DE6801138U - DIALYZER - Google Patents

Description

Dialyzer

The subject of the innovation is a dialyzer that can be used preferably as an artificial kidney and beyond also for other methods of separating the colloidal and the molecularly disperse components of solutions by means of membranes suitable is.

Today's medicine calls for devices for blood washing that are easy to transport, easy to handle, hygienically clean and inexpensive to manufacture. Such non-stationary Devices can be made available to a wide variety of patients who depend on an artificial kidney, if they can connect to the artificial kidney itself and so from a regular visit to a hospital are exempt. A suitable dialyzer must without additional auxiliary equipment, such as one

Blood pump, get by, have a low blood volume and be economical in the consumption of washing liquid, d. H. to use their effectiveness as far as possible and thus the efficiency of the dialyzer.

The dialyzers previously used in medicine have the main disadvantage that the resistance to the through the dialyzer The blood flowing through it is large and, if a blood pump is not used, the arterial blood pressure is only slow Can cause blood flow through the dialyzer. As a result of angled feeders and cross-sectional narrowing Branches on the way of the blood through the dialyzer form unwanted blood vortices, which coagulate the Favor blood. For these reasons, an excessive amount of anticoagulant drugs must be added to the blood which can have serious consequences with regard to possible injuries to the person concerned.

The innovation is therefore based on the task of a dialyzer to create that is easy to manufacture from as few parts as possible, easy and safe to use and before in particular has such a guide for the blood that a largely laminar blood flow is achieved.

According to the innovation, a dialyzer solves this task in an extremely advantageous manner by means of a stack of congruent ones Plates, intervening membranes and end plates consists, with separate, pairwise opposite one another Cavities formed by recesses in the plates and the membranes and closed by the end plates are, and crossing channel groups separated by one of the membranes, which are marked by grooves on the Upper and lower sides of the plates formed s ^ id and respectively Opposite cavities connect directly into these.

A cube or parallelepiped shape of the stack, the four cavities of which have an elongated, narrow cross section, is particularly advantageous are arranged parallel to its side walls.

A major advantage results from a Gleichgerichi
\ tete arrangement of the grooves on the top and bottom of each

of the plates of the stack.

A particular advantage lies in the sealing surfaces of these plates, the grooves and grooves between them belonging to a channel group which are arranged by these unconnected cavities.

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Another advantage is characterized by connecting pieces of the end plates, which lead directly into the cavities are.

The membranes are advantageously made from a cellulose film.

Grooves on the plates with parallel grooves are particularly advantageous a tip distance of about 0.3 mm and a depth of about 0.1 mm.

The new dialyzer can just as advantageously be used as an oxygenator if the membranes are made of a silicone rubber that is permeable _{to Op and CO 2.}

Another advantage is characterized in that the stack has a rectangular plan and the rectangular plates have grooves offset by 90 relative to one another on their top and bottom.

The very simple structure of the new dialyzer enables inexpensive series production that allows it to be used once Use to destroy the device. Herein lies an essential he advantage for easy handling, since the device can be sterilized during manufacture so that Infections are avoided during use. As a material for

the remaining parts of the new analyzer are preferred Plastics are used, such as elastomers or similar physiologically harmless substances.

The innovation is explained in more detail below with reference to the drawing of preferred exemplary embodiments. It shows:

Figure 1 shows a dialyzer according to the innovation in perspective Opinion,

FIG. 2 shows the essential part of the new analyzer in exploded form Depiction,

FIG. 3 a diagonal section through the dialyzer,

FIG. 4 shows a section of the inside of the stack of the new one Dialyzer in an enlarged view,

FIG. 5 shows a detail of two adjacent plates of the dialyzer in an enlarged view,

FIG. 6 a further embodiment of the new dialyzer in an exploded view.

One recognizes in detail in Figure 1 a stack 1, which is preferably has a square plan and therefore has a cube shape. As can be seen from Figure 2, there is a stack from congruent, stacked plates 2, between which membranes 3 are arranged with the same outline.

