NO762373L - - Google Patents

Description

The present invention relates to an improvement of peristaltic pumps. The advantage of such pumps is that they are widely used, particularly in medicine. The invention also relates to the use of these pumps

and the peristaltic tubes themselves.

The peristaltic pump described in Norwegian patent no. 128,846 presents a tube which is only partially pressed together by the pressure bodies and where a passage is thus maintained. In a blood circulation outside the body, this pump allows the blood to circulate, while at the same time air bubbles that may accidentally be introduced are held back. To regulate a cross-section of the passage in line with the pressure means which make it possible to extract the air, it is sufficient to adjust the resistance in the pipe, so that a greater resistance makes it possible to reduce the cross-section of the passage and vice versa.

Such a pump therefore has a wide range of applications.

But if one is to satisfy the requirement for safety in these pumps, it is necessary to fulfill two conflicting conditions. On the one hand, it is necessary to automatically limit the pump pressure and, on the other hand, to reduce the outflow as a function of the increasing amount of air that is retained. Usually one uses a peristaltic tube with given properties (especially those relating to the thickness and strength of the elastic material) and a speed of the pump which is determined as a function of the permissible amount of hemolysis.

If the pressure losses in the circuit become greater than assumed, the maximum transport pressure in the pump can only be increased under certain conditions. To achieve this, one must increase the tension in the peristaltic tube, which reduces the cross-section of the passage at the level of the pressure bodies. The return of air in counterflow at the level of the pressure body is thus slowed down,

which entails a risk of forcing entrainment of air bubbles in the blood that is returned to the patient.

This risk is all the greater as the pressure losses in the circuit outside the body during compression of the pump have become much higher, which makes it necessary to maintain a very high tension on the peristaltic tube.

On the other hand, an improvement in ability will

to retain air could be achieved by reducing either the speed of the pump or the tension on the peristaltic tube. In these two cases, the transport pressure in the pump will be lower, which can lead to it being reduced to values that are below what is desired.

It can thus be stated that pumps according to previous techniques, both in manufacture and in use,

must try to achieve a compromise between these two conflicting conditions in order to obtain a satisfactory level of safety.

The purpose of the present invention is to produce one peristaltic pump, so that the disadvantages that have previously been found and which in particular do not require such a compromise.

The invention also relates to a peristaltic pump which can transport a liquid and retain a gas, regardless of the axial pressure acting on the tube, the load exerted on it by the rollers or pins and/or the drive speed of the rollers or by the load exerted by the stator on the tube.

The purpose of the invention is to improve the safety of a blood circuit outside the body, which uses peristaltic pumps but which is without special detectors for bubbles, which is common with the circuits used e.g. in artificial kidneys.

It has been discovered, and this is the purpose of the present invention, a peristaltic pump equipped with at least one peristaltic tube, characterized in that said tube is equipped with devices that limit the tube's closure regardless of physical and/or mechanical loads to which it is subjected.

The peristaltic pumps according to the invention

can be such where the devices which are connected to the peristaltic tube and which limit the tube's closure, are placed on the inner surface of the tube or on the outer surface of the wall of the peristaltic tube.

The peristaltic tube can thus e.g. be equipped with at least one longitudinal channel or longitudinal rib on its inner wall. It can also e.g. on the outer surface of the wall be equipped with at least one longitudinal rib or at least one longitudinal, projecting edge.

By "inner surface" in the wall of the peristaltic tube is meant the surface which in the interior limits the wall and which is in contact with the liquid which is driven by the peristaltic pump.

By "external surface" in the wall of the peristaltic tube, one understands in the following a real and/or fictitious surface which on the outside limits a wall of constant thickness and likewise in the case of minimal thickness of the wall in the said tube and this outer real and /or fictitious surface is not in contact with the fluid driven from the pump. In the following drawings, a fictitious outer surface is shown with dashed lines.

By "closing", the total closing is understood

a pipe. The pump according to the invention is equipped with devices that limit the closing of a peristaltic tube, i.e. devices that limit the closing of the tube, when it is exposed to pressure means, which can be the longitudinal pressure in the pipe and/or the pressure exerted on it by the pressure means like for example. rolls or taps or also the pressure exerted by the stator in the tube.

For this reason, there is again a passage at the height of the pressure devices and this passage makes it possible to return the air in a counter flow.

