Technical Field

The present disclosure relates to a process for manufac turing a rotationally symmetric plastic housing for a medical device, e.g., a dialyzer, an ultrafilter, or a device for removing carbon dioxide from blood.

Description of the Related Art

Common processes for manufacturing cylindrical housings for medical products, such as dialyzers, involve an in jection molding process. Because an injection molding tool must be manufactured for each housing design, the housing is very expensive when only a small number of housings are produced. Geometrical changes cannot be im plemented in the housing design within a short timeframe, because the injection molding tool must be altered. Dif ferent polymer materials cannot be tested by using the same injection molding tool, because these tools are de signed for one specific polymer material. Parts designed for production by injection molding must have uniform wall thickness over the whole part to avoid shrink holes.

Small numbers of housings may also be manufactured by a 3D printing process. However, medical grade polymers are not generally available as starting materials for 3D printing. Moreover, 3D printed parts usually exhibit high surface roughness, which is undesirable for medical de- vrces . It would be desirable to provide a manufacturing process for medical device housings, which uses medical grade polymers, yields housings with a high surface quality as required for medical devices, and allows for lowering production cost even if only a small number of housings is produced.

Summary

The present disclosure provides a process for manufactur ing a rotationally symmetric plastic housing for a medi cal device. The process involves the use of a CNC lathe and produces a housing having low surface roughness.

Brief Description of the Drawings

Figure 1 is a schematic cross sectional view of a semi finished housing and some of the components in volved in an embodiment of the process of the present disclosure;

Figure 2 is a schematic cross sectional view of an as sembly of the components shown in Figure 1.

Detailed Description

The present disclosure provides a process for manufactur ing a rotationally symmetric plastic housing for a medi cal device. Examples of medical devices include capillary dialyzers, hemofilters, plasma filters, ultrafilters, and gas exchangers. In one embodiment, the medical device is a device for extracorporeal membrane oxygenation (ECMO) or for extracorporeal carbon dioxide removal (ECC0 ₂ R) . The process for manufacturing a rotationally symmetric plastic housing for a medical device of the present dis closure comprises the steps of:

a) providing a massive cylindrical rod of a medical grade polymer;

b) producing a rotationally symmetric bore along the longitudinal axis of the cylindrical rod, the bore ex tending from a first end of the cylindrical rod to a sec ond, opposite end of the cylindrical rod, wherein the di ameter of the bore decreases from the first end in the direction of the second end;

c) introducing a mandrel having a shape matching the inner contour of the bore into the bore from the first end of the rod;

d) mounting a fixation cover on the second end of the rod;

e) connecting the mandrel and the fixation cover by a fastener to press the rod onto the mandrel;

f) machining the outer surface of the rod using a CNC lathe to produce a desired outer contour of the hous ing .

The process involves providing a massive cylindrical rod of a medical grade polymer. Examples of suitable medical grade polymers include polycarbonate (PC) , polyethylene terephthalate (PET) , polymethylmethacrylate (PMMA) , or polypropylene (PP) . In one embodiment, the medical grade polymer is polycarbonate.

In a first step of the manufacturing process, a rotation- ally symