CA1135197A - Forming fluid manifold - Google Patents

Abstract

ABSTRACT OF THE DISCLOSURE
A fluid manifold is constructed in a fluid flow apparatus that uses a pleated membrane bonded at its tips to the interior of the apparatus housing by forming a channel portion in the housing interior, applying a thixotropic adhesive around the channel portion, and placing the membrane tips against the adhesive to provide a formed-in-place gasket prior to potting of the membrane tips to the housing interior with a potting material.

Description

113519~

This inVention relates ta fluid flow t~ansfer devices using separatory membranes and fluid 10w manifolds at the inlet and outlet.
In constructing a fluid flow transfer device such as a hemodialyzer that uses a pleated membrane, it is desirable to pot the membrane tips to the interior of the housing on the blood side of the membrane to force the blood down into the membrane folds and thereby prevent shunting of the blood from inlet to outlet without being dialyzed within those folds. Such potting is effectively done with an initially easily flowable material such as low viscosity polyurethane. It is important, however, to keep the potting from flowing into the blood inlet and outlet manifold areas and into the membrane folds opposite those areas, or blood flow into or out of those folds will be undesirably blocked and the dialyzer will have a reduced capacity.
We have discovered that by applying a thixotropic adhesive around the manifold areas prior to potting and contacting the membrane tips with the still-wet adhesive, we can provide a formed-in-place gasket that will prevent liquid potting from entering the manifold areas or wicking into the membrane folds exposed to those areas. Our invention thus prevents blockage of the manifold areas and yields a more efficient fluid flow transfer apparatus.
Thus, according to one aspect of the present invention, there is provided in a method of forming a fluid flow manifold for a fluid flow transfer apparatus having a pleated membrane stack and a housing, wherein said membrane is folded and the fold edges form tips that are bonded to an interior surface of said housing by a potting material that is introduced in a flowable state, and wherein said housing has a channel portion formed along said interior surface, said channel communicating through a fluid port to the exterior of said housing, and said channel forming a manifold with said membrane stack, the improvement comprising the steps of: applying a gasket material to said housing interior surrounding said channel portion prior to bonding tlle tips of said pleated membrane to said housing~ said gasket material being flowable enough to conform to the shape of the membrane tips and to penetrate into the ; spaces formed between the tipswhile viscous enough to avoid wicking of itself .
-1- ~

113s~17 along said spaces into the maniold area, that is, thixotropic, and placing said membrane tips against said applied gasket material while said material is still deformable, to cause said material to conform to said tips and to penetrate far enough into said spaces between tips to prevent capillary flow of subsequently-introduced potting material through said spaces, whereby when said potting material is introduced it is prevented from blocking the manifold area.
According to another aspect of the present invention, there is provided in a fluid flow transfer apparatus having a pleated membrane stack and a housing, wherein said membrane is folded and the fold edges form tips that are bonded to an interior surface of said housing by a potting material that is introduced in a flowable state, and wherein said housing has a channel portion formed along said interior surface, said ch2nnel communicating through a fluid port to the exterior of said housing, and said channel forming a manifold with said membrane stack, the improvement comprising a formed-in-place gasket adjacent said channel portion, said gasket being formed of a material different from said potting material, said gasket conforming to said interior surface and to said membrane tips, and said gasket protruding far enough into the spaces formed between adjacent tips to prevent capillary flow of potting material through said spaces into the manifold area and resulting blockage of the area.
In particular aspects, our invention includes forming ribbed portions around the manifold areas and placing the adhesive on the sides of the ribbed portions remote from the manifold areas, and using silicone rubber adhesive.
The invention will now be described in greater detail with refer-ence to the accompanying drawings, in which:
Pigure 1 is a perspective view of a dialyzer utilizing the presently preferred embodiment;
Figure 2 is a somewhat diagrammatic sectional view along 2-2 of ' ~, -la-~" ~}

