KR20160026344A - Blood supply unit - Google Patents

Abstract

A blood transferring apparatus according to the present invention comprises: a blood supply pump supplying the blood of a patient to a blood dialysis filter; a blood recovery pump recovering the blood, having been passed through the blood dialysis filter, to the patient; a first flow path switch switching a flow path between the blood supply pump and the patient or between the blood supply pump and the blood dialysis filter; and a second flow path switch switching a flow path between the blood recovery pump and the patient or the blood supply pump and the blood dialysis filter. In addition, the blood supply pump and the blood recovery pump are configured to include: a cylinder having an internal space; and a piston installed within the cylinder to be able to reciprocate and compressing or expanding the cylinder. The cylinders of the blood supply pump and the blood recovery pump repeats the compression and the expansion simultaneously. The blood transferring apparatus with a simple structure of the cylinder and the piston can rapidly change the blood pressure within the blood dialysis filter and increase water exchange and material transfer between blood and dialysis fluid.

Description

Blood supply unit

In the hemodialysis treatment for removing impurities in the blood by flowing the blood and the dialysis fluid through the hemodialysis filter, the present invention rapidly changes the blood pressure in the hemodialysis filter using the pulsatile blood flow, The present invention relates to a blood transfer device capable of increasing water exchange and mass transfer between a blood vessel and a blood vessel.

If a kidney function is impaired, moisture and waste products to be discharged outside the body are accumulated in the body, and an electrolyte imbalance occurs. Hemodialysis therapy to remove the urinary toxin and excess water accumulated in the body through the hemodialysis filter, which is a semi-permeable membrane, is mainly performed by circulating the blood outside the body by improving the kidney failure symptom have. Hemodialysis is a technique that uses the principle of filtration by diffusion and pressure difference by the concentration difference of the two fluids by flowing the blood to one side of the semipermeable membrane on the other side, And to balance the electrolyte.

A hemodialysis filter equipped with a semi-permeable hemodialysis membrane is used in one container so that mass transfer can be easily performed while blood and dialysate pass through. Hemodialysis filters are mainly hollow fiber membrane type hemodialysis filters in which bundles of hollow fiber membranes are loaded in a cylindrical vessel and potting is performed by using synthetic resin such as polyurethane at both ends thereof. Hollow hemodialysis hemodialysis filter has a large effective contact area between hemodialysis solution and hemodialysis solution compared with hemodialysis hemodialysis filter.

As the blood and the dialysate flow through the hemodialysis filter, the blood pressure and the dialysate flow in opposite directions in the hemodialysis filter, so that the blood pressure in the hemodialysis part of the hemodialysis filter is higher than the dialysate pressure The filtration phenomenon occurs in which the moisture in the blood moves to the dialysis fluid region. On the contrary, since the dialysis fluid pressure is higher than the blood pressure in the blood outlet portion, a reverse filtration phenomenon occurs in which moisture moves from the dialysis fluid to the blood region.

When water moves from the blood to the dialysate area, the wastes in the blood are removed together, which is referred to as convective mass transfer. It is known that the mass transfer by the convection can efficiently remove the mediator - mediated urinary toxin from patients with renal failure and the dialysis prognosis of patients is greatly improved. However, since the size of the hemodialysis filter is limited in the conventional hemodialysis device and the increase of the blood flow rate is considerably limited considering the body weight and the vascular condition of the patient, there is a great difficulty in improving the dialysis efficiency by the transfer of mass by convection .

Korean Patent No. 10-1549221 (Feb. 1, 2014) Korean Patent Publication No. 10-2014-68348 (June 9, 2014)

It is an object of the present invention to provide a blood transfer device capable of improving hemodialysis efficiency by controlling a pressure difference between blood and a dialysis fluid without increasing the size or blood flow of the hemodialysis filter.

According to an aspect of the present invention, there is provided a hemodialysis apparatus comprising: a hemodialysis filter, in which mass transfer occurs between blood and a dialysis fluid; a blood dialysis filter; Blood supply pipe, a blood return pipe connecting the blood dialysis filter and the patient and returned to the patient, a dialysis fluid pump for transferring the dialysis fluid, a dialysis fluid flow tube for flowing the dialysis fluid, and a blood dialysis filter And a blood transfer device for transferring rough blood to the patient. The hemodialysis filter includes a hemodialysis filter container having an inner space and a blood dialysis membrane accommodated in an inner space of the container, and the inner space of the container is partitioned into a blood flow area and a dialysis fluid flow area by a blood dialysis membrane.

