 34 as necessary.
[0060]
Further, an A liquid supply line 68 for supplying the A liquid via the A liquid control means 66 is connected and arranged downstream of the water supply line 34. Accordingly, at the junction 37 between the water supply line 34 and the A liquid supply line 68, the A liquid is injected into the mixed liquid of water and B liquid to adjust the dialysate.
[0061]
The dialysate adjusted in this way is introduced into the storage tank 70 and stored. The storage tank 70 is provided with an upper limit level detector 71 a and a lower limit level detector 71 b, and a required amount of dialysate is always stored and sent to each dialyzer via the discharge channel 72. In this case, the supply flow rate of the dialysate to each dialysis machine varies depending on the increase or decrease in the number of patients undergoing dialysis treatment.
[0062]
The storage tank 70 is normally opened to the atmosphere via an air filter (not shown). When the liquid level in the storage tank 70 is lowered to the position of the lower limit level detector 71b, the dialysate adjustment operation is started. When the liquid level rises to the set level of the level detector 71b, the dialysate adjustment operation is stopped. Therefore, the dialysate during dialysis is adjusted intermittently.
[0063]
Further, in the present embodiment, as the water control means 64 provided in the water supply line 34, for example, one configured as shown in FIG. 6 can be used. In this case, the water flow rate often changes during adjustment of the dialysate due to a change in the pressure of the water supplied from the water supply source 14 (see FIGS. 1 and 2).
[0064]
However, in FIG. 6, the water control means 64 inserts and arranges a piston 82 that reciprocates in the cylinder 80, and seals 83 and 85, 85 are inserted into the insertion portions of the piston 82 and piston rods 84, 84 with the cylinder 80, respectively. And liquid-tight pump chambers 86 and 88 are formed inside the cylinders 80 on both sides of the piston 82, respectively. The flow paths 90 and 92 communicating with the pump chambers 86 and 88 are connected to the water supply line 34 via control valves 91a and 93b and 93a and 91b on the upstream side and the downstream side, respectively.
[0065]
In the state shown in FIG. 6, the water control means 64 configured as described above first opens the control valves 91a and 91b, and the piston 60 moves to the right by the pressure of the water supply, and water passes through the control valve 91a. Then, the water in the pump chamber 88 flows from the flow path 90 to the downstream side of the water supply line 34 through the control valve 91b. Next, when the control valves 91a and 91b are closed and the control valves 93a and 93b are opened, the piston 60 moves to the left, and the water in the pump chamber 86 passes through the control valve 93b from the flow path 90 and downstream of the water supply line 34. Liquid is fed to the side. Therefore, by opening and closing the control valves 91a, 91b and 93a, 93b as appropriate, water can be continuously supplied to the water supply line 34.
[0066]
In this case, the value of the water flow rate can be obtained by sequentially calculating by providing the piston speed measuring means 94 and measuring the piston speed. Then, the speed at which the B liquid control means 60 and the A liquid control means 66 shown in FIG.
[0067]
Next, the operation of the dialysate adjusting means 40 having the above configuration will be described. The B liquid prepared by the B powder dissolving means shown in FIGS. 1 and 2 is supplied from the B liquid extraction line 32, but the concentration of this B liquid changes. In addition, the liquid A is supplied to a predetermined concentration.
[0068]
Therefore, the concentration of the B liquid is measured by the B liquid concentration measuring means 62, and the dialysate having a predetermined concentration is obtained according to the concentration measurement value (and the water flow rate), so that the B liquid control means 60 and the A liquid are obtained. The operating speed of the control means 66 is adjusted. However, while the concentration of the B liquid is stably supplied, the mixing amount ratio of water, the B liquid, and the A liquid does not change, but when the concentration of the B liquid changes, the concentration of the B liquid is sequentially increased. In accordance with the change in the measured value, the B liquid control means 60 and the A liquid control means 66 are also controlled so that the dialysate has a predetermined concentration with respect to the water flow rate, and the B liquid extraction line 32 and the A liquid. The flow rates of the liquid B and the liquid A flowing through the supply line 68 are changed.
[0069]
Dialysate adjustment means (part 2)
FIG. 4 shows another embodiment of the dialysate adjusting means. For convenience of explanation, the same components as those in the embodiment shown in FIG. 3 will be described with the same reference numerals.
[0070]
That is, in the embodiment shown in FIG. 4, the B liquid supplied from the B liquid extraction line 32 and the A liquid supplied from the A liquid supply line 66 are introduced into the mixing tank 74. In this case, the liquid A may be configured to be supplied to the mixing tank 74 after a predetermined amount is measured in a measuring tank (not shown) in advance. Further, a water supply line 64 is connected to the mixing tank 74 via a control valve 62 so as to supply water. In this way, when the liquid level in the mixing tank 74 reaches the set level by the level detector 75, the control valve 62 is closed to stop water supply. Therefore, in this case, the dialysate for the volume set by the level detector 75 of the mixing tank 74 is adjusted by adjusting the dialysate once.
[0071]
However, in this embodiment, the B liquid concentration measuring means 62 is provided in the B liquid extraction line 32. Therefore, the concentration of the B liquid supplied from the B powder dissolving means (see FIG. 1 and FIG. 2) changes. In this case, in order to adjust the dialysate having a predetermined concentration for each adjustment of the dialysate, What is necessary is just to set so that the quantity of sodium bicarbonate melt | dissolved in the supplied B liquid may become fixed.
[0072]
Therefore, the time required for supplying the B liquid is set to a fixed time T every time the dialysate is adjusted. During this time T, the B liquid control means 60 is sequentially controlled according to the measurement value of the B liquid concentration measuring means 62, and the amount of sodium bicarbonate contained in the B liquid supplied during the unit time ΔT is determined. Operate to be constant. That is, it is possible to know in advance how much sodium bicarbonate is contained in the B liquid with respect to the B liquid concentration measurement value (for example, conductivity), and the B liquid control means corresponds to the concentration measurement value. The 60 control data can be stored in advance in the apparatus. In this way, the B liquid control means 60 can be controlled with almost no time delay by using the control data in accordance with the concentration measured value by the B liquid concentration measuring means 62.
[0073]
A circulation channel 77 provided with a pump 76 is disposed outside the mixing tank 74, and the dialysate concentration is measured while stirring the liquid in the mixing tank 74. If it is confirmed that the dialysate concentration is normal, the dialysate storage tank 70 is transferred to the dialysate storage tank 70 through the discharge passage 72 led out from a part of the circulation passage 77 through the control valve 78 and stored. The stored dialysate can be appropriately supplied to a large number of dialysis machines.
[0074]
The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and various design changes can be made without departing from the spirit of the present invention. .
[0075]
For example, in the embodiment shown in FIG. 1 and FIG. 2, it is possible to supply the B liquid from the B powder dissolving means to the plurality of dialysate adjusting means 40 by branching the B liquid extraction line 32. .
[0076]
Further, when the B-powder dissolving means and the dialysate adjusting means 40 are configured as separate units as in the prior art, both units are not necessarily arranged close to each other in the dialysis facility. It is preferable to provide a pump means or a heat insulation treatment to the B liquid extraction line 32 shown in FIGS.
[0077]
Furthermore, for the purpose of supplying a clean B liquid, it is possible to easily carry out the addition of cleaning and disinfecting functions, the installation of a germicidal lamp, the installation of a filter for the purpose of sterilization, etc. in the B powder dissolving means of the present invention. it can.
[0078]
The B powder can be charged into the melting tank 10 with a powder feeder or the like, but the B powder can be charged manually by hand. In other words, the B powder to be fed does not need to be metered in and can be added even during dialysis. Therefore, the work of charging the B powder is not a troublesome work, and this work is performed manually. There is no obstacle to doing. In this case, it is preferable to have a function of notifying that additional charging of the B end is necessary.
[0079]
That is, when the remaining B powder in the dissolution tank 10 is low, the concentration of the B liquid sent to the dialysate adjusting means 40 decreases as a result of the additional water supply. As a result, the measured value of the B liquid concentration measuring means 62 decreases. When this measured value falls below a set concentration (usually, a light concentration within a range that does not interfere with dialysate adjustment), the alarm means having a buzzer or a display function is notified. In this case, it can also comprise so that additional water supply may not be carried out. By this alarm notification, the B powder may be additionally supplied manually as required.
[0080]
In addition, another B liquid concentration measuring means may be appropriately provided in the B powder dissolving means, and the notification may be performed based on the measurement value of the B liquid concentration measuring means.
[0081]
In this way, in the B powder dissolving means in the present invention, a large amount of B liquid is supplied to the dialysate adjusting means 40 over a long period of time by adding additional B powder to the dissolving tank 10 at any time. Adjustments can be made.
[0082]
In the embodiment of the dialysate adjusting means shown in FIG. 3 and FIG. 4, the case where the liquid A is adjusted to a predetermined concentration has been described, but the case where the liquid A concentration also changes is as follows. It can also be operated.
[0083]
For example, when a powder (or granule) (A powder) is dissolved in a dialysis facility to form a liquid A as the agent A, the agent A has a composition mainly containing a plurality of electrolyte compounds. The adjustment of the liquid is usually performed by dissolving a predetermined amount of A powder in a predetermined amount of water. It should be noted that there may be cases where the concentration does not always reach the predetermined concentration every time the liquid A is adjusted due to a measurement error of water or the A powder.
[0084]
On the other hand, when the concentration of the liquid A changes, a liquid A concentration measuring unit is appropriately provided in the liquid A supply line 68 shown in FIGS. Then, the B liquid control means 60 and the A liquid control means 66 are sequentially controlled so that the dialysate has a predetermined concentration according to the change in the measurement value by the A liquid concentration measurement means and the change in the B liquid concentration measurement value. Can be configured to.
[0085]
【The invention's effect】
  As is clear from the above-described examples, according to the present invention, sodium bicarbonate powder and water are introduced and mixed together, and the undissolved sodium bicarbonate solution is passed through the filter with the undissolved sodium bicarbonate solution on the filter. A dissolution tank configured to obtain a sodium bicarbonate solution having a required concentration in the compartment, water supply means provided with a control valve connected to the dissolution tank, and a communication chamber connected to the dissolution chamber compartment.With the undissolved sodium bicarbonate solution on the filter in the dissolution tank, the sodium bicarbonate concentrate present at the bottom of the filter is sent directly to the dialysate adjustment unit.Sodium bicarbonate solution extraction means, and dialysate adjustment means that is directly connected to the sodium bicarbonate solution extraction means to send a sodium bicarbonate solution at a required concentration, thereby providing sodium bicarbonate in the dissolution tank. Powder and water are supplied to create a sodium bicarbonate solution with the required concentration, and this sodium bicarbonate solution is diluted as needed to obtain a sodium bicarbonate solution with a predetermined concentration. It is possible to obtain a multi-person bicarbonate dialysis solution adjusting device that can supply a solution and that can easily achieve additional preparation of a sodium bicarbonate solution in a dissolution tank even during dialysis.
[0086]
According to the multi-person bicarbonate dialysis fluid adjusting device of the present invention, at least 1 is prepared by dissolving a large amount of B powder over a long period of time by adding additional B powder into the dissolution tank as needed. B liquid can be smoothly supplied to the dialysate adjustment apparatus of a stand.
[0087]
Furthermore, it is not necessary to measure the B powder corresponding to the B liquid expected to be consumed during dialysis before the start of dialysis, and an appropriate amount can be added, and additional B powder can be added at any time during dialysis. Is possible.
[0088]
Therefore, in the apparatus of the present invention, it is not troublesome to manually introduce the B powder into the dissolution tank, and since the ratio of the B liquid is small, the B liquid is supplied to the conventional multi-person dialysate supply apparatus. Compared with the B-powder dissolving means, it can be made compact, and the adjustment work can be easily achieved. That is, in the dissolution tank, the B liquid is not adjusted, but the inside of the dissolution tank is configured to be the B powder and the B liquid of the required concentration during dialysis, and the B liquid that is always prepared in the dissolution tank is used as needed. Since the B liquid having a predetermined concentration can be adjusted by dilution, a large storage tank for storing the B liquid is not required, and a small amount of B liquid can be supplied.
[0089]
The apparatus of the present invention has an advantage that the structure and operation are simple, and a small amount of dialysate can be supplied, compared with a configuration in which dissolution of B powder and adjustment of B solution are repeated by a batch method. Have
[Brief description of the drawings]
FIG. 1 is a schematic system diagram showing an embodiment of a multi-person bicarbonate dialysate adjusting apparatus according to the present invention.
FIG. 2 is a schematic system diagram showing another embodiment of the multi-person bicarbonate dialysate adjusting apparatus according to the present invention.
FIG. 3 is a schematic system diagram showing an embodiment of dialysate adjusting means applied to the multi-person bicarbonate dialysate adjusting apparatus according to the present invention.