11351~7 Figure 1;
Figure 3 is an exploded view of a portion of the membrane and support netting of the dialyzer of Figure l;
Figure 4 is an enlarged perspective view of a portion of the support netting of Figure 3;
i Figure 5 is a sectional view along 5-5 of Figure 1; and Figure 6 is a greatly erlarged vertical sectional view like that of Figure 2 of a portion of the membrane and support nettirg of the dialyzer of Figure 1.
The embodiment shown in the drawings and its operation are now described.
1. Embodiment Figures 1 and 2 show dialyzer 10, which includes a two-part housing comprising trough-shaped polycarbonate casing 12 and interfitting polycarbonate casing 14, which is open at both longitudinal ends and has a pair of longitudinal fins 16. Casing 12 includes inlet 18 and outlet 20, both integrally molded therewith. Casing 14 includes integrally molded inlet 22 and outlet 24. Inlets 18 and 22 and outlets 20 and 24 become char~
nels of steadily decreasing cross section when they enter their respective casings. A pair of stub shafts 26, formed by mating semicircular portions on casings 12 and 14, and a pair of cooperating stops 28 (only one is shown in Figure 2), spaced equidistantly longitudinally from the right stub shaft, permit rotatable, vertical mounting of the dialyzer on a bracket, for degassing and normal operation.
Dialysis membrane 30, a Cuprophan (trademark of Enka Glanzstoff AG) cuprammonium cellophane sheet having a generally accordion pleated con-figuration and to which glycerin has been added as a plasticizer and humectant for smooth processing, is squeezed between fins 16, and is sealed with poly-urethane potting 32 along its outermost flaps to the outer faces of the fins.

- 2 -:, 1135~9t7 The folded upper tips of membrane 30, shown somewhat rounded in Figure 2~
are affixed to casing 12 by being anchored in polyurethane potting 32, there-by forming a series of separate parallel fluid flow passages, indicated by B in Figure 3, in the valleys above the membrane. Potting of the upper tips prevents shunting of fluid directly from inlet 18 to outlet 20 without entering passages B. Support netting 34, a nonwoven polypropylene mesh (see the arrangement of its strands 35 in Figure 4) sold under the Du Pont trademark Vexar, is also in the form of an accordion pleated sheet, and is positioned within membrane 30 on the membrane side adjacent casing 14 (Figure 3). By this configuration, support netting 34 spaces apart the underside faces of adjacent membrane walls with two layers of the netting shown in Figure 4, and provides parallel fluid flow passages underneath the membrane, indicated by D in Figure 3. Netting 34 is not bonded to either casing, except at its longitudinal ends, as will be described hereinafter, and unlike membrane 30 does not fold over fins 16.
Both membrane 30 and netting 34 are pleated along generally parallel lines, and strands 35 run at 45 to those lines.
Casing 12 has a continuous peripheral ridge 50 that seats in continuous peripheral groove 52 of shelf portion 54, which surrounds casing 14. When casing 12 and casing 14 are so interfitted, the tips of fins 16 are vertically spaced from the adjacent inner surface of casing 12 and from ribs 36 running transversely on that surface, to avoid cutting of membrane 30 between the pointed fin tip and casing 12.
Longitudinal ends of membrane 30 and netting 34 are bonded to casings 12 and 14 by pottirg 32 (Figure 5). Transverse ribs 36 (one shown in Figures 2 and 5) of casing 12 space the folded tips of membrane 30 from the casing ceiling to provide channels for flow of potting 32 during con-struction of dialy~er 10, described hereinafter. Ribs 36 have arcuate por-tions 56 which laterally space fins 16 from the angled and vertical sidewalls 113519~7 of casing 12 by tangential contact with fins 16 through membrane 30;
portions 56 perlnit the flow channels to extend from the central fluid chamber between fins t6 to the side compartments between each fin and the corresponding sidewall of casing 12. A continuous ridge of General Electric RTV 108 thixotropic silicone rubber adhesive 38 adjacent casing ribs 40 surrounds the channel portion of outlet 20 (and in the same way inlet 18, though not shown) and bonds to the membrane tips, to act as a formed-in-place gasket in order to prevent flow of potting 32 into the channel area during conr struction. The adhesive needs to be thixotropic so that it will not itself wick across the membrane folds in the manifold area and thus block entrances to passages B. Inlet 18 and outlet 20 thus cooperate along their channel portions with membrane 30 to form inlet and outlet manifolds into and out of the fluid passages indicated at B in Figure 3. Likewise inlet 22 and outlet 24 cooperate along their channel portions with membrane 30 on its underside to form inlet and outlet manifolds into and out of the fluid passages indicated at D in Figure 3.
In constructing dialyzer 10, one pleats a sheet of membrane 30, pleats a sheet of netting 34, and combines the two by placing each fold of netting within a corresponding fold of membrane (Figure 3). The resultant membrare-netting stack is squeezed together and placed in a casing 14 between fins 16, with each of the two outermost flaps of membrane 30 folded over its respective fin. Each outermost flap is then sealed to the outer face of the adjacent fin 16 with polyurethane potting 32. Casing 12 is then provided, and two ridges of silicone rubber adhesive 38, each having a weight of approximately one gram, are then applied around the outer edges of the channel portions of inlet 18 and outlet 20 of casing 12, adjacent ribs 40 and on end shoulders 41 (one shown in Figure 5). Casing 14 is then interfitted with casing 12. Ridge 50 is wetted with solvent and then pressed - into groove 52, to which it bonds on drying. A ramp portion 48 running along ~ - 4 -the base of each fin 16 serves to guide ridge 50 into groove 52. The interfitting is done while the silicone adhesive 38 is still wet so that it will seep a short way (about 1/16 to 1/8 inch) into the membrane folds to prevent wicking of polyurethane potting in the folds in the manifold area and consequent undesirable blockage of fluid flow into or out of the folds.
The membrane and netting longitudinal ends are then potted in polyurethane 32, which is applied through holes 42 in casing 14 at each end thereof by a needle inserted through tapes (not shown) placed on raised portions 58 and covering the holes 42 (only one hole is shown in Figure 5). Dialyzer 10 is held vertical during this process, with the end to be potted at the bottom. After curing of the potting at the end, the dialyzer is rotated 180, with the other end at the bottom, ready to receive its potting. Potting seeps into the netting side of the membrane but not generally into the other side (Figure 5). Holes 42 are sealed with the hardened potting, and the tapes are removed.
The potting of the membrane tips and flaps to casing 12 now takes place. Dialyzer 10 is positioned horizontally with the membrane tips to be potted below the membrane body and horizontally aligned with casing 12 on the bottom (inverted from Figure 2). Plugs (not shown) are placed in inlet 22 and outlet 24, and a needle is inserted through one of the plugs to apply 300 mmHg positive pressure from a pressure source through netting 34 against the face of membrane 30 adjacent casing 14. The pressure source is removed after pressurization is complete, and a pressure gauge is used to check for leaks. The plug maintains the pressure. Inlet 18 and outlet 20 are open to atmospheric pressure. Approximately 60cc of polyurethane potting 32, which comprises an initially liquid mixture of~Polyol 936 and ~orite 689, a urethane prepolymer, both manufactured by N. L. Industries, Bayonne, New Jersey, is then pumped into dialyzer 10 through hole 44 (Figure 2) in one sidewall of casing 12. The potting flows into the side compartment ~t~ S