The blood transfer device includes a blood supply pump for supplying the blood of the patient to the hemodialysis filter, a blood recovery pump for returning the blood through the hemodialysis filter to the patient, a blood supply pump and a patient, or a blood supply pump A first channel converter for converting the flow path between the hemodialysis filter, a second flow converter provided in the blood return pipe for converting a flow path between the blood return pump and the patient or between the blood return pump and the hemodialysis filter . In addition, the blood supply pump and the blood recovery pump include a cylinder having an internal space, a piston installed inside the cylinder so as to reciprocate, and a piston for compressing or expanding the cylinder.

The first and second flow path converters include first, second, and third flow ports provided on an outer circumferential surface of the housing and the housing, and a rotary rotor disposed inside the housing and hermetically coupled to the inner circumferential surface of the housing A passage through which the blood can flow is provided in the inside of the rotating rotor, and when the passages are connected to either of the two flow ports, the flow path is opened between the connected flow ports.

When the blood supply pump cylinder and the blood collection pump cylinder are inflated, the first channel converter connects the flow path between the patient and the blood supply pump, and the second flow converter converts the blood to the hemodialysis Connect the flow path between the filter and the blood recovery pump. The inflation of the blood supply pump cylinder introduces the blood of the patient into the cylinder, and the blood of the hemodialysis filter flows into the cylinder due to the expansion of the blood return pump cylinder. When the blood of the hemodialysis filter is introduced into the blood return pump cylinder, the blood area of the hemodialysis filter is closed, so that the blood pressure is lower than the dialysis fluid pressure and the backfiltration phenomenon in which the water in the dialysis fluid moves to the blood area Lt; / RTI >

Conversely, when the blood supply pump cylinder and the blood return pump cylinder are compressed, the first flow path converter connects the flow path between the blood supply pump and the hemodialysis filter, and the second flow path converter connects the flow path between the blood return pump and the patient do. The blood in the cylinder is supplied to the hemodialysis filter by the compression of the blood supply pump cylinder, and the blood inside the cylinder is returned to the patient by the compression of the blood return pump cylinder. When the dialysis fluid of the blood supply pump cylinder is supplied to the hemodialysis filter, the blood area of the hemodialysis filter is sealed, so that the blood pressure is higher than the dialysis fluid pressure and the filtration phenomenon in which moisture and waste in the blood move to the dialysis fluid area Lt; / RTI >

That is, when the blood supply pump and the blood return pump are inflated, the inter-membrane pressure (TMP) defined as the difference between the blood pressure and the dialysate pressure in the hemodialysis filter becomes negative (-) and reverse filtration occurs, When the pump is compressed, TMP has a positive value and filtration occurs. As such, one cycle of expansion-compression of the blood supply pump and the blood collection pump constitutes one cycle of reverse filtration-filtration and repeats the reverse filtration-filtration cycle during hemodialysis. During filtration, moisture and waste in the blood are removed, and water lost during reverse filtration is replenished.

Finally, the blood transfer device according to an embodiment of the present invention may further include a pressure relief bypass which connects the front end and the rear end of the second flow path converter, and the pressure relief bypass path may include a front end And is opened / closed by the blood pressure of the blood. By establishing a pressure relief bypass, the blood pressure of the hemodialysis filter can be adjusted to always be within an acceptable range.

As described above, the blood transfer device according to the present invention can rapidly change the blood pressure in the hemodialysis filter, thereby increasing water exchange and mass transfer between the blood and the dialysis fluid during hemodialysis, The hemodialysis efficiency can be improved without increasing the size of the hemodialysis filter or increasing the blood and dialysate flow rate.

