DE19827408A1 - Fluid pump assembly as an external blood pump - Google Patents

Abstract

The fluid pump assembly has at least one valve as a non-return valve (2) with at least one flexible hose (5,6). The valve (2) is secured so that, when in operation, it gives a circular push action with its longitudinal axis. The flexible hoses (5,6) are secured (12) in a variable setting according to the rotating radius of the powered valve (2).

Description

The invention relates to a fluid pump arrangement for preference show use in medical areas where a pul fluid delivery by moving the pump mechanism is achieved by means of a drive unit and at least has a valve for determining the conveying direction.

Such fluid pumps are used, for example, as extracorporeal Blood pumps used in cardiac surgery. Possible use areas are also conceivable outside of medical technology, for example in closed systems of biotechnology, chemical industry and laboratory technology.

For open heart surgery this is usually the case Decommissioning is necessary for the duration of the operation. The circle During this time, the patient's course is mechanically maintained receive. The heart functions as a blood pump, the function of the lungs is a membrane oxygenator. The blood is in Hoses from the body through the machine back to the body managed by the patient. This extracorporeal cycle is realized by a heart-lung machine. Known so far Blood pumps can be used as a technical device however, the natural function of the heart is only conditional put. They cause, especially after a few hours Use, blood damage. With the currently used Blood pumps are in spite of a high technical development the effects of blood damage on the patients  not to be neglected.

For example, blood pumps have been used for years, that work as roller pumps based on the displacement principle. On silicone tube inserted into a housing is exzen Rollers that are rotatably rotated are continuously squeezed. The Blood is delivered virtually continuously in the direction of movement of roles. The volume flow is through selection of the hose knife, the speed of the roller guide and the Degree of tube squeeze adjustable.

The disadvantage of this solution is that roller pumps that are through simple application and low operating costs drawing that are problematic with hemolysis. One On the one hand, the occlusion of the tube leads to a considerable one Shear stress on the blood with the result that erythrocytes be crushed, on the other hand it happens due to the elevation to the migration of the hose material during migration of tube particles, such as broken mussels, into the bloodstream of the Patient. After just three hours of use the roller pump causes an increased risk for the Patient.

Other known blood pumps work as centrifugal pumps. The The blood is promoted either by an inspection feltes or an unbladed impeller. For this are under different embodiments have become known, however, in also have disadvantages in most cases. So at these pumps hemolysis of the blood by exceeding the Limit shear stresses of the erythrocytes due to high speed gradient between the rotor and the stationary housing and caused by turbulence in the pump. Besides, that is Operating time limited by the risk of thrombus formation, which among other things due to a locally increased temperature load Blood buildup due to frictional heat at bearings in Connection with poor washing behavior arises.

Another disadvantage is that moving parts, bearings  or seals inside the pump vessel, which are used for Damage to the blood. The production of such Pump mechanisms also have a one time only Use proven to be very expensive.

DE 38 74 392 T2 discloses a fluid pump, which is intended to rule out at least some of the shortcomings mentioned. It describes a rotary pump, which consists of a rotatable Container that has a central inlet and a tang in it tial direction on the outer peripheral region of the container has ordered outlet and connected to a device that rotates the container around an axis. In the container a horn-shaped membrane made of a flexible plastic arranged that a broke between the container and membrane gas is tightly enclosed. Because of the rotation The container is the liquid that flows through the inlet into the Container flows, rotated, causing a centrifugal flow occurs so that the liquid ent speaking of the rotational speed of the container from the Outlet opening can flow out. Because the liquid is thus is largely closed off from the outside environment also almost free of penetrating germs.

The disadvantage here is that the membrane used - um Ge to avoid driving sources such as cracking or breaking - must be designed as a double chamber membrane, which is ins special in terms of the one-time use of the rotary edible vessel has an unfavorable effect on the production costs. In addition, a permanent, 100% tightness between the with a gas-filled cavity and the one filled with blood Pump room must be guaranteed, since only a few milliliters of gas can lead to fatal embolism of the patient. This Sealing in turn has an adverse effect on the manufacturing cost out.

Finally, US Patent 5,266,012 describes a so-called called vibration pumps, where a hose or a Lei tion with the valve arranged therein at intervals from this  is fixed by means of holding devices and via a drive device performs a linear forward and backward movement. At least sections of the Hose or the line formed bellows-like.

The disadvantage of this solution is that the linear pre and Backward movement due to the constant change between acceleration Cleaning and braking the drive from an energy perspective is unfavorable. The bellows-like design of the hose or the line also provides a source of blood damage because areas are created inside the hose in which the blood is not continuously transported. Another disadvantage is that due to the constructive out leadership-related size of the fluid pump.

It is therefore an object of the invention to provide a fluid pump arrangement to indicate the structurally simple and safe hand available and inexpensive to manufacture and use of materials is the blood when used in medical fields of the patient with a low risk of haemolysis and can replace the pumping function of the heart.

