JP2524876Y2 - Hemodialysis machine - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a hemodialysis apparatus using a hemodialysis technique such as a so-called artificial kidney.

[Prior Art] A conventional hemodialysis apparatus will be described with reference to FIG. FIG. 5 is an example of a monitoring device for dialysis. Blood extracted as extracorporeal circulating blood from the patient 1 passes through the arterial blood circuit 2, and the extracorporeal circulating blood flow is set by the blood pump 3. Usually, heparin is injected into the extracorporeal blood as an anticoagulant for blood by the syringe pump 4 before the blood pump 3. The blood that has exited the blood pump 3 enters the arterial drip chamber 100, is air trapped, and is sent to the dialyzer 5. The blood purified by the dialyzer 5 is air trapped in the venous drip chamber 6 and then returned to the patient 1.
Usually, a venous pressure gauge 7 is set in the venous drip chamber 6, and the internal pressure of the drip chamber 6 is measured as a venous pressure.

On the other hand, with respect to the dialysate, dialysate from a multi-person dialysate supply device (not shown) is first supplied to the supply dialysate line 80.
Through the liquid supply solenoid valve 9 from the liquid supply port 8,
Enter the storage tank 10. In the storage tank 10, the heater
While the dialysate is heated by 11, the dialysate in the tank is degassed by the throttle unit 12 and the deaeration pump 13. Storage tank
An air filter 14 is attached to the upper part of the filter 10 to block entry of various bacteria in the air. The storage tank 10 also has an upper limit detection float switch 15 for detecting that the dialysate liquid level has reached a set high level, and a lower limit detection for detecting that the dialysate level has reached a set low level. A float switch 16 is provided.

The dialysate that has exited the storage tank 10 is supplied to the dialyzer 5 through a dialyzer inlet-side liquid stop solenoid valve 17. The dialysate, which receives wastes from the patient's blood in the dialyzer 5 and flows out of the dialyzer 5, passes through the dialyser outlet side liquid stop solenoid valve 18, is sucked by the dialysate pump 21, and is discharged from the drain port 22. It is discharged outside the device. When the dialysate temperature becomes abnormal, the dialyzer inlet-side solenoid valve 17 and the dialyzer outlet-side solenoid valve 18 are closed, and the inlet side of the solenoid valve 17 and the outlet side of the solenoid valve 18 are connected. The bypass valve 19 of the bypass passage 20 is opened and the abnormal dialysate is not supplied to the dialyzer 5, but is drawn through the bypass passage 20 by the dialysate pump 21 and discharged from the drain port 22. Has become.

The control unit 30 controls the entire apparatus, and controls the pump 3,
21, control of valves 9, 17, 18, and 19, signal processing from float switches 15 and 16, and the like are performed.

“Problem to be Solved by the Invention” In the conventional hemodialysis apparatus, the liquid level control in the storage tank 10 was performed as follows.

* When the liquid level is higher than the upper limit detection float switch 15, the liquid supply solenoid valve 9 is closed.

* If the liquid level is lower than the lower limit detection float switch 16, the liquid supply solenoid valve 9 is opened.

In other words, according to the detection states of the float switches 15 and 16,
Only the supply electromagnetic valve 9 was turned ON / OFF (fully opened or completely closed).

Fluctuation of the liquid level in the storage tank 10 is caused by the difference between the supply flow rate from the multi-person dialysate supply device and the dialysate flow rate determined by the setting operation of the dialysate pump 21 when the supply solenoid valve 9 is open. Determined by balance. Usually, the dialysate flow rate of the monitoring device for dialysis is often set to 400 to 600 ml / min, especially 500 ml / min. On the other hand, the supply flow rate supplied from the multi-person dialysate supply device is 600 ml / min per one dialysis monitoring device. Therefore, when the dialysate flow rate of the dialysis monitoring device is set to 500 ml / min, the liquid level of the storage tank 10 always rises while the liquid supply solenoid valve 9 is kept open. For example, assuming that the capacity of the storage tank 10 between the upper limit detection float switch 15 and the lower limit detection float switch 16 is 3 liters, the dialysis fluid level is reduced to the lower limit detection float switch 16 within 30 minutes. The liquid level is at the position of the upper limit detection float switch 15. On the other hand, 6 minutes after the dialysate level reaches the upper limit detection float switch 15, the dialysate level becomes the position of the lower limit detection float switch 16.

If the liquid level in the storage tank 10 fluctuates, the temperature control accuracy will decrease, and if the liquid level is high, the dialysate will have a lower temperature,
When the liquid level is low, the dialysate is at a high temperature. Further, not only the temperature control but also the water pressure fluctuation due to the liquid level fluctuation causes the problem that the deaeration pressure fluctuates and the deaeration ability fluctuates. Numerical example: For example, a case where 20 dialysis monitoring devices are connected to a 20-dialysis fluid supply device, and if the number of dialysis monitoring devices to be connected is 10, the supply flow rate per device Is usually doubled, and in this case, the liquid level fluctuation of the storage tank 10 becomes more severe.