1 is a schematic view of a hemodialysis apparatus according to an embodiment of the present invention.
2 is a cross-sectional view of a hemodialysis filter according to an embodiment of the present invention.
3 shows a blood transfer device according to an embodiment of the present invention.
4 is a schematic view of a channel converter according to an embodiment of the present invention.
5 and 6 illustrate blood flow in a blood transfer device according to an embodiment of the present invention.
FIG. 7 shows a blood transfer device according to an embodiment of the present invention showing one blood vessel approach.
Fig. 8 shows a blood transfer device according to the instant embodiment of the present invention in which a pressure relief bypass is provided.
9 is a schematic view of a pressure relief bypass.
10 shows a blood transfer device according to an embodiment of the present invention, which is composed of a tube and a tube pressing member.

Hereinafter, a blood transfer apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In describing the present invention, the sizes and shapes of the components shown in the drawings may be exaggerated or simplified for clarity and convenience of explanation. In addition, the terms defined in consideration of the configuration and operation of the present invention may be changed according to the intention or custom of the user, the operator. These terms are to be construed in accordance with the meaning and concept consistent with the technical idea of the present invention based on the contents throughout the present specification.

FIG. 2 is a cross-sectional view of a hemodialysis filter according to an embodiment of the present invention. FIG. 3 is a cross-sectional view of a hemodialysis apparatus according to an embodiment of the present invention. .

1, a hemodialysis apparatus 10 according to an embodiment of the present invention includes a hemodialysis filter 20 in which mass transfer occurs between blood and dialysate, a blood supply pipe 20 for connecting the hemodialysis filter and the patient, A dialysis fluid pump 13 for connecting the hemodialysis filter to the patient, a blood return pipe 12 for connecting the hemodialysis filter to the patient, a dialysis fluid pump 13 for transferring the dialysis fluid, a dialysis fluid flow tube 14 connecting the dialysis fluid pump and the hemodialysis filter, , And a blood transfer device (30) for supplying the blood of the patient to the hemodialysis filter and returning the blood through the hemodialysis filter to the patient.

2, the hemodialysis filter 20 includes a hemodialysis filter container 21 having an inner space and a blood dialysis membrane 22 accommodated in an inner space of the container, (22) into a blood flow region and a dialysis fluid flow region. A blood inlet 23 and a blood outlet 24 are provided at one end and the other end of the hemodialysis filter container. A dialysis fluid inlet 25 and a dialysis fluid outlet 26 are provided at the upper and lower portions of the outer circumferential surface of the vessel. The blood that flows into the blood inlet 23 flows through the blood flow area inside the blood permeable membrane and is discharged through the blood outlet 24. The dialysis liquid flowing into the dialysis fluid inlet 25 flows into the dialysis fluid flow area outside the blood dialysis membrane And is discharged through the dialysis solution outlet 26.

3, the blood transfer device 30 according to the embodiment of the present invention includes a blood supply pump 31 for supplying blood of a patient to the hemodialysis filter 20, blood that has passed through the hemodialysis filter A first channel converter 41 installed in the blood supply pipe 11 for converting the flow path between the blood supply pump and the patient or between the blood supply pump and the hemodialysis filter, And a second channel converter (42) installed in the recovery pipe (12) for converting the flow path between the blood recovery pump and the patient or between the blood recovery pump and the hemodialysis filter.

The blood supply pump 31 and the blood recovery pump 32 are provided with cylinders 31a and 32a having an internal space, pistons 31b and 32b that are reciprocally movable in the cylinder and compress or expand the cylinder, And a reciprocating piston driver. The piston driver may be of various structures capable of advancing and retracting the pistons 31b and 32b to compress or expand the blood supply pump cylinder 31a and the blood recovery pump cylinder 32a. Here, the blood supply pump cylinder 31a and the blood recovery pump cylinder 32a are repeatedly compressed and expanded, and therefore, they can be driven by the same driver.

4, the first and second flow converters 41 and 42 include a housing 48, first, second, and third flow ports 43, 44, and 45 provided on the outer circumferential surface of the housing, A rotating rotor 47 positioned inside the housing and hermetically engaged with the inner circumferential surface of the housing, and a flow path conversion driver 46 for driving the rotating rotor. As shown in the drawing, a passage through which blood can flow is provided in the rotary rotor 47, and when the passages are connected to either of the two flow ports, the flow path is opened between the connected flow ports. That is, when the flow path is connected between the first port 43 and the second port 44 by the rotation of the rotating rotor 47, the flow path through the third port 45 is blocked, and the rotating rotor 47 rotates And the flow path through the second port is blocked when the flow path between the first port and the third port is opened.