Since the pump according to the present invention is never closed, no matter what physical and/or mechanical stresses the peristaltic tubes are subjected to. The minimum cross-section in the passage is determined partly to make it possible to lead it back, but also to prevent backflow of the liquid when the pump is not working. The ratio between the vertical cross-section in the passage and the vertical cross-section in the line itself in the peristaltic tube at rest is usually between 1 and 1 and preferably between 1 and lo.000 20 " 1 . This ratio is determined, for example, experimentally, taking into account the different conditions present and especially to the speed of the liquid to be pumped.Furthermore, the ratio must be increased as the viscosity of the liquid becomes higher.

The present invention is more easily understood with the help of the attached drawings, which illustrate different designs of peristaltic tubes for peristaltic pumps according to the invention. The various designs are given as examples and are not limiting and they are reproduced without a specific scale. Fig. 1 is a cross-section of a first embodiment of a peristaltic tube at rest. Fig. 2 is a cross-section of a pipe according to fig. 1 which is pressed against a roller. Fig. 3 is a cross-section of another embodiment of a peristaltic tube at rest. Fig. 4 is a cross-section of a pipe according to fig. 3, which is pressed together against a roll. Fig. 5 is a cross-section of a third embodiment of a peristaltic tube which is pressed together against a roller. Fig. 6 is a cross-section of a fourth embodiment of a peristaltic tube which is pressed together against a roller. Fig. 7 is a cross-section of a fifth embodiment for a peristaltic tube which is pressed together against a roller. Fig. 8 is a longitudinal section along A of a peristaltic tube according to fig. 2. Fig. 9 is a cross-section of a sixth embodiment of a peristaltic tube at rest. Fig. 10 is a cross-section of a pipe according to fig. 9 pressed together against a roll. Fig. 11 is a cross-section of a seventh embodiment of a peristaltic tube at rest. Fig. 12 is a cross-section of a pipe according to fig. 11 pressed together against a roll. Fig. 13 is a cross-section of an eighth embodiment of a peristaltic tube at rest. Fig. 14 is a cross-section of a pipe according to fig. 13 pressed together against a roll, where two parts of the pipe in relation to the roll are shown in fig. 14A, 14B. Fig. 15 is a cross-section of a ninth embodiment of a peristaltic tube at rest. Fig. 16 is a cross-section of the tube according to fig. 15 pressed together against a roll, where two positions of the tube in relation to the roll are shown in fig. 16A and 16B. Fig. 17 is a cross-section of a tenth embodiment of a peristaltic tube at rest. Fig. 18 is a cross-section of a pipe according to Fig. 17 pressed together against a roll, where three positions of the pipe in relation to the roll are shown in Fig. 18A, 18B and 18C. Fig. 19 is a cross-section of an eleventh embodiment of a peristaltic tube at rest. Fig. 20 is a cross-section of the tube according to Fig. 19, pressed together against a roll. Fig. 21 is a cross-section of a twelfth embodiment of a peristaltic tube at rest. Fig. 22 is a cross-section of the tube according to fig. 21 pressed together against a roll.

The different designs of peristaltic tubes for peristaltic pumps according to the present invention and described in the following, can be made in different materials which are both soft and elastic, opaque or not. For peristaltic pumps used in medicine, the peristaltic tubes can optionally be equipped on their inner surfaces and optionally on their outer surfaces with a coating of a material that is adapted to the biological fluids that are to flow through them. They may in particular be coated with a thin coating of silicone elastomer, in particular by a method described in French patent no. 2,126,573.

To produce peristaltic tubes, natural rubber or synthetic rubber, poyyr vinyl chloride, polyurethane are used and it is always preferred to use silicone elastomers which are at the same time soft. and elastic, impervious to liquids and

biologically compatible.

The peristaltic pumps according to the invention which are equipped with peristaltic tubes, where the devices which limit their closure are placed on the inner surface of the tube wall are described first. Figures 1 to 8 illustrate more precisely different designs of such peristaltic tubes.

In fig. 1 shows a peristaltic tube 1, in elastic material, e.g. a silicone elastomer, which in its rest position describes a cylindrical wire 2, with e.g. a circular cross-section. The outer profile in the pipe cross-section 1

may also be largely circular in the resting position, but this is not critical. According to the invention, a longitudinal channel 3, with a largely constant cross-section, e.g. in a semicircular shape placed in the inner surface 49, and placed in the wall material 20, in the peristaltic tube 1 so that it is connected to the line 2.