As described above, in the conventional monitoring device for dialysis, since the liquid level of the storage tank 10 fluctuates drastically, as described above, the secondary phenomena such as instability of the dialysate temperature and the degassing ability are caused. Also, since the opening and closing frequency of the liquid supply solenoid valve 9 is high, the problem of noise generated at the time of opening and closing and the liquid supply solenoid valve 9
There was also a problem that the life of the device was short.

"Means for solving the problem" The hemodialysis apparatus of the present invention uses a dialyzer to contact extracorporeal blood of a patient with renal insufficiency with dialysate to remove excess ions, unnecessary waste and water in the patient's blood. A dialysis treatment is performed while being moved into the dialysate, and a storage tank for storing the dialysate is provided between the inlet of the supply dialysate line to which the dialysate is supplied and the dialyzer. A liquid level detecting means for detecting a set high liquid level and a low liquid level of the dialysate liquid level is provided, and the supply dialysate is shut off between the inlet of the supply dialysate line and the storage tank. A hemodialysis apparatus having a supply valve inserted therein, a flow step setting means provided in series with the supply valve and capable of setting the flow rate of the dialysate in two or more stages, and wherein the liquid level detection means has a low liquid level. When it detects When the flow rate of the flow rate step setting means is set so that the supply flow rate of the dialysate to the storage tank is determined by the flow rate of the dialysate passing through the supply valve, and the liquid level detection means detects a high liquid level, the storage is performed. Control means for setting the flow rate of the flow rate step setting means so that the supply flow rate of the dialysate to the tank is determined by the flow rate step setting means and smaller than the supply flow rate when the low liquid level is detected.

[Embodiment] Fig. 1 shows an embodiment of the present invention, and the same parts as those in Fig. 5 are denoted by the same reference numerals, and redundant description is omitted. In FIG. 1, a leak solenoid valve 23 is installed in the supply dialysis line 80 between the liquid supply solenoid valve 9 and the storage tank 10 as flow rate setting means. The leak solenoid valve 23 is a valve that leaks at a flow rate corresponding to the supply pressure while being controlled to be “closed”.

FIG. 2A shows the structure of a normal solenoid valve, which is of a normally closed type (closed when not energized). When no current flows through the coil 36, the plunger 37 is pressed downward in the figure by the force of the spring 38, and the diaphragm 35 is pressed at the lower end of the plunger 37.
Is pressed against the opening 81 of the flow path, the opening 81 is closed, and the liquid does not flow. When the coil 36 is energized, the plunger 37 moves upward, the diaphragm 35 rises and the opening 81 opens, and the liquid from the inlet port 31 passes through the opening 81 and exits from the outlet port 32.
Flows to

FIG. 2B shows a structural example of the leak solenoid valve 23. FIG. 2A
The configuration is almost the same as the above, except that the inlet port 31 and the outlet port
The difference is that a small hole 34 is formed in a wall 33 between the hole 32 and the wall 32.
In the closed control state (when no current is flowing through the coil 36), the liquid flows through the small holes 34, and the flow rate is
Depends on 34 hole diameter. When the leak solenoid valve 23 is "closed", the diaphragm 35 is pressed downward to close the opening 81 as in the case of a normal solenoid valve, so that only the liquid flowing from the leak small hole 34 flows. At the time of “open”, the liquid flows through the normal flow path passing through the opening 81 and the small hole for leak.

Next, the operation of the liquid supply solenoid valve 9 and the leak solenoid valve 23 in this embodiment will be described below.

* When the liquid level exceeds the upper limit detection float switch 15, the liquid supply solenoid valve 9 is closed.

* When the liquid level is between the upper limit detection float switch 15 and the lower limit detection float switch 16, the liquid supply solenoid valve 9 is opened and the leak solenoid valve 23 is closed.

* When the liquid level is lower than the lower limit detection float switch 16, both the liquid supply solenoid valve 9 and the leak solenoid valve 23 are opened.

FIG. 3 shows a liquid supply pressure-leak flow rate characteristic of the leak solenoid valve 23 in this embodiment. In this example, the supply pressure is 0.5k
g / cm ² leak at 400 ml / min, 1.0 kg / cm ²
It leaked at 720 ml / min and at 1.5 kg / cm ² it leaked at 960 ml / min. The normal supply pressure of the liquid supplied from the multi-person dialysate supply device is 0.5 to 0.7 kg / cm ² . Now, set the supply pressure to 0.
Assuming 5 kg / cm ² , the leakage flow rate of the leakage solenoid valve 23 is 400 ml
/ Min. Change the capacity of the storage tank 10 between the upper limit detection float switch 15 and the lower limit detection float switch 16.
When the supply flow rate is 600 ml / min and the dialysate flow rate supplied to the dialyzer 5 is 500 ml / min (adjusted by the dialysate pump 21), the dialysate level is changed from the upper limit detection float switch 15 to the lower limit detection float. The time to reach switch 16 is 3000 / (500−
400) = 30 minutes, which is 5 times longer than the conventional example. On the other hand, the time required for the dialysate level to reach the float switch 16 for detecting the upper limit from the float switch 16 for detecting the lower limit is the same as that of the conventional example, so that 3000 / (600−500) = 30 minutes. In other words, the time required for the dialysate level to make one round trip between the float switches 15 and 16 is one hour, and for a five hour dialysis time, the dialysate level is five round trips. (Approximately 8.3 reciprocations in the conventional example) Regarding temperature control accuracy and suppression of fluctuations in degassing ability, a mode in which the dialysate level falls from the upper limit detection float switch 15 to the lower limit detection float switch 16 is a significant effect compared to the conventional mode. Obtainable. The function of the control unit 30 in this embodiment is the same as that of the conventional example except for the control related to the leak solenoid valve 23.

