DE102014201714A1 - Electric peristaltic pump with roller bearing elements - Google Patents

Abstract

The invention discloses a hose pump (20, 21) comprising an electric motor (1, 10) and a flexible hose (4, 14) for transporting a medium, wherein the hose pump is characterized by a first and a second bearing ring (3, 6, 12 , 15), wherein the bearing rings (3, 6, 12, 15) are rotatable relative to each other and at least one of the bearing rings (3, 6, 12, 15) by the electric motor (1, 10) can be driven, and between the bearing rings (3 , 6, 12, 15) roll rolling elements (7, 13), wherein the flexible tube (4, 14) between the first bearing ring and the rolling elements (4, 14) is arranged such that the rolling elements (4, 14) at a relative rotation of the bearing rings (3, 6, 12, 15) roll on the flexible hose (4, 14) and promote the medium by squeezing the hose (4, 14) on the bearing surfaces of the rolling elements (4, 14).

Description

The invention relates to a peristaltic pump for transporting a medium, in particular a fluid.

Background of the invention

Hose pumps, also called peristaltic pumps or peristaltic pumps, are previously known from the prior art. These are positive displacement pumps, in which the medium to be pumped is forced through it by external mechanical deformation of a hose. In conventional peristaltic pumps, this hose is disconnected by pressure rollers or sliding shoes, which rotate on a rotor or are moved via a camshaft. In both types of movement, the movement causes the Abklemmstelle moves along the tube, thereby driving the fluid. The intake vacuum is generated in standard hose pumps by the elasticity of the tubing. As a rule, the pressure rollers or sliding blocks are usually interconnected in a fault-prone transmission, which is not robust enough for work applications with high demands on reliable (continuous) operation, failing as a result of the defect and thus can not work sufficiently reliably. In addition, conventional peristaltic pumps often have a large diameter.

Object of the invention

Based on the aforementioned prior art, the invention is based on the object to improve the state of the art structurally: It will be further developed a peristaltic pump, which is simple, compact and robust.

Description of the invention

According to the invention this object is achieved according to claim 1. Advantageous embodiments can be found in the dependent claims.

The hose pump according to the invention has an electric motor and a flexible hose for transporting a medium and is characterized by a first and a second bearing ring, wherein the bearing rings are rotatable against each other and at least one of the bearing rings is driven by the electric motor. According to the invention movable rolling elements are arranged between the bearing rings. The flexible hose is arranged between the first bearing ring and the rolling elements in such a way that the rolling elements roll on the flexible hose during a relative rotation of the bearing rings and drive the medium by squeezing the hose against the bearing surfaces of the rolling elements.

By the rolling movement of the rolling elements on the flexible hose thus a media promotion is effected in the hose. The peristaltic pump designed according to these features describes a simple, compact and robust arrangement for transporting a medium, in particular a liquid. In addition, rolling elements guided in a raceway system are technically manageable and calculable with respect to the rolling element lifetimes. Due to the compact design of a track system, the diameter of the pump head can be made substantially smaller, whereby the waste of space is prevented.

In a further advantageous embodiment, the peristaltic pump is designed such that the second bearing ring has recesses and the rolling elements are guided in these recesses. These recesses determine the position of the rolling elements relative to this bearing ring in the circumferential direction. It results advantageous a defined distance of the rolling elements with each other. Advantageously, it follows that in the flexible hose at exactly defined distances from each other a media wave can be promoted. The flow of the medium through the hose pump is thus not dependent on a variable position of the rolling elements, but predefined. The flow becomes calculable and predictable.

In an alternative advantageous embodiment of the hose pump, the rolling elements are guided in a cage between the bearing rings and the cage is fixed to the first bearing ring. This fixation can be performed for example as a weld or screwing. This configuration results in the same advantage that results from the aforementioned definition of the position of the rolling elements when they are guided in recesses in the bearing ring: The transport of media through the hose pump can thereby be planned (i.e., calculated and calculated).

It is possible in an even further embodiment, the cage and the bearing ring in one piece, so that one of the bearing rings has pockets, can be used in the rolling elements.

In a further advantageous embodiment of the peristaltic pump, the electric motor has a fixed housing and a rotatable rotor shaft, wherein the rotor shaft is rotatably coupled via a shaft with one of the bearing rings and this bearing ring surrounds the shaft in an annular manner. It has proved to be beneficial, especially if the inner bearing ring is designed as a rotatable bearing ring, so that the outer bearing ring, as well as the fixed housing of the electric motor are not moving parts and can be screwed from the outside to an existing connection structure or installed permanently in an existing machine.

In this case, the outer bearing ring and the housing can be designed as a structural unit, for example as a metallic casting or as Kunststoffausformteil. Such a reduction in parts enables cost savings in assembly and production.