`` 11351~7 formed between the sidewall of casing 12 and one fin 16 through channels between arcuate rib portions 56, down into the trough of casing 12, trans-versely through channels formed by 0.06 inch deep transverse ribs 36 (Figure 5), and again through channels between arcuate portions 56 up into the other side compartment between the other sidewall of casing 12 and the other fin 16. Arcuate portions 56 prevent fins 16 from flaring outward to contact the sidewalls of casing 12 and thereby block potting Mow into or out of the side compartments. A pair of pinholes (not shown) in casing 14, one adjacent inlet 22 and the other adjacent outlet 24, let air escape as the potting is pumped in. The potting settles uniformly on the inner surface of casing 12 and reaches the same level in each side compartment. Because of the positive pressure maintained on the opposite side of membrane 30, passages B are closed up, and the potting cannot wick or otherwise flow up between the folds. After a curing time o~ 60 minutes, one of the plugs is removed to permit a vacuum to be applied to the membrane side that ini-tially received the higher pressure. Ten dialyzers 10 are connected in parallel to a vacuum pump through a 25 gauge one inch long needle acting as a pneumatic resistor, and the evacuation produces a negative pressure from 20 to 24 inches of mercury. The resistor chosen gives a desirable rate of evacuation. If evacuation is either too fast or too slow, unwanted bubbles ; will form in the polyurethane potting.
As a result of the evacuation, the folds of membrane 30 are drawn back from each other, enlarging the spaces between the folds, and are drawn tightly and even crushed against the folds of netting 34 (Figure 6), which then support the membrane and prevent it from pulling away from the inner surface of casing 12. The nowimore viscous potting can seep up through the entrances to the spaces between the membrane folds and into those spaces to increase the bonding surface area provided by the membrane tips and thereby further improve the casing-membrane bond effected by the potting.

