Cassette module

Abstract

The present invention relates to a cassette module for controlling fluid flows, in particular for use in blood treatment systems or in infusion systems, wherein the cassette module comprises at least one base body having means for the flow guidance of at least one fluid flow and at least two membranes which are at least sectionally directly or indirectly in contact with the base body, wherein at least one actuation element is arranged between the membranes by means of which the means for the flow guidance can be acted on.

Claims

1. A cassette module, wherein the cassette module comprises at least one base body having a first flow system including channels, chambers, valves, and pump sections for controlling at least one fluid flow, at least two membranes at least sectionally directly or indirectly in contact with the base body, at least one movable actuation plunger or plunger plate arranged between the two membranes, and capable of transferring force between the two membranes, by which the first flow system can be acted on, at least one first functional layer, at least one second functional layer, and a third functional layer, wherein the first functional layer has the first flow system, wherein the second functional layer is arranged between the two membranes, and wherein the third functional layer has a second flow system including the chambers and the channels for actuating one or both of the two membranes hydraulically or pneumatically, wherein the plunger has two end positions, at least one of the two end positions being formed by the second functional layer.

2. A cassette module in accordance with claim 1, characterized in that at least one of the functional layers comprises flexurally stiff material.

3. A cassette module in accordance with claim 1, characterized in that the two membranes are elastic membranes.

4. A machine, having at least one slot in which at least one cassette module in accordance with claim 1 is located.

Description

(1) Further details and advantages of the invention will be explained in more detail with reference to an embodiment shown in the drawing. There are shown:

(2) FIG. 1: a sectional view through a cassette module in accordance with the present invention;

(3) FIG. 2: a sectional view through a membrane such as can be used in the cassette module in accordance with the invention; and

(4) FIG. 3: a further sectional view through a cassette module in accordance with the invention.

(5) FIG. 1 shows a longitudinal sectional view through a cassette module in accordance with the invention.

(6) The first functional layer is marked by the reference numeral 7 and the second functional layer is marked by the reference numeral 2.

(7) Reference numeral 1 marks the third functional layer.

(8) As can be seen from the Figure, the second functional layer 2 is located between the first functional layer 7 and the third functional layer 1.

(9) Furthermore, a first membrane 6 is located between the second functional layer 2 and the first functional layer 7 and a second membrane 5 is located between the third functional layer 1 and the second functional layer 2.

(10) As can furthermore be seen from the Figure, a respective one plunger or a respective one plunger plate 3 is located between the membranes 5, 6 in both chambers shown which equally serves as a valve for closing or releasing an opening 70, 70 in the first functional layer 7.

(11) As can further be seen from the Figure, means for the flow guidance of at least one liquid flow such as blood, dialyzate, an infusion solution, etc. are located in the first functional layer 7, wherein in the embodiment shown here, the means are configured in the form of a valve which allows or prevents a throughflow of the chambers 14, 14 of the cassette module.

(12) As can further be seen from the Figure, the valve block or the cassette module designed as a valve block has two such valves, wherein the valve having the opening 70 in the chamber 14 of the cassette module shown at the left being open and the valve having the opening 70 in the chamber 14 of the cassette module shown at the right being closed.

(13) The opening of the valve takes place in that underpressure is generated in the pneumatic chamber 12 as shown by an arrow. This has the result that the second membrane 5 and, due to the vacuum present between the membranes, also the first membrane 6 as well as also the plunger plate 3 are moved upwardly, whereby the opening 70 is released by the membrane 6. A fluid flow through the fluid chamber 14 is thereby made possible.

(14) In the chamber 12 of the cassette module shown at the left, in contrast, an excess pressure is generated, as is symbolized by the arrow shown which symbolizes the inflow of a pneumatic fluid, in particular of compressed air. The two membranes 5, 6 as well as also the plunger plate 3 shown at the right are thereby urged downwardly and the opening 70 is closed by means of the first membrane 6. The chamber 14 can thus not be flowed through by a fluid, as is indicated by the dashed arrows.

(15) As already stated above, the terms excess pressure and underpressure do not necessarily mean that an excess pressure or underpressure relative to atmospheric pressure has to be present, although such an embodiment is also covered. They can also mean values relative to one another.

(16) It is thus conceivable, for example, that an underpressure in the chamber 12 does not only mean that vacuum is applied by a pump in the chamber 12. It can also mean that a liquid is flowed into the chamber 14 by the operation of the cassette without, however, actuation taking place in the chamber 12. The membranes 5, 6 are then deflected and the chamber 12 represents the underpressure side with respect to the chamber 14 without a vacuum being actively applied in the chamber 12.

(17) It is conceivable that the pressure in the functional layer 2 is smaller than in the layers 1 and 14.

(18) The cassette module shown in the Figure is a valve block. Any desired other functionalities are generally also covered by the invention such as a pump function or the like.