FIG. 4 is a schematic system diagram showing another embodiment of dialysate adjusting means applied to the multi-person bicarbonate dialysate adjusting apparatus according to the present invention.
5 is an enlarged cross-sectional view of a main part showing a configuration example of discharge means in the multi-person bicarbonate dialysis fluid adjusting device shown in FIG. 2;
6 is an enlarged cross-sectional explanatory view of a main part showing a configuration example of water control means in the dialysate adjusting means shown in FIG. 3. FIG.
[Explanation of symbols]
10 Dissolution tank
12 opening
14 Water supply
16 Water supply line
18 Control valve
20a Upper limit level detector
20b Lower limit level detector
22 Stirring means
24 filters
26 room
28 Degassing means
30 Exhaust line
32 Liquid extraction line
34 Water supply line
35 Junction
36 Branch water supply line
37 Junction
38a Upper limit level detector
38b Lower limit level detector
39 Control valve
40 Dialysate adjustment means
42 Pump
44 Discharge line
46 Discharge means
48 Discharge pipe
50 Liquid collection chamber
51 through holes
52 Rotor
53 Stopper
54 Injection pipe
55 Injection hole
60 B liquid control means
62 Concentration measuring means
64 Water control means
66 A liquid control means
68 A liquid supply line
70 storage tank
71a Upper level detector
71b Lower limit level detector
72 Discharge channel
74 Mixing tank
75 level detector
76 pumps
77 Circulation channel
78 Control valve
80 cylinders
82 piston
83 Seal
84 Piston rod
85 seal
86, 88 Pump room
90, 92 flow path
91a, 91b Control valve
93a, 93b Control valve
94 Piston speed measuring means

Claims (6)

Sodium bicarbonate powder and water were introduced, and these were stirred and mixed, so that a sodium bicarbonate solution having a required concentration was obtained in the compartment through the filter while the undissolved sodium bicarbonate solution was on the filter. A dissolution tank, a water supply means provided with a control valve communicating with the dissolution tank, and a filter connected to the dissolution tank compartment, while the undissolved sodium bicarbonate solution remains on the dissolution tank filter. Sodium bicarbonate solution extraction means for sending out the sodium bicarbonate concentrate present at the lower part directly to the dialysate adjustment section, and the sodium bicarbonate solution of the required concentration is directly connected to the sodium bicarbonate solution extraction means. A multi-person bicarbonate dialysis fluid adjusting device, comprising: a dialysate adjusting means to be sent.   The dialysate adjusting means is provided with sodium bicarbonate solution control means and concentration measuring means in the sodium bicarbonate solution taking-out means, and this sodium bicarbonate solution taking-out means is provided according to the concentration measurement value by the concentration measuring means. Combined with a water supply means equipped with a water control means for adjusting the concentration of the sodium solution, and further connected with a means for supplying a dialysate containing no sodium bicarbonate solution to adjust the dialysate, the place of the obtained dialysate The apparatus for adjusting a bicarbonate dialysate for multi-person use according to claim 1, wherein a fixed amount is stored in a storage tank.   The dialysate adjusting means includes a predetermined amount of dialysate not containing sodium bicarbonate and a predetermined amount of sodium bicarbonate liquid supplied from the sodium bicarbonate liquid take-out means and water supplied from the water supply means in the mixing tank. The apparatus for adjusting a multi-person bicarbonate dialysis solution according to claim 1, wherein the apparatus is configured to introduce and adjust the dialysis solution and to store a predetermined amount of the obtained dialysis solution in a storage tank.   The dissolution tank defines a compartment for obtaining a sodium bicarbonate solution having a required concentration through a filter at the bottom, and a stirring means is provided above the filter, and an upper limit level setter and a lower limit level set above the filter. The apparatus for adjusting a bicarbonate dialysate for multi-person use according to claim 1, further comprising a vessel.   The apparatus for adjusting bicarbonate of dialysate for a large number of persons according to claim 1, wherein the agitating means comprises means for rotating a screw, transmitting ultrasonic waves, and circulating fluid by a pump.   A water supply means provided with a control valve is connected to the dissolution chamber in which a compartment for obtaining a sodium bicarbonate solution having a required concentration is obtained via a filter, and the filter is further connected to the compartment via a pump. 2. A multi-person bicarbonate dialysis solution adjusting device according to claim 1, further comprising a branch water supply means for communicatingly connecting a discharge means as an agitation means disposed in the upper part of the apparatus.

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