However, the potting is too viscous to seep undesirably far into those spaces so as to interfere with flow passages B. Curing time between the pressure and evacuation steps is important; if the time chosen for the par-ticular potting compound is too short, the potting will not be viscous enough and will seep too far into the spaces between the membrane folds when the vacuum is applied, thus interfering with fluid flow passages B.
If the time is too long, unwanted bubbles will form in the potting because of its increased viscosity.
After further curing, dialyzer 10 is ready for use.
Dimensions of dialyzer 10 are as follows. Its housing is approxi-mately 12 inches by 3 5/8 inches by 2 inches. Membrane 30 has a dry thick-ness of 13.5 microns and an actual surface area of approximately 1.54 m2.
Netting 34 has 16 strands per inch and a mean thickness of 0.022 inch. Both membrane and netting have 66 folds ("folds" meanirlg adjacent pairs of me~
brane or netting walls joined along a crease), which is equivalent to the number of upper tips of membrane 30 affixed to casirg 12 (far fewer folds are shown in the somewhat diagrammatic view of Figure 2). There are 65 fluid flow passages B along the folds. The channel portions of inlet 18 and outlet 20 are approximately 2 3/4 inches long, 3/8 inch wide and 5/32 inch deep adjacent the tubular portion of the inlet or outlet, which acts as a port, and 3/8 inch wide and 1/16 inch deep at the narrower channel tip. There are seventeen ribs 36, spaced about 1/2 inch apart, and seven-teen corresponding pairs of arcuate portions 56. Additionally, there is a pair of arcuate portions 56 (not shown) between each longitudinal end of casing 12 and inlet 18 and outlet 20.
2. Operation When used as a hemodialyzer, dialyzer 10 operates as follows.
Blood tubing is connected to inlet 18 and outlet 20, and dialysate tubing is colmected to inlet 22 and outlet 24. Dialyzer 10 is mounted vertically, 11351~7 with inlet 18 and outlet 24 on top. Blood is introduced into inlet 18, Mows along its channel portion, and then, partly because of the potting 32~ flows into the spaces B between the folds of membrane 30 and in the general direction indicated by arrows in Figure 3, until it is collected in the channel portion of outlet 20 and then passes out of dialyzer 10.
Dialyzing fluid or dialysate is introduced into irlet 22 and flows along its channel portion where it is distributed into all of the dialysate flow passages D (Figure 3), and flows in the general direction indicated by arrows in Figure 3, countercurrently with blood flow. It has been found that the membrane tips adjacent casing 14 dolnot need to be potted to it, when dialysate is introduced on this side. Dialysate is collected in the channel portion of outlet 24 and then passes out of dialyzer 10, from which it is collected for regeneration or disposal. Dialysis occurs across membrane 30. Blood is introduced into its inlet port with use of a pump while dialy-sate is introduced into its irlet port at a lower pressure. Thus in addition to removal of unwanted substances from the blood by dialysis, dialyzer 10 effects removal of water from the blood through membrane 30 because of the pressure difference across the membrane.
In normal operation dialysate flows upward because of the vertical positioning of dialyzer 10, and the dialysate flow paths D (Figure 3) are constantly being degassed as dialysate flows in that direction. The blood flow paths B (Figure 3) are degassed prior to dialysis by inverting dialyzer 10, introducing a saline primirg solution, and having that solution flow upward for a predetermined time.
An enlarged view of the arrangement of support netting 34 and membrane 30 is shown in Figure 6. Potting 32 has seeped somewhat into the space between the folds shown, to increase the bonding area and hence im-prove the bond between membrane tips and the potting. The pleated sheet con-figuration of nettirg 34 provides a spacer between adjacent membrane folds 11~519~7 that is two layers thick. The effect i9 to increase the dialysate flow passages and to lower the dialysate pressure drop through the dialyzer. The double layer of netting tends not to entrap air bubbles, which on accumulating would impede dialysate flow and increase the pressure drop. Instead the bubbles desirably wash on through. As to blood flow, strands 35 ten~ to pinch adjacent folds of membrane 30 at spaced points designated P in Figure 6. Between points P portions of folds of membrane 30 sag into inter-strand spaces of netting 34 to create separate blood flow passages 46. Pressure from the blood helps keep the membranes apart for blood flow.
Dialyzer 10 provides the following specifications and results when used in hemodialysis:
Pressure DroPs Blood (at flow rate, QB~ of 200 ml/min. and - 15 m~Hg Transmembrane Pressure (TMP) of 100 mmHg) (Hematocrit = 30%) Dialysate (at flow rate, Qn, 500 ml/min. and 2 mmHg TMP of 100 mm~g~
In Vitro Clearances *
- (QB = 200 ml/min.
QD = 500 ml/min.TMP = 100 mmHg) Urea 140 ml/min.
Creatinine 120 ml/min.
B-12 31 ml/min.
Ultrafiltration Rate (in vitro) * 3.6 ml/hr/mmHg TMP
Blood Volume 100 mmHg TMP85 ml 200 mmHg TMP120 ml Dialysate Volume730 ml Maximum TMP500 mmHg * Performance subject to variations in Cuprophan membrane.
_ g _ Variations and Modifications The fluid flow manifold of the present invention has other uses beside that in hemodialysis; for example, it can be used in laboratory di-alysis.
Other embodiments of the invention will be obvious to those skilled in the art.
Other Inventions The method of injecting liquid potting material into a housing for uniform potting of the membrane tips to the housing was the invention of Thomas E. Goyne.
The fin-membrane sealing construction was the invention of Donn D.
Lobdell.
The pressure-evacuation two-step method for anchoring the membrane tips to the casing was the invention of Dennis J. Hlavinka, and is the sub-ject matter of Canadian patent application Serial No. 300321 filed on`April