According to the invention the object is achieved in that the at least one valve is designed as a check valve, that the valve is connected to at least one flexible hose is and that the valve is fixed so that it in the driven state with its longitudinal axis a circular thrust execution.

This non-occlusive fluid pumps according to the invention arrangement largely prevents when used in cardiac surgery going to damage the blood as the destruction of the red Blood cells are reduced and there are no harmful substances Can get blood that contaminate it. The simple one Construction of the fluid pump also ensures an economical Manufactured since neither actively moving parts nor seals or Bearings in the fluid area are available.  

In the further embodiment of the fluid pump arrangement, the solution according to the invention essentially in two Lichen embodiments can be advantageously implemented.

According to a first advantageous embodiment, the valve stationary directly in the outlet area of a pump vessel arranged, the pump vessel is rotationally symmetrical and instructs one and one almost at right angles to it ordered outlet, on each of which a flexible hose is arranged. The pump vessel is in one on the inlet side gimbal mounted and articulated on the exhaust side connected to the drive unit. The longitudinal axis of the pump barrel runs eccentrically to the longitudinal axis of the An drive unit and leads a in the driven state Circumferential surface of a cone describing wobble.

The pumping action is achieved in that the time fluctuating pressures in the fluid caused by the wobble of the Pump vessel are created in interaction with the dynamic Properties of the valve, its opening and closing ver causes. Thereby a pulsating promotion is achieved. In Depends on the speed of the non-rotating Movement and the geometrical dimensioning of the pump and the supply and discharge lines are flow rate and Controllable pressure.

After a preferred embodiment of the invention The solution is to deflect the longitudinal axis of the pump vessel in adjustable from the longitudinal axis of the drive unit educated.

In this way, the performance parameters of the Fluid pump arrangement adapted to the actual requirements become.

Characterized in that the drive shaft of the drive unit is articulated and is detachably connected to the pump vessel and centrally on is arranged on the outlet end of the pump vessel  one achieved that a quick and safe replacement of the pump container can only be used once. To the other Ren is used in conjunction with the gimbal is sufficient for the pump vessel to perform the intended wobble movement carries out.

After a simple and inexpensive execution of the Fluid pump arrangement is the drive shaft as a cardan shaft, which is connected to the drive motor via a universal joint, trained and on the pump vessel by means of a detachable connection attached.

After another advantageous and inexpensive fort Formation of the solution according to the invention is the pump tube shaped.

To the heart function in the most natural way possible To be able to replace it is provided according to the invention that the Size of the pump vessel to the flow rate of the fluid is adjusted.

Furthermore, it is advantageous for cost reasons if that at least one valve as a sail flap or ball valve is trained.

The invention is described below with reference to an embodiment game are explained in more detail. The accompanying drawing shows doing in

Fig. 1 shows a schematic representation of the fluid pump assembly according to claim 2,

Fig. 2 is a side view of a fluid pump assembly according to FIG. 1,

Fig. 3 is a sectional view according to section AA of Fig. 2,

Fig. 4 basic representation of the circular thrust moving Venti les,

Fig. 5 shows another embodiment of the fluid pump arrangement according to claim 6 and

Fig. 6 shows a schematic representation for illustrating the wobble movement of the pump vessel according to Fig. 5.

According to FIGS . 1 to 3, the fluid pump arrangement consists of the drive unit 1 , the check valve 2 designed as a sail flap valve, to the inlet and outlet 3 and 4 of which a hose 5 and 6 is connected. The hose ends enclose the inlet 3 and the outlet 4 in a form-fitting and tight manner, so that no liquid can escape. An extension is formed on the valve 2 , through which the drive shaft 7 is guided and fastened to the valve 2 by means of a simple screw connection 8 . To carry out the circular thrust movement and to hold the valve 2 , the drive shaft 7 is fixedly arranged in a holder 10 via shaft joints 9 . The valve 2 is connected to the drive shaft 7 so that its longitudinal axis 11 lies in the circular plane of the circular thrust movement. Characterized in that the valve 2 executes a circular thrust movement, on the one hand a continuous drive of the valve and on the other hand a natural, pulsating delivery of the fluid is achieved. This is due to the fact that a pressure difference occurs across the valve, due to phase-shifting, fluctuating pressure at the circumferential hose ends. The check valve 2 is thereby periodically opened and closed, the flow rate and delivery head of the fluid pump arrangement depending on the radius, the speed and the dynamic properties as well as the flow resistance in the circuit. The tubes 5 and 6 are fastened by means of simple tube attachments 12 at such a distance from the valve 2 that the circular thrust movement can be carried out without problems — for example with the aid of a crank mechanism. Fig. 4 illustrates the circular thrust movement in a basic manner.