Periodically, one of the .pins or rollers 4

in the pump gradually compress the peristaltic tube, which in cross-section eventually takes the shape shown in fig. 2.

The tubes are elastic and will then tend to return to the shape it had in its resting position.

In peristaltic pumps of known type and likewise in pumps according to the invention, the cross-section of the line 2 will usually have a shape like a manual, with bulges at the ends and more compressed in the middle, as long as the compression of the tube is partial, but in known pumps the cross-section will for passage in the line 2 is reduced to the openings 5 and 6f when the pressure on the pipe against the rollers reaches its maximum value. The cross-section of this residual opening is usually very small and in practice equal to zero, but it varies greatly with the load on the peristaltic tube and an increase in this load can close the pump.

In contrast, with a pump according to the invention, the channel 3 remains open regardless of the degree of load on the peristaltic tube, i.e. regardless of what the longitudinal pressure on the tube is and/or the pressure of the roller or the stator on the tube. Consequently, the pump according to the invention is never closed regardless of the physical and/or mechanical loads for which the peristaltic tube is designed.

The effect of the pump according to the invention is clear from fig. 8. Only the upper parts of the pump corresponding to a piece of pipe between the suction and compression opening in the pipe are shown, and the peristaltic pipe is shaped like an inverted U. The roller 4 moves both in the direction of the arrow F as it moves around the pump's axis of rotation and it also turns around itself so to speak without: friction in contact with the peristaltic tube.

The liquid is therefore displaced from the inlet 7 towards the outlet opening 8 in the peristaltic tube. There, air that has been present in the liquid will remain in the zone 9 in the upper part of the pump inside the peristaltic tube. Air bubbles that are drawn towards the outlet opening can rise from zone 9 through channel 3.

It is therefore possible to retain air trapped in the peristaltic pump, regardless of the applied pressure, the load exerted by the pins or the rollers on

the peristaltic tube or the speed at which these move. One can therefore regulate the compression pressure and volume for the pump to all desired values with complete safety.

The shape of the channel's cross-section is critical. The width and depth of the channel are usually chosen so that the depth is between the third and five times the depth. Preferably, the width of the channel is between one and three times the depth of the channel. The walls of the channel are usually cut into the inner surface 49, in the wall 20 of the conduit 2, of the peristaltic tube so that the angle alpha is between 45 and 90°, (fig. 1).

Furthermore, it is important that the channel is in connection with the line 2, in the peristaltic tube, in a width that is more than half of the maximum width of the channel.

Furthermore, it is an advantage for manufacturing reasons that the channel extends the entire length of the peristaltic tube, but in certain cases it can only extend over the part of the peristaltic tube that is affected by the pins or rollers.

In order to obtain a sufficiently large passage, it may be advantageous in certain cases to divide channel 3 into several equal channels. One can e.g. place up to five longitudinal, largely parallel channels, without this number being limiting. These channels are preferably cut out in the part of the wall of the peristaltic tube which is not in contact with the pins or rollers. The profiles of the pins or rollers are usually not critical and mechanical elements of a known type can be used.

Fig. 3 shows another method for producing a peristaltic tube. This peristaltic tube is equipped with two parallel channels 9 and 10 which are similar to each other, and which correspond to the preceding channel 3. They are placed diametrically opposite each other and the peristaltic tube is preferably pressed together along these two channels as shown in fig. 4. The wall in the peristaltic tube is made thinner at the level where the compression takes place, which leads to less resistance, less wear and longer life. If this is desired, the pipe can also be pressed together in such a way that the two channels come directly opposite each other.

You can of course combine the devices

which is shown in fig. 2 and 4 with three channels or more. A third method for producing a peristaltic tube is shown in fig. 5. This peristaltic tube 1 is not equipped with a longitudinal channel, but with a longitudinal rib 11.

This rib 11, when it comes into contact with the inner surface 49, on the opposite side of the peristaltic tube, will create on each side of it two passages 12, and 13, which correspond to the passages created by the channel 3, in the peristaltic tube shown in fig. 1 and 2.

A fourth method for producing a peristaltic tube for pumps according to the invention is shown in fig.6; At least one staff such as can be flexible and as e.g. can

having a circular cross-section 14, is placed inside the peristaltic tube. It preferably consists of the same material as the pipe and is attached to it at at least one point at the inlet end and preferably at both ends in a manner known per se, e.g. by thermowelding.