In the case of the first channel converter 41, the first, second and third ports are respectively connected to a blood flow pipe connecting the blood supply pump 31, the patient, and the hemodialysis filter 20, 42, the first, second and third ports are preferably coupled to a blood return pump 32, a hemodialysis filter 20, and a blood flow conduit connected to the patient, respectively. The opening or closing time of the flow path can be adjusted by adjusting the rotational speed of the rotating rotor 47. [

The structure of the channel converter is not limited to that shown and can be changed to another structure capable of converting the flow of blood. For example, as shown in Fig. 4 (d), the blood flow path can be shielded by using the blood flow tube compression member 49 capable of linear reciprocating motion and the compression member driver for providing a linear force to the compression member. For example, when the compression member opens the blood supply pipe connecting the blood supply pump 31 and the patient, the blood supply pipe connecting the blood supply pump and the hemodialysis filter 20 . Conversely, when the compression member opens the blood supply pipe connecting the blood supply pump 32 and the hemodialysis filter 20, the blood supply pipe connecting the blood supply pump and the patient is preferably blocked.

Hereinafter, the operation of the blood transfer device 30 according to the embodiment of the present invention will be described with reference to the accompanying drawings. The dialysis fluid pump 14 is operated so that the dialysis fluid flows through the dialysis fluid area of the hemodialysis filter 20 and the blood is returned to the patient through the hemodialysis filter 20 by the operation of the blood transfer device 30. [ The blood flows into the blood dialysis membrane 22 and the dialysis fluid flows out of the blood dialysis membrane.

5, when the blood supply pump cylinder 31a and the blood collection pump cylinder 32a are inflated, the first flow path converter 41 connects the flow path between the patient and the blood supply pump 31 , And the second flow path converter 42 connects the flow path between the hemodialysis filter 20 and the blood return pump 32. The blood of the patient flows into the cylinder 31a by the expansion of the blood supply pump cylinder 31a and the blood of the hemodialysis filter 20 flows into the cylinder 32a by the expansion of the blood recovery pump cylinder 32a. When the blood of the hemodialysis filter is introduced into the blood return pump cylinder 32a, as shown in the figure, the blood area of the hemodialysis filter 20 is closed, so that the blood pressure is lower than the dialysis fluid pressure, A backfiltration phenomenon that moves to the blood region occurs.

6, when the blood supply pump cylinder 31a and the blood collection pump cylinder 32a are compressed, the first channel converter 41 is connected to the blood supply pump 31 and the hemodialysis filter 20 And the second flow path converter 42 connects the flow path between the blood return pump 32 and the patient. The blood in the cylinder is supplied to the hemodialysis filter by the compression of the blood supply pump cylinder 31a and the blood in the cylinder is returned to the patient by the compression of the blood recovery pump cylinder 32a. When the dialysis fluid of the blood supply pump cylinder 31a is supplied to the hemodialysis filter, the blood area of the hemodialysis filter is closed, so that the blood pressure is higher than the dialysis fluid pressure, and the water in the blood and the waste filtration phenomenon occurs.

That is, when the blood supply pump 31 and the blood return pump 32 are inflated, the inter-membrane pressure TMP defined as the difference between the blood pressure and the dialysis fluid pressure in the hemodialysis filter 20 becomes negative And reverse filtering occurs. On the other hand, when the pump 31, 32 is compressed, TMP has a positive value and filtration occurs. As such, one cycle of expansion-compression of the blood supply pump 31 and the blood collection pump 32 constitutes one cycle of reverse filtration-filtration and repeats the reverse filtration-filtration cycle during hemodialysis. During filtration, moisture and waste in the blood are removed, and water lost during reverse filtration is replenished.

Similarly, when the blood supply pump 31 and the blood return pump 32 are inflated, the patient's blood flows to the blood supply pump through the blood supply pipe 11, and conversely, the blood supply pump 31 and the blood return pump 32 are compressed, the blood of the blood collection pump 32 is returned to the patient through the blood return pipe 12. [ That is, during one cycle of the expansion-compression of the blood supply pump 31 and the blood collection pump 32, one cycle of blood outflow and inflow is achieved. As described above, in the blood transfer device 30 according to the embodiment of the present invention, the blood flow from the blood vessel and the blood flow into the blood vessel are alternately generated.