(19) The functional layers 1, 2, 7 comprise a flexurally stiff plastic, i.e. a stable-shape plastic, whereas the membranes 5, 6 are designed as flexible, preferably elastic membranes so that the desired flow guidance can be set.

(20) It can further be seen from the Figure that both the first functional layer 7 and the third functional layer 1 have flared portions which form chambers 12, 14, 12, 14 which serve, on the one hand, for controlling the membranes via an actuator medium such as compressed air and, on the other hand, for controlling a fluid flow such as blood, dialyzate, infusate, etc.

(21) The cassette module shown is naturally not only suitable for controlling a liquid flow, but also, for example, to control a gas flow.

(22) The control via the chambers 12, 12 also does not necessarily have to take place using a gas or compressed air, but can rather likewise take place via a fluid, i.e. hydraulically.

(23) The valve shown or the plunger plate 3 is brought into the one or other end position by the excess pressure or underpressure in the chambers 12, 12 and closes or opens a fluid circuit or the opening 70, 70 with its side opposite the pneumatic system or hydraulic system in dependence on its instantaneous position.

(24) The end positions can, for example, be formed by surfaces or functional layers such as by the second functional layer. In the right chamber, the plate-shaped region of the plunger plate abuts the second functional layer so that an end position is thereby defined.

(25) The control circuit, for example the pneumatic circuit, and the fluid circuit, for example a circuit for conveying blood, dialyzate, etc., are reliably separated by the presence of two membranes 5, 6 so that no contamination can occur on the tearing of a membrane.

(26) The membrane 5 is preferably in direct contact with the functional layers 1 and 2 and the membrane is preferably in direct contact with the functional layers 2 and 7.

(27) It is pointed out at this point that the term membrane is to be understood widely and covers any areal and movable material which can carry out the named functions. The membranes can, for example, be configured as films.

(28) They are preferably impermeable for the fluid as well as also for the actuator medium (such as compressed air, hydraulic medium, etc.). They are furthermore largely impermeable for gas.

(29) The movement or valve function exerted by the second membrane 5 takes place faster and more precisely due to the plunger disk 3 located between the membranes 5, 7. This allows higher clock rates of the valve switching, which is desirable.

(30) A possible realization of the coupling between the pneumatic circuit and the fluid circuit comprises welding the two membranes 5, 6 to the respective sides adjacent to them. The involved housing parts, i.e. the named functional layers, also have to be connected to one another.

(31) An inexpensive and also technically simple realization of this connection comprises that at least one or both of the membranes 5, 6 shown in FIG. 1 are partially heated and thus the adjacent hard components being welded to one another. The membranes thus serve as connection means for the functional layers.

(32) The membrane can in this respect furthermore satisfy the valve function or sealing function required for the embodiment in accordance with FIG. 1.

(33) To prevent an excessive heating for the purpose of welding the membrane, the membrane has at least one layer which transmits the laser light.

(34) The wavelength of the laser can be selected such that the plastic material of the functional layers used is permeable for this light, whereas the layers 1 and 3 of the membrane shown in FIG. 2 have portions absorbing the laser light and are thus heated in the transmission.

(35) An Nd:YAG laser is preferably used within the framework of the method in accordance with the invention.

(36) Lumogen IR 788 BASF can, for example, be used as the absorber or absorbing material which absorbs in the infrared region so that the components provided therewith are largely transparent in the wavelength of visible light. The absorber is preferably admixed into the membrane material with a concentration of 100 ppm.

(37) FIG. 2 shows an exemplary structure of this membrane 5, 6 and illustrates that the membrane has two cover layers 1, 3 which are designed as absorbing the laser light and has a middle layer 2 which is disposed therebetween and which has a smaller degree of absorption for the laser light and thus is not heated or is only heated slightly more than the layers 1, 3.

(38) Due to the fact that the membrane only has thin layers 1, 3 of a laser light absorbing material at its outer sides, a high temperature is also only generated there, i.e. at contact points to the hard parts or components of the base body or functional layers to be welded, whereas the shown middle layer 2 is not heated or is only heated a little and the stability of the structure and the plastic and elastic properties of the membrane are largely maintained.

(39) A welding can take place in the interior of the total structure due to the materials of the base body, i.e. in particular functional layers, transparent for the laser light used, i.e. a welding can take place after the at least one membrane has already been inserted.

(40) FIG. 3 shows the weld points, marked by circled regions, at which the membrane is connected to at least one further component by the method in accordance with the invention. The laser beam is marked by the reference symbol L. The connection can be made to the plunger disk, to the base body or functional layer and/or to a further membrane.

(41) Both individual weld spots can be set and thin tracks, e.g. for enclosing the areas to be sealed, can be drawn by the welding by means of a laser. The heat input and thus the load on the cassette module to be welded can be kept very small by the direct introduction of the welding energy only onto the required material amounts.