3, 1978, . ':' ,.,~ .~ .,

Claims (9)

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. In a method of forming a fluid flow manifold for a fluid flow transfer apparatus having a pleated membrane stack and a housing, wherein said membrane is folded and the fold edges form tips that are bonded to an interior surface of said housing by a potting material that is introduced in a flowable state, and wherein said housing has a channel portion formed along said interior surface, said channel com-municating through a fluid port to the exterior of said housing, and said channel forming a manifold with said membrane stack, the improvement comprising the steps of:
applying a gasket material to said housing interior surrounding said channel portion prior to bonding the tips of said pleated membrane to said housing, said gasket material being flowable enough to conform to the shape of the membrane tips and to penetrate into the spaces formed between the tips while viscous enough to avoid wicking of itself along said spaces into the manifold area, that is, thixotropic, and placing said membrane tips against said applied gasket material while said material is still deformable, to cause said material to conform to said tips and to penetrate far enough into said spaces between tips to prevent capillary flow of subsequently-introduced potting material through said spaces, whereby when said potting material is introduced it is prevented from blocking the manifold area.

2. The method of claim 1 wherein said gasket material is silicone rubber.

3. The method of claim 2 wherein said potting material is polyurethane.

4. The method of claim 2 wherein said channel portion is about 2 3/4 inches long, about 3/8 inch wide and 5/32 inch deep adjacent said fluid port, and tapers to a depth of about 1/16 inch and width of 3/8 inch at its opposite end, and approximately one gram of adhesive is applied around said channel.

5. The method of claim 1 wherein said method in-cludes forming a ribbed portion in said housing longitudinally surrounding said channel portion and said gasket material is applied on the sides of said ribbed portion away from said channel portion.

6. In a fluid flow transfer apparatus having a pleated membrane stack and a housing, wherein said membrane is folded and the fold edges form tips that are bonded to an interior surface of said housing by a potting material that is introduced in a flowable state, and wherein said housing has a channel portion formed along said interior surface, said channel communicating through a fluid port to the exterior of said housing, and said channel forming a manifold with said membrane stack, the improvement comprising a formed-in-place gasket adjacent said channel portion, said gasket being formed of a material different from said potting material, said gasket conforming to said interior surface and to said membrane tips, and said gasket protruding far enough into the spaces formed between adjacent tips to prevent capillary flow of potting material through said spaces into the mani-fold area and resulting blockage of the area.

7. The subject of claim 1 or 6 wherein said gasket material is adhesive.

8. The subject of claim 1 or 6, wherein said gasket material extends fully around said channel portion.

9. The fluid flow apparatus of claim 6 wherein said housing interior has a ribbed portion longitudinally surrounding said channel portion and said gasket is formed on the sides of said ribbed portion away from said channel portion.