It has further been found to be advantageous if the flexible hose of the peristaltic pump has an inner side in contact with the medium and has an opposite outer jacket and this outer jacket is arranged on the raceway of the non-rotatable bearing ring or at least applied flat at more than one point. Due to the stiction between outer jacket and raceway, the hose is fixed to this track. Slipping of the tube within the raceway can be prevented and the risk of undesirable looping of the hose within the raceway is prevented. Particularly advantageous is, for example, the fixing of the hose on the non-rotatable bearing ring by means of hose clamps which are mounted on the outer jacket of the hose such that the rolling of the rolling elements on the hose is not hindered.

In a further advantageous embodiment of the hose pump, one of the bearing rings comprises at least one through hole into which an inlet opening and an outlet opening of the flexible hose can be arranged. This through-hole is particularly useful in order to be able to lead the two hose ends out of the pump in order to integrate the hose pump into an existing media circuit.

In an advantageous use of a peristaltic pump, this is provided in a medical application for the delivery of a fluid, for example for the delivery of blood.

Brief description of the drawings

Hereinafter, embodiments of the invention will be explained in more detail with reference to the accompanying drawings. Showing:

1 an exemplary embodiment of the hose pump according to the invention with spherical rolling elements, in an axial full section in side view;

2 the exemplary embodiment of the hose pump according to the invention 1 , along the section AA;

3 the exemplary embodiment of the hose pump according to the invention 1 and 2 in an exploded view;

4 an alternative exemplary embodiment of the hose pump according to the invention in a full section in side view;

5 the exemplary embodiment of the hose pump according to the invention 4 along the section BB;

6 the exemplary embodiment of the hose pump according to the invention 4 and 5 in an exploded view.

Detailed description of the drawings

1 shows an exemplary embodiment of the hose pump according to the invention 20 with spherical rolling elements 7 , in an axial full section in side view. 2 shows this exemplary embodiment along the section AA:
An electric motor 1 is designed as a DC motor and has a housing 1b and a rotatably mounted in this housing rotor shaft 1a on. It acts as a drive source for the peristaltic pump 20 , The rotor shaft 1a is over a shaft 8th with a nut 5 screwed. By means of the nut 5 becomes a second bearing ring 6 axially on the housing 1b attached. In the second bearing ring 6 are spherical rolling elements 7 inserted so that they form fit, but under play, in recesses 9 this bearing ring 6 can run as soon as the bearing ring 6 rotates. Axially between the bearing ring 6 and the housing 1b is a first bearing ring 3 attached, the bearing rings 3 . 6 are rotatable against each other. The balls 7 are in a space between both bearing rings 3 . 6 movably mounted along a ring curve. In the space between the two bearing rings 3 . 6 is also a flexible rubber hose 4 arranged so that the balls 7 on the rubber hose 4 rest and the hose at the bearing surfaces of the balls 7 to squeeze. The rubber hose 4 has two open ends, an inlet opening 22 and an outlet opening 23 on, through which a liquid enters the hose 4 can flow in and out. Intended use of peristaltic pump 20 is the hose 4 filled with liquid. The rubber hose 4 changes its location between the camp rings 3 . 6 not if the electric motor is the bearing ring 6 drives. With relative rotation of the bearing rings 3 . 6 the balls roll against each other 7 on the rubber hose 4 so that the pinch points in the hose 4 migrate annularly according to the relative rotation. Due to this movement of the squeezing spots, the pressure in the hose is increased 4 moving liquid moves. The result is a liquid transport through the hose 4 , where the fluid flow through the hose 4 proportional to the rotational speed of the driven bearing ring 6 , The hose pump 20 is suitable, for example, for applications in the field of medical technology, in particular for continuous operation, preferably as a blood or infusion pump.

3 shows the exemplary embodiment of the hose pump according to the invention 20 out 1 and 2 in an exploded view. It is easy to see that the two bearing rings 6 . 3 Seen from the outside are formed largely rotationally symmetrical, the bearing ring 3 however, a recess 3a in which the inlet opening 22 and the outlet opening 23 of rubber hose 4 in the assembled state of the peristaltic pump 20 is inserted. All further details can be taken from the aforementioned description of the figures.

4 shows an alternative example of the hose pump according to the invention 21 with roller-shaped rolling elements 13 in an axial full section in side view. 5 shows this exemplary embodiment along the section BB:
The function of the peristaltic pump is almost analogous to the function of in 1 and 2 described peristaltic pump 20 However, in this embodiment, the bearing ring 12 designed as a rotatable inner ring and the bearing ring 15 designed as a non-rotatable outer ring. The inner ring 12 is by the electric motor 10 drivable, according to the principle of action explained in the previous figure descriptions. The rubber hose 14 lies on the inner casing of the outer bearing ring 15 and there is secured over the static friction of the rubber with the bearing ring material against slipping. Another difference is that instead of the ball bearing 7 a cylindrical roller bearing 13 is used. Because of that, cylindrical rollers 13 one opposite bullets 7 have improved load transfer, such a peristaltic pump is suitable 21 for applications in mechanically stressed working environments. Furthermore, the cylindrical rollers 13 that are inside the bearing rings 12 . 15 are arranged and on the hose 14 roll over, in a cheese 16 guided on the inner, rotatable, bearing ring 12 fixed, in particular welded, is. By this measure, the recesses 9 that in the first-mentioned peristaltic pump 20 exist, omitted, since the leadership of the rolling elements 13 is taken over by the cage. The Ka 16 moves at the angular velocity with which the rotatably mounted bearing ring 12 from the electric motor 10 is driven.