In cases where it is a peristaltic tube that is subjected to tension, the rod is preferably somewhat longer than the tube between the connection points so that the cross-section is not reduced when the tube is stretched.

In the embodiment mentioned above, the rod creates two longitudinal passages 12 and 13 which correspond to the passage created by the channel 3. This embodiment makes it possible to use standard pipes.

A variant of this design consists in introducing into the peristaltic tube in part of its length a rigid or semi-rigid rod in the form of a circular arc, usually a semi-circle, whose diameter makes it possible for it to enclosed by the pressure means in the peristaltic pump of rotary type to be used. The special shape of the rod enables it to be held in place by the peristaltic pump, without the need to attach it to the peristaltic tube.

In some peristaltic pumps, it can be

an advantage to keep the tube inside a fixed housing, which usually

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is called a stator. For this purpose, the peristaltic tube is equipped on the outside with a control chamber 15, which fits into a corresponding cutout in the stator. According to the invention and as shown in fig. 7, you can use a pipe such as e.g. consists of an elastomer plate, where the two longitudinal edges are folded edge to edge and sealed. 16. The opposite, rounded edges 17 and 18 limit in the inner surface 49 of the tube 1 a channel with a triangular cross-section which creates a longitudinal passage 19 when the peristaltic tube is pressed together.

The peristaltic pumps according to the invention are equipped with peristaltic tubes with devices that limit their closure, which are placed on the outer surface of the wall of the peristaltic tube described in the following. Figures 9 to 20 specifically illustrate different designs of such peristaltic tubes.

The peristaltic tube 1, according to an embodiment shown in rest position in fig. 9, restricts a wire 2 having a largely circular cross-section. The tube has a wall 20

with largely constant thickness, and the outer profile of cross-

the section of the pipe 1 at rest is likewise largely circular.

The peristaltic tube 1, according to the

The present invention has, on its outer surface 21, a longitudinal rib 22, along one of the tube's generatrices with a large, constant cross-section, such as e.g. can be semicircular.

Periodically, one of the pins will rush the rollers 4

in the peristaltic pump gradually compress the peristaltic tube 1, which takes a shape shown in fig. 10. The pipe, which is made of elastic material, will afterwards take back the shape it had in its resting position.

The longitudinal rib 22, during the compression of the peristaltic tube 5, will lead to a raising of the wall 20 in the tube 1 on each side of the rib 22, which prevents the tube from closing by creating two passages 23

and 24 in the form of a coil.

It is an advantage that these peristaltic tubes

according to this sixth method of producing them^ are oriented when placed around the pressure means of the peristaltic pump, i.e. it is an advantage that the rib 22 is in contact with the pins or rollers as shown in fig. 10.

Peristaltic tubes can be produced which have

more ribs. The seventh method for performing these is shown in fig. 11 and 12. The peristaltic tube according to the present invention which is shown in cross-section and in rest position in fig. 11 and compressed in fig. 12, corresponds to the peristaltic tube described above. Djt has six ribs on the outer surface, such as 25 and 26, with a semi-circular cross-section and equidistant from each other. It is not necessary to orient such a peristaltic tube when it is placed in contact with the pressure means. When the pins or rollers 4 in the peristaltic pump are rotated to form peristaltic tubes, at least two ribs 25 and 26 will be in contact with the roller 4, and between the ribs a deflection of the wall 20 is created which creates a passage 27 which prevents closure of the peristaltic tube.

The cross-section of the ribs placed on the outer surface, in two embodiments of the peristaltic tubes, need not be semi-circular. The ribs or ribs may have a cross-section such as a trapezoid, a triangle, or the cross-section may be square or rectangular. One can also have ribs with different cross-sections on the outer surface of the compressed peristaltic tube.

The number of ribs is not critical, but a high number tends to reduce the softness of the tube. It seems that five longitudinal ribs which are generally parallel are suitable, without being limited to this number.

It is not necessary that the ribs are equidistant from each other on the outer surface of the peristaltic tube. However, it is an advantage that part of the outer surface of the peristaltic tube which comes into contact with the pressure means has at least one rib.