FIGS. 5 and 6 show a second embodiment of to the invention OF INVENTION A fluid pump assembly. According to this, the fluid pump arrangement consists of the drive unit 13 , a tubular pump vessel 14 which has an inlet 15 and an outlet 16 arranged at right angles thereto, which are each connected to flexible hoses 17 and 18 . The check valve 19, which is designed as a ball valve, is arranged in a fixed position in the outlet area of the pump vessel. The pump vessel 14 is fastened on the inlet side in a cardanic suspension 20 and releasably connected on the outlet side at the end of the non-angled pump vessel part via a universal joint 21 to the cardan shaft 22 of the drive unit 13 . The pump vessel is arranged between the gimbal 20 and universal joint 21 that the longitudinal axis 23 of the pump pengefäßes 14 eccentrically to the longitudinal axis 24 of the Antriebsein unit 13 , the angle of deflection of the longitudinal axis 23 of the pump vessel 14 is adjustable. Simple screw connections 25 allow the device to be adjusted.

In the driven state, the pump vessel 14 executes a wobbling movement that describes the lateral surface of a cone. Fig. 6 illustrates the wobbling movement of the pump vessel 14 and shows that by the arrangement of the valve 19 in the angled outlet 16 this executes the same circular thrust movement as in the fluid pump arrangement according to FIG. 1st

Reference list

1

Drive unit

2nd

check valve

3rd

Inlet

4th

Outlet

5

tube

6

tube

7

drive shaft

8th

Detachable connection

9

Shaft joint

10th

bracket

11

Longitudinal axis of the valve

12th

Hose attachment

13

Drive unit

14

Pump vessel

15

Inlet

16

Outlet

17th

tube

18th

tube

19th

check valve

20th

gimbal suspension

21

Universal joint

22

propeller shaft

23

Longitudinal axis of the pump vessel

24th

Longitudinal axis of the drive unit

25th

Screw connection

Claims (12)

1. Fluid pump arrangement for preferred use in medical areas in which a pulsating fluid delivery is achieved by moving the pump mechanism by means of a drive unit and which has at least one valve for determining the direction of delivery, characterized in that the at least one valve as a check valve ( 2 , 19 ) that the valve ( 2 , 19 ) is connected to at least one flexible hose ( 5 , 6 , 18 ) and that the valve ( 2 , 19 ) is fixed in such a way that in the driven state it has its longitudinal axis ( 11 ) performs a circular push. 2. Fluid pump arrangement according to claim 1, characterized in that the valve ( 2 ) is connected directly to the ends of two flexible hoses ( 5 , 6 ), that on both sides of the valve ( 2 ) the hoses ( 5 , 6 ) in at least one fixing device ( 12 ) are held, the respective hose length between valve ( 2 ) and fixing device ( 12 ) depending on the running radius of the circular thrust movement of the driven valve ( 2 ) to be carried out variably adjustable. 3. Fluid pump arrangement according to claim 2, characterized characterized that the circular thrust movement  is generated by a crank mechanism. 4. Fluid pump arrangement according to claim 2 and 3, characterized in that the connecting hoses ( 5 , 6 ) consist of an expandable material. 5. Fluid pump arrangement according to claim 2 to 4, characterized in that for fixing the hoses ( 5 , 6 ) usual hose fastenings, such as clamps ( 12 ) or the like are used. 6. Fluid pump arrangement according to claim 1, characterized in that the valve ( 19 ) is arranged directly in the outlet region ( 16 ) of a pump vessel ( 14 ), that the pump vessel ( 14 ) is rotationally symmetrical, one and one almost perpendicular to it arranged outlet ( 15 and 16 ), on each of which a flexible hose ( 17 , 18 ) is arranged, that the pump vessel ( 14 ) is fixed on the inlet side in a cardanic suspension ( 20 ) and on the outlet side articulated with the drive unit ( 13 ) is connected and that the longitudinal axis ( 23 ) of the pump vessel ( 14 ) extends eccentrically to the longitudinal axis ( 24 ) of the drive unit ( 13 ) and, in the driven state, executes a wobbling movement which describes the lateral surface of a cone. 7. Fluid pump arrangement according to claim 6, characterized in that the deflection of the longitudinal axis ( 23 ) of the pump vessel ( 14 ) with respect to the longitudinal axis ( 24 ) of the drive unit ( 13 ) is adjustable out. 8. Fluid pump arrangement according to claim 6 and 7, characterized in that the drive shaft ( 22 ) of the drive unit ( 13 ) is articulated and detachably connected to the pump pengefäß ( 14 ) and is arranged centrally on the outlet end Eride of the pump vessel ( 14 ). 9. Fluid pump arrangement according to claim 8, characterized in that the drive shaft ( 22 ) is designed as a cardan shaft, which is connected via a universal joint ( 21 ) to the drive motor, and is attached to the pump vessel ( 14 ) by means of a releasable connection. 10. Fluid pump arrangement according to one of claims 6 to 9, characterized in that the pump pengefäß ( 14 ) is tubular. 11. Fluid pump arrangement according to one of claims 6 to 10, characterized in that the size of the pump vessel ( 14 ) is adapted to the flow rate of the fluid. 12. Fluid pump arrangement according to one of claims 6 to 11, characterized in that the least least a valve ( 2 , 19 ) is designed as a sail valve or Kugelven valve.