6 shows the exemplary embodiment of the hose pump according to the invention 21 out 4 and 5 in an exploded view. It is easy to see that the two bearing rings 12 . 15 are also formed largely rotationally symmetrical. The fixed outer bearing ring 15 also has through holes here 15a . 15b on, in which the inlet opening 22 and the outlet opening 23 flexible hose 14 in the assembled state of the peristaltic pump 21 are inserted.

All other details are analogous to the aforementioned figure descriptions.

LIST OF REFERENCE NUMBERS

1

 electric motor

1a

 rotor shaft

1b

 casing

2

 retaining ring

3

 bearing ring

3a

 Through Hole

4

 tube

5

 securing means

6

 bearing ring

7

 rolling elements

8th

 shaft

9

 recess

10

 electric motor

10a

 rotor shaft

10b

 casing

11

 retaining ring

12

 bearing ring

13

 rolling elements

14

 tube

15

 bearing ring

15a

 Through Hole

15b

 Through Hole

16

 Cage

17

 securing means

18

 Rifle

19

 shaft

20

 peristaltic pump

21

 peristaltic pump

22

 inlet port

23

 outlet

Claims (7)

Peristaltic pump ( 20 . 21 ) comprising: an electric motor ( 1 . 10 ) and a flexible hose ( 4 . 14 ) for transporting a medium, characterized by - a first and a second bearing ring ( 3 . 6 . 12 . 15 ), whereby the bearing rings ( 3 . 6 . 12 . 15 ) are rotatable against each other and at least one of the bearing rings ( 3 . 6 . 12 . 15 ) by the electric motor ( 1 . 10 ) is drivable, and between the bearing rings ( 3 . 6 . 12 . 15 ) movable rolling elements ( 7 . 13 ) - wherein the flexible hose ( 4 . 14 ) between the first bearing ring and the rolling elements ( 4 . 14 ) is arranged, that the rolling elements ( 4 . 14 ) during a relative rotation of the bearing rings ( 3 . 6 . 12 . 15 ) on the flexible hose ( 4 . 14 ) and the medium by squeezing the tube ( 4 . 14 ) on the bearing surfaces of the rolling elements ( 4 . 14 ). Peristaltic pump ( 20 . 21 ) according to claim 1, wherein the second bearing ring ( 6 . 12 ) Recesses ( 9 ) and the rolling elements ( 7 . 13 ) in these recesses ( 9 ), these recesses ( 9 ) the position of the rolling elements ( 7 . 13 ) against at least one bearing ring ( 3 . 6 . 12 . 15 ) in the circumferential direction. Peristaltic pump ( 20 . 21 ) according to claim 1, wherein the rolling elements ( 7 . 13 ) in a cage ( 16 ) between the bearing rings ( 3 . 6 . 12 . 15 ), whereby the cage ( 16 ) on the second bearing ring ( 6 . 12 ) is fixed. Peristaltic pump ( 20 . 21 ) according to at least one of the preceding claims, wherein the electric motor ( 1 . 10 ) a fixed housing ( 1b . 10b ) and a rotatable rotor shaft ( 1a . 10a ), wherein the rotor shaft ( 1a . 10a ) over a shaft ( 8th . 19 ) with one of the bearing rings ( 3 . 6 . 12 . 15 ) is rotatably coupled, said bearing ring ( 3 . 6 . 12 . 15 ) the shaft ( 8th . 19 ) surrounds annularly. Peristaltic pump ( 20 . 21 ) according to at least one of the preceding claims, wherein the flexible hose ( 4 . 14 ) has an inner side in contact with the medium and has an opposite outer jacket, wherein the outer jacket of this hose ( 4 . 14 ) on the raceway of the first bearing ring ( 3 . 15 ) is created. Peristaltic pump ( 20 . 21 ) according to at least one of the preceding claims, wherein one of the bearing rings ( 3 . 6 . 12 . 15 ) at least one through hole ( 3a . 15a . 15b ) into which an inlet opening ( 22 ) and an outlet opening ( 23 ) of the flexible hose ( 4 . 14 ) can be arranged. Use of a peristaltic pump ( 20 . 21 ) according to at least one of claims 1 to 6 in a medical application for delivering a fluid, for example for the delivery of blood.

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