The peristaltic tube, according to an eighth method for carrying this out, consists of at least one longitudinally projecting comb, which generally runs along the generatrix of the tube. The tube shown in Figures 13 and 14 A and B has two longitudinally projecting edges 28 and 29 e.g. placed diametrically opposite each other. Figures 14A and 14B show example two. relatively different positions of the roller/peristaltic tube. According to fig. 14A, the protruding edges, due to their width 30, and their thickness which is greater than the thickness of the wall 20, in the tube 1, will cause them to resist the closing of the tube when it is pressed together by the rollers 4 and form two passages 31 and 41 . According to fig. 14B, the projecting edge 28 plays a similar role as the rib 22 in the tube according to fig. 9.

The peristaltic tube 1 according to a ninth embodiment is shown in fig. 15 and 16A and B and the tube has a cross section and an outer profile which is ellipsoidal. Along the major axis of the ellipse, the walls 32 and 33 have a thickness that is greater than the thickness in the peristaltic tube otherwise and which act as longitudinally projecting edges with a half-moon-shaped cross-section on the outer, surface 21 of the peristaltic tube 1.

The large thickness in the wall at 32 and 33 will prevent the tube from closing when it is pressed together by the roller 4 and two passages 34 and 42 will be formed as shown in fig. 16A. Also at the location shown in fig. 16B, two passages are formed.

The peristaltic tube 1 after a tenth embodiment is shown in fig. 17 and 18 A, B and C consist of a

ning 2 which is largely cylindrical and which has a cross-

cut with an outer profile that is also circular. The cylindrical surfaces that limit the wall of the tube are not coaxial and the wall of the tube therefore does not have a constant thickness, but is equipped with a thicker zone 35 and a thinner zone 36.

The device that prevents compression

of such a peristaltic tube, consists of a protruding edge with a cross-section like a crescent between the outer surface 21, of the tube (this surface is practically fictitious here) and a cylindrical, non-coaxial surface which limits the outer surface of the tube. The thick zone 35 in the wall 20 prevents the tube from being pressed together when it is subjected to pressure by the roller 4. During the passes of the roller and the tube shown in fig. 18A and C, two passages 37 and 43 are formed.

According to the position shown in fig. 18B is formed where a passage 44.

The peristaltic tube according to the eleventh method of its execution is shown in fig. 19 and 20 which show a conduit 20 which is cylindrical and a wall 20 which in cross-

section has a profile that is polygonal and that is mostly square. The outer surface 21 is also in this embodiment actually fictitious and the projecting edges have a cross-section in the form of a curved triangle. The wall 20 in the tube 1 is not of constant size, being thicker at the edges of the prism as shown at 38. These zones of greater thickness prevent the tube from closing when it is subjected to compression by the rollers 4 and two passages 39 and 40 are formed.

The peristaltic tube can have three longitudinally protruding edges in the form of a curved triangle, where the tube in cross-section will have a profile that is largely triangular.

The peristaltic tube 1, according to the twelfth embodiment, is shown in fig. 21 and 22 and consists of a wire 2 with an elliptical cross-section and a wall 20, which in section has a profile that is mostly elliptical and where the wall 20 has a greater thickness along the minor axis than along the major axis" in the ellipse. The wall in the peristaltic tube thus does not have a uniform thickness and the zones of greater thickness 45 and 46 correspond to protruding edges placed in the outer surface 21, which in this case is largely fictitious. The pipe 1, pressed together by the rollers 4, does not close and two openings 47 and 48 are formed.

In order to facilitate production, the devices which limit the closure of the peristaltic tube and which are placed on the outer surface thereof, preferably extend along the entire length of the peristaltic tube and the peristaltic tube can thus be provided by extrusion.

In certain cases, these devices may only extend over the part of the peristaltic tube that is affected by the pins or rollers.

The peristaltic pumps according to the invention which are equipped with peristaltic tubes where the devices that limit the closure of the tubes are placed on the outer surface of the wall of the peristaltic tube, as described above, have an inner surface which is cylindrical with a directrix in the form of a closed curve without inflection point, e.g. in most cases circular. It is therefore easy to connect such a pump to liquid lines by means of connecting pieces with an outer surface that is cylindrical with a directrix in the form of a closed curve, without an inflection point, e.g. in most cases circular. One can also easily use connecting pieces which on their outer surface have one or more collars which are placed vertically on the axis of the connecting piece.

Without going outside the scope of the invention, one can combine two or more of the embodiments described above, which are only given as examples and which are not limiting.