The stack 1 is closed on the top and bottom by end plates 4. Holes 13 in the plates 2, the membranes and the end plates 4, which are congruent one above the other in the stack 1, are used either to carry out screws that hold the stack 1 together or they are used to bind the individual parts, for example with a hardening plastic adhesive or the like poured out. The plates 2 and the membranes 3 also have recesses 6 which also lie congruently one above the other in the stack 1 and form cavities 5. These cavities 5 are through the front the end plates 4 completed. The recesses 6 and thus the cavities 5 have an elongated narrow cross section and are arranged parallel to the outer walls of the stack 1. With regard to those moving through the cavities 5 Dialysis fluids, the cavities 5 and the recesses 6 can also have a wedge-shaped shape or some other flow-favorable shape Own shape. On the end plates 4 connecting pieces 11 and 12 are arranged, which directly into the cavities 5 lead.

The plates 2 preferably have parallel grooves 7 on their upper and lower sides, each of which connects two opposing recesses 6 to one another. The recesses 6, which run parallel to the grooves 7 and are rightly connected to them, are delimited from one another by a sealing surface .0,

which is expediently part of the entire supporting surface 4 on the upper or lower side of a plate 2. Preferably the grooves 7 are directed in the same direction on both sides of a plate 2.

For the construction of a dialyzer according to FIG. 2, only one type of plate 2 is required. These plates 2 are stacked on top of one another in such a way that the grooves 7 of two adjacent plates separated from one another by a membrane 3 2 cross one another and thus connect two different cave spaces 5 that are assigned to one another in pairs. As FIG. 4 shows in detail, the grooves 7 form a plate 2, unless they are arranged in the same direction, each a channel group 8 on the top and bottom, while the adjacent plate 2, offset by 90 °, has two further channel groups 9, which preferably run at right angles to the channel groups 8. The profile of the grooves 7 can be semi-circular or joval also be polygonal, but it is expedient that it opens wide towards the membrane 3. Connect channel groups 8 and 9 two opposing cavities 5> into which they open directly, so that the two dialysis fluids follow the path indicated by arrows A and B in FIG take the dialyzer. For example, blood is under arterial pressure through the lower connector 11 into the front Introduced cavity 5, flows through the channel groups 8 in the

rear cavity 5, from where it leaves the analyzer via the upper connecting piece 11. At the same time, for example, under the pressure caused by gravity, the washing liquid enters the left cavity of the stack 1 through the upper connection nozzle 12, crosses this through the channel groups 9 to the right cavity 5 and leaves it through the lower nozzle 12 "

In this way, the two dialysis fluids move cross-flow to one another. Almost the entire surface of the membranes 3 is available for the dialysis process. These are held between the contact points 14, which are formed between the crests of intersecting grooves 7 of two adjacent plates 2. The membranes 3 act as ultrafilter j ie they seal the plates 2 from one another so that the dialysis fluids cannot be mixed, but a molecular metabolism can take place between the two fluids according to the laws of osmosis and diffusion. Above all, the seal towards the cavities 5 is important for those channel groups 8 or 9 _a which are not connected to the cavities 5. This is explained using the detail shown in FIG. For example, the channel groups 8 are assigned the bloodstream and the channel groups are assigned the path of the washing liquid. The channel groups 8 lead with their open end faces directly into the blood-filled

filled cavity 5. The channel closest to this cavity the channel group 9 carrying the washing liquid must therefore be closed off from the blood-filled cavity, so that an unnecessary Blood loss into the washing liquid is avoided. This is done through the membranes 3> the stiffness, which is present in these small dimensions, prevents the blood from moving under it in the direction of the channel groups 9 pushes through. Preferably between that channel of the channel group 9 is that of the adjacent cavity 5 is next and is not connected to this, a sealing surface 10 is arranged, which is designed so that the membranes 3 adheres to it as a result of molecular forces. In the opposite case, it is of course also parallel to the channels In group 8, on the edge, an identical sealing surface, which forms the channel of the blood-carrying channel group 8 that is located at the extreme from the cavity 5 containing the washing liquid. Also crucial for a perfect seal are the geometrical dimensions of the grooves 7 »whose tip spacing is approximately 0.3 mm and their preferred depth is about 0.1 mm. In addition, for example, the blood due to the lower flow resistance of the channels Channel groups 8 preferably enters this before it has to squeeze under the membrane. The same goes for entry the washing liquid in the channel groups 9.