FIG. 4 shows another embodiment of the leak solenoid valve 23. This is to flatten a silicon tube 40 connecting the liquid supply solenoid valve 9 and the storage tank 10 to adjust the flow rate. The rotation of the DC motor 44 is reduced by a gear head 43, and the reduced output shaft is connected to the applanation head 44 by a spring coupling 42. The applanation head 44 is threaded externally and the base 45
Screwed through the female screw of As a result, the motor 44
Is converted into a linear motion of the applanation head 44 in a direction perpendicular to the tube 40. The degree to which the tube 40 is pressed against the receiving plate 46 by the linear movement of the applanation head 44 changes, and the degree to which the tube 40 is crushed changes. Although not shown, in this embodiment, the tube
Position where 40 is closed (upper limit of applanation head 44) and tube 40
Is detected by a microswitch at a position where the applanation is not performed at all (the lower limit of the applanation head 44).
The motor 44 operates. The control section 30 performs the forward / reverse rotation control of the DC motor 44, the determination of the upper / lower limit position of the applanation head 44, and the change in the resistance of the potentiometer 48.

Regarding the relationship between the applanation with respect to the tube 40 and the flow rate of the liquid in the tube 40, for example, when the tube 40 is not applanated at all (however, the applanation head 44 is in contact with the outer wall of the tube 40), The resistance of a potentiometer 48 connected to the shaft on the opposite side of the tube side of the motor 44 by a coupling 47 is made zero, and the motor 44 is rotated to measure the actual flow rate of the liquid flowing through the tube 40 and the potentiometer. It can be obtained by associating 48 resistance values.

In this embodiment, a flow rate close to the flow rate of the dialysate supplied to the dialyzer 5 (FIG. 1) is detected by the resistance value of the potentiometer 48 within a range not exceeding the flow rate, and the flatness is set. The liquid level fluctuation at 10 can be made very small.

"Effects of the invention" As described above, according to the invention, by inserting means for setting the flow rate in series with the liquid supply valve, it is possible to effectively buffer the liquid level fluctuation in the storage tank, The number of times of controlling the liquid supply valve can be reduced, so that noise is less generated and the life of the liquid supply valve is prolonged. When controlling the temperature of the dialysate in the storage tank, the temperature control accuracy becomes higher,
When deaeration is performed in the storage tank, the defunctionality is stabilized. The flow rate step setting means can be constructed relatively simply, and may be a slightly improved conventional solenoid valve.

[Brief description of the drawings]

FIG. 1 is a block diagram showing an embodiment of the hemodialysis apparatus according to the present invention, FIG. 2A is a sectional view showing a conventional solenoid valve,
FIG. 2B is a cross-sectional view showing an example of a leak solenoid valve as a flow rate step setting means, FIG. 3 is a view showing a feed pressure-leak flow rate characteristic of the leak solenoid valve of FIG. 2B, and FIG. FIG. 5 is a block diagram showing another example of a conventional hemodialysis apparatus.

Claims (1)

(57) [Scope of request for utility model registration] 1. A dialysis treatment is performed by bringing extracorporeal blood of a patient with renal failure into contact with a dialysate by a dialyzer and moving excess ions, unnecessary waste and water in the patient's blood into the dialysate. A storage tank for storing dialysate is provided between an inlet of a supply dialysate line to which dialysate is supplied and the dialyzer, and the storage tank has a set high liquid level of the dialysate level. And a liquid level detecting means for detecting a low liquid level is provided, in a hemodialysis apparatus in which a supply valve capable of shutting off a supply dialysate is inserted between an inlet of the supply dialysate line and the storage tank, A flow rate step setting means that is provided in series with the supply valve and that can set the flow rate of the dialysate in two or more steps; and when the liquid level detection means detects a low liquid level, the dialysate is supplied to the storage tank. Supply flow is the above supply Setting the flow rate of the flow rate step setting means so as to be determined by the flow rate of the dialysate, and when the liquid level detecting means detects a high liquid level, the supply of the dialysate to the storage tank is performed by the flow rate step setting means. And a control means for setting the flow rate of the flow rate step setting means so as to be smaller than the supply flow rate at the time of detection of the low liquid level.