Therefore, as shown in FIG. 7, in the hemodialysis using the blood transfer device 30 according to the present invention, the outflow and inflow of blood can be achieved by one blood vessel access needle. That is, the blood vessel access needle is inserted into the blood vessel of the patient, and the blood supply tube 11 and the blood return tube 12 are connected to the blood vessel access needle, so that blood flow and inflow may occur alternately. In normal hemodialysis, two separate blood vessel insertion conduits or needles are required, which are connected to the blood supply tube 11 and the blood return tube 12. [ However, the catheter or needle inserted into the blood vessel causes pain to the patient and causes inflammation in the inserted skin. However, in the blood transfer device 30 according to the embodiment of the present invention, blood flow and inflow can be accomplished through one conduit or needle inserted in a patient's blood vessel, so that the above-mentioned problem of access to blood vessels can be overcome .

8, the blood transfer device 30 according to the embodiment of the present invention may further include a pressure relief bypass 35 connecting the front end and the rear end of the second flow path converter 42 Lt; / RTI > The front end of the second channel converter 42 corresponds to the blood return pipe 12 connecting the hemodialysis filter 20 and the blood return pump 32 and the rear end corresponds to the blood return pipe (12). The pressure relief bypass 35 is opened and closed by the blood pressure at the front end of the second flow path converter 42. As can be seen in the drawing, the blood pressure at the front end of the second flow path converter 42 is supplied to the hemodialysis filter (P2) in the blood flowing region.

When the blood supply pump 31 and the blood return pump 32 are compressed, the blood flow area of the hemodialysis filter is sealed, so that the blood pressure of the hemodialysis filter P2) increases. Therefore, the water in the blood moves to the dialysis fluid region by filtration and the blood pressure drops immediately. However, in actual hemodialysis, blood cells and plasma proteins in the blood adhere to the inner wall of the blood dialysis membrane and may interfere with the water movement due to filtration. Therefore, when the blood pressure P2 passing through the hemodialysis filter becomes abnormally high, the blood of the hemodialysis filter can be returned to the patient via the pressure relief bypass 35, whereby the blood pressure of the hemodialysis filter is reduced can do.

Conversely, when the blood supply pump 31 and the blood collection pump 32 are inflated, the blood pressure P2 of the hemodialysis filter decreases because the blood flow area of the hemodialysis filter 20 is closed. Due to the decrease in blood pressure, the water in the dialysis fluid replenishes to the blood area and the blood pressure increases soon. However, as described above, when the blood pressure through the hemodialysis filter is abnormally lowered, the second channel converter 42 can be operated through the pressure relief bypass 35, The blood at the downstream end is supplemented into the blood region of the hemodialysis filter and the blood pressure of the hemodialysis filter can be increased. In this manner, the pressure relief bypass 35 is provided to prevent the blood pressure P2 of the hemodialysis filter from exceeding the allowable value.

9 (a) shows an example of the pressure relief bypass line 35, in which the pressure relief bypass is normally shut off by the compression of the spring, but the blood pressure P2 of the hemodialysis filter is less than the compression force of the spring The spring can be moved upward and the bypass can be opened. Alternatively, as shown in Fig. 9 (b), the blood pressure P2 value of the hemodialysis filter may be input and the pressure relief bypass 40 may be opened or closed.

Here, the pressure relief bypass line 35 is not limited to being opened and closed by the blood pressure P2 at the front end of the second flow path converter 42. The pressure relief bypass can be opened or closed by both ends of the pressure relief bypass, that is, the pressure difference (P2-P1) between the front and rear ends of the second flow passage converter 42 or the blood passing through the hemodialysis filter 20 and the dialysis liquid And can be opened and closed by the inter-membrane pressure TMP which is a difference in pressure value.