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In order to keep the flow resistance for the blood as low as possible, the plates 2, the membranes 3 and the end plates k are advantageously given a rectangular plan, so that the stack 1 has a cuboid shape. This is shown in FIG. In this embodiment, two types of plates 2 must be provided, one in which the grooves ' ( connect the longer recesses 6, and on the other hand those in which the grooves 7 connect the shorter recesses 6 if the grooves 7 on the upper - and underside of these plates 2. If the grooves 7 on the upper and lower side of the plates 2 are offset from one another by 90 °, then in this embodiment, too, one can make do with a design for the plates 2. In this simple way the effective cross-section for the passage of the blood increases and at the same time the path of the washing liquid is lengthened, so that this is used even more extensively than is already the case with the advantageous cross-flow process.

For blood dialysis it is advantageous to produce the membranes 3 from a cellulose film. To the same dialyzer To use as an oxygenator, it is advantageous to use silicone rubber instead of cell glass, which is for oxygen molecules and carbon dioxide is permeable. The special advantage of the

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Dialyzer is mainly because the dialysis fluids on a short way via the connecting pieces 11 and 12 directly into the cavities 5 opening from there directly into the corresponding ones Enter channel groups, stand there in mutual exchange and just as quickly back to the outlet side Entering cavity 5 leave it immediately through a connecting piece 11 or 12, respectively. Both quiet areas like turbulent sections on the flow path of the fluids are avoided and by special flow favorable Valuation of the cavities 5 can be the ideal state of a laminar Flow of the blood can be achieved as quickly as possible.

An essential advantage for the production is that the stack 1 of the dialyzer is made up of already prefabricated Parts can be assembled, which consist of plates 2 and 3 membranes in the composite. Particularly useful the plates 2 are coated with membranes 3 in such a way that the blood vessels, d. H. the corresponding grooves 7, aseptically to be covered. These prefabricated parts, like the individually stacked plates 2 and membranes 3 in selectable number can be combined, whereby the volume of the Dialyzer can be adapted to the respective requirements.

Claims (10)

1.) Dialyzer, characterized by a stack (1) consisting of congruent plates (2) lying in between Diaphragms (3) and end plates (4) are made with mutually separate, opposing pairs Cavities (5) »formed by recesses (6) in the plates (2) and the membranes (3) and by the end plates (4) are closed, and intersecting channel groups separated by one of the membranes (3) (8) and (9), which are formed by grooves (7) on the upper and lower sides of the plates (2) and respectively Opposite cavities (5) open directly into these connecting them. 2.) Dialyzer according to claim 1, characterized by a cube or parallelepiped shape of the stack (1), whose four cavities (5) are arranged parallel to its side walls of elongated, narrow cross-section. 3.) Dialyzer according to claim 1, characterized by a rectified arrangement of the "^ .efen (7) on the upper and underside of the plate (2) Bank details 1 Deutsche Bank A.-G., GOIersloh / Westf. Account 334/6! 'PcWaiecMiento ifcrtmuft) NU 4.) Dialyzer according to claim 1, characterized by sealing surfaces (10) of the plate (2) between the one Channel group (8) or. (9) associated grooves (7) and the cavities (5) not connected by them 5 ·) Dialyzer according to claim 1, characterized by connecting pieces (11, 12) of the end plates (4), which are immediately are guided into the cavities (5). 6.) Dialysacor according to claim 1, characterized in that the membranes (3) are made of a cellulose film. 7 ·) Dialyzer according to one or more of the preceding claims, characterized by parallel grooves (7) of the plates (2) with a tip distance of about 0.3 now and a depth of about 0.1 mm. 8.) Dialyzer according to claim 1, characterized in that the membranes (3) of a permeable for Op and COp There are silicone rubber, which is suitable as an oxygenator. 9.) Dialyzer according to claim 1, characterized in that the stack (1) has a rectangular plan and the rectangular plates (2) have grooves (7) offset from one another by 90 ° on their top and bottom. 10.) Dlalysator according to the preceding claims, characterized in that the stack (1) from prefabricated Parts, each consisting of a plate (2) with an adhesive membrane (3), composed 1st.