The pump according to the invention has several advantages. On the one hand, it has greater functional reliability compared to known pump types. It retains air contained in a liquid, no matter what the pressure in the pipe may be, what load is exerted by the rollers or what speed the rollers are moving. It therefore makes it possible to avoid using a detector device for air bubbles with complete safety. The capacity of the pump is gradually reduced as a function of the volume of air retained and periodic cleaning is required if this is necessary.

On the other hand, the application is greatly simplified, since the pressure in the pipe, the load on the rollers and/or the drive speed can be regulated without dealing with the retained air.

Furthermore, in certain designs that have been seen, a local thinning of the tube wall will make it possible to limit the loads and therefore increase the lifetime and safety of the pump and in other designs it has the advantage of allowing a sufficient tightness between the ends of the peristaltic tube and the cylindrical connecting pieces, without making it necessary to use sealants.

The production of the pump according to the invention

is very simple, as it largely limits itself to the production of a suitable peristaltic tube. Therefore, the tubes according to the invention, and this is a very big advantage, can be equipped with mechanical devices for peristaltic pumps of a known type. They can e.g. use pumps with pins or rollers, rotating or non-rotating that act by compression or by tension, equipped with one or more tubes in parallel, devices to control the tube, etc., where the tubes are usually in the shape of an inverted U.

The pump according to the invention is used for several different purposes. Within medicine, it can be advantageously used for circulation of blood outside the body, especially with artificial kidneys or heart-lung machines.

Claims (20)

1. Peristaltic pump equipped with at least one peristaltic tube, characterized in that said tube is equipped with devices that limit the tube's closure, regardless of physical and/or mechanical loads to which the tube is subjected. 2. Pump according to claim 1, characterized in that the peristaltic tube on its inner surface in the wall is equipped with at least one longitudinal collar. 3. Pump according to claim 1, characterized in that the peristaltic tube on the inner surface of the tube wall is equipped with at least one longitudinal rib. 4. Pump according to claim 1, characterized in that a rod extends longitudinally inside the peristaltic tube, at least in the part of the tube which is exposed to the influence of pressure means. 5. Pump according to claim 4, characterized in that the rod is rigid or semi-rigid and that it has the shape of a circular arc. 6. Pump according to claim 4, characterized in that the rod is flexible and is attached to the peristaltic tube at least at one point upstream in relation to the pressure means. 7. Pump according to claim 1, characterized in that the peristaltic tube consists of a plate of elastomer material, where the two longitudinal edges are folded edge to edge and sealed to thereby form an outer guide cam. 8. Pump according to claim 2, characterized in that it has at least two identical parallel channels and where these channels are placed diametrically opposite each other and in that the wall of the pipe is reduced along the channels. 9. Pump according to claim 1, characterized in that the said devices are placed on the outer real and/or fictitious surface of the wall of the said pipe. 10. Pump according to claim 9, characterized in that the said devices consist of at least one longitudinal rib, placed on the outer surface of the wall of the said pipe. 11. Pump according to claim 9, characterized in that the said devices consist at least of a longitudinally projecting edge placed on the outer surface of the wall of the said pipe. 12. Pump according to claim 11, characterized in that the said devices consist of longitudinal, projecting edges with a cross-section in the form of a crescent and where the peristaltic tube has a cross-section and an outer profile that is ellipsoidal. 13. Pump according to claim 11, characterized in that the said devices consist of a longitudinally projecting edge with a cross-section in the form of a crescent which lies between the outer surface of the pipe and a cylindrical non-coaxial surface. 14. Pump according to claim 3, characterized in that the said devices consist of at least three longitudinally projecting edges with a cross-section in the form of a curved triangle and where the pipe has a cross-section with an outer profile that is polygonal. 15. Peristaltic pump according to any one of claims 1-14, characterized in that it is used to circulate blood outside the body. 16. Peristaltic tube, characterized in that it is equipped with devices which mean that when said tube is compressed transversely, at least one passage remains where the ratio between the vertical cross-section in the passage and the vertical cross-section of the tube in rest position lies between y-Q — and io"^ooo * 17. Peristaltic tube according to claim 16, characterized in that the devices are placed on the inner surface of said tube. 18. Peristaltic tube according to claim 16, characterized in that the devices are placed on the outer real and/or fictitious surface of said tube. 19. Peristaltic tube according to any one of claims 16 to 18, characterized in that it is made of a silicone elastomer. 20. Peristaltic tube according to any one of claims 16 to 19, characterized in that it is coated on the inner and/or the outer surface with a thin coating of silicone elastomer.