It is preferable that the blood pressure or TMP capable of opening the pressure relief bypass line 35 does not have a predetermined value but is set differently depending on the type of blood dialysis membrane to be used. A conventional hemodialysis filter has a tolerance of a positive (+) value and a negative (-) value of TMP in order to prevent breakage of the blood dialysis membrane. The TMP tolerance differs depending on the type of blood dialysis membrane, but its absolute value has a value between 500 and 1,500 mmHg. It is not desirable that the TMP value of the positive (+) reaches the allowable value because the blood pressure (P2) passing through the hemodialysis filter becomes high or the TMP value of the negative (-) reaches the allowable value due to the low blood pressure. Thus, if the blood pressure through the hemodialysis filter is significantly increased (approximately between 200 and 1,500 mm Hg), the blood of the hemodialysis filter flows to the patient via the pressure relief bypass 35 and, conversely, if the pressure is significantly reduced -200 to -1,500 mmHg) The patient's blood is supplied to the hemodialysis filter via the pressure relief bypass 35. As such, by providing the pressure relief bypass 35, the blood pressure of the hemodialysis filter can be adjusted to be always within an acceptable range.

The pressure relief bypass line 35 is not limited to connecting the front and rear ends of the second flow path converter 42, as shown in FIG. The pressure of the blood supply pipe 11 connecting the patient and the blood supply pump 31 and the pressure at the rear end of the second flow path converter 41, that is, the blood return The pressure of the blood return pipe 12 connecting the pump 32 and the patient is the same. When the blood pressure loss in the hemodialysis filter 20 is neglected, the pressure at the downstream end of the first channel converter 41, that is, the pressure of the blood supply pipe 11 between the blood supply pump 31 and the hemodialysis filter 20 It can be seen that the pressure and the pressure at the front end of the second channel converter 42 are the same. Therefore, the pressure relief bypass line 35 may connect the front end and the rear end of the first channel converter 41 or connect the rear end of the first channel converter 41 and the rear end of the second channel converter 42, May be altered to other configurations that allow adjustment of the blood pressure through the patient to within tolerance.

The blood supply pump 31 and the blood recovery pump 32 constituting the blood transfer device 30 are not limited to the cylinders 31a and 32a and the pistons 31b and 32b for compressing or expanding the cylinder , And other structures capable of delivering the dialysis fluid. For example, as shown in Fig. 10, the blood supply pump 31 and the blood recovery pump 32 are constructed of tubes 31c and 32c made of a flexible material capable of contracting and relaxing, tubes Pressure members 31d and 32d, and a pressing member driver for providing a linear force to the tube pressing member. The tube urging members 31d and 32d press the blood supply pump tube 31c and the blood return pump tube 32c at the same time while linearly moving along the guide rails provided on the one side wall. That is, as the expansion and compression of the cylinders 31a and 32a constitute one cycle of the reverse filtration-filtration, the expansion and compression of the tubes 31c and 32c can constitute a reverse filtering-filtering cycle as well.

The tube urging member driver may be of various structures capable of transferring reciprocating linear motion force to the tube urging members 31d and 32d. An exemplary tube biasing member actuator may include a cam for urging the tube urging members 31d and 32d toward the tube support wall and a motor for rotating the cam and the tube urging members 31d and 32d may be rotated by rotation of the cam, The blood supply pump tube 31c and the blood recovery pump tube 32c are simultaneously compressed. When the external force by the cam is removed, the tube urging members 31d and 32d are moved to their original positions , The tubes 31c and 32c are restored to their original state by their own elastic force, and the inside of the tube is expanded. In the present invention, the tube pressurizing device is not limited to the illustrated structure, and the tube pressing members 31d and 32d can be changed into various structures capable of contracting and relaxing the blood supply pump and the blood recovery pump tubes 31c and 32c And the pressing member driver can be changed to another structure capable of operating the tube pressing members 31d and 32d.

As described above, the hemodialysis apparatus according to the embodiment of the present invention is a hemodialyzer having a simple structure having cylinders 31a and 32a, pistons 31b and 32b or tubes 31c and 32c and tube urging members 31d and 32d, The transfer device 30 can be used to quickly change the blood pressure in the hemodialysis filter. This maximizes water exchange and mass exchange between the blood and the dialysis fluid in the hemodialysis filter during hemodialysis and improves hemodialysis efficiency without increasing the size of the hemodialysis filter or increasing the blood and dialysate flow rate have.

10: Hemodialysis device
11: Blood supply tube
12: Blood collection tube
13: Dialysis fluid pump
14: Dialysis fluid flow tube
20: hemodialysis filter
21: hemodialysis filter container
22: blood dialysis membrane
23: blood inlet
24: blood outlet
25: Dialysis fluid inlet
26: dialysis solution outlet
30: blood transfer device
31: Blood supply pump
31a: cylinder
31b: piston
31c: tube
31d: tube pressing member
32: Blood collection pump
32a: cylinder
32b: piston
32c: tube
32d: tube pressing member
35: Pressure relief bypass
41: first flow converter
42: second flow converter
43: First port
44: second port
45: Third port
46:
47: rotating rotor
48: Housing
49: blood flow tube compression member

Claims (9)

A blood transfer apparatus for supplying blood of a patient to a hemodialysis filter and returning blood to the patient through a hemodialysis filter,
A blood supply pump for supplying blood of a patient to a hemodialysis filter;
A blood collection pump for returning the blood of the hemodialysis filter to the patient;
A first channel converter for alternately opening and closing a channel connecting the blood supply pump and the patient, and a channel connecting the blood supply pump and the hemodialysis filter;
And a second channel converter for alternately opening and closing a channel connecting the blood collection pump and the patient, and a channel connecting the blood collection pump and the hemodialysis filter.
The method according to claim 1,
Blood supply pumps and blood return pumps,
A cylinder having an internal space;
And a piston installed inside the cylinder so as to reciprocate to compress or expand the cylinder,
Wherein the blood supply pump cylinder and the blood return pump cylinder are repeatedly compressed and expanded at the same time.
3. The method of claim 2,
When the cylinder is inflated, the first flow path converter opens the flow path connecting the blood supply pump and the patient and cuts off the flow path connecting the blood supply pump and the hemodialysis filter, and the second flow converter converts the blood withdrawal pump and hemodialysis The flow path connecting the filter is opened and the flow path connecting the blood return pump and the patient is blocked,
When the cylinder is compressed, the first channel converter opens the channel connecting the blood supply pump and the hemodialysis filter, blocks the channel connecting the blood supply pump and the patient, and the second channel converter converts the blood return pump and the patient And the flow path connecting the blood return pump and the hemodialysis filter is shut off.
The method according to claim 1,
Blood supply pumps and blood return pumps,
A tube made of a flexible material capable of contracting and relaxing;
And a tube pressing member for discharging blood in the tube by pressurizing the tube,
Wherein the blood supply pump tube and the blood recovery pump tube are repeatedly compressed and expanded at the same time.
5. The method of claim 4,
When the tube is inflated, the first channel converter opens the channel connecting the blood supply pump and the patient, blocks the channel connecting the blood supply pump and the hemodialysis filter, and the second channel converter disconnects the blood collection pump and the hemodialysis The flow path connecting the filter is opened and the flow path connecting the blood return pump and the patient is blocked,
When the tube is compressed, the first channel converter opens the channel connecting the blood supply pump and the hemodialysis filter, blocks the channel connecting the blood supply pump and the patient, and the second channel converter converts the blood return pump and the patient And the flow path connecting the blood return pump and the hemodialysis filter is shut off.
6. The method according to any one of claims 1 to 5,
A blood supply pipe connecting the blood supply pump and the hemodialysis filter or a blood return pipe connecting the hemodialysis filter and the blood recovery pump and a blood supply pipe or a blood recovery pump connecting the blood supply pump and the patient, And a pressure relief bypass which connects any one of the blood return pipes to the blood return pipe.
The method according to claim 6,
The pressure-
The difference in blood pressure at both ends connected by the pressure relief bypass, or
The pressure of the blood supply line connecting the blood supply pump to the hemodialysis filter, or
The pressure of the blood return line connecting the hemodialysis filter and the blood withdrawal pump, or
And the inter-membrane pressure, which is the difference between the blood passing through the hemodialysis filter and the dialysate pressure, is opened or closed by any one of the values.
The method according to claim 6,
Wherein the first and second flow path converters comprise:
housing;
A rotating rotor hermetically coupled to an inner circumferential surface of the housing and having a passage for allowing blood to flow therein; And
And a flow path changing actuator for rotating the rotating rotor.
The method according to claim 6,
Wherein the first and second flow path converters comprise:
A tube compression member;
And a compression member driver for providing a linear reciprocating force to the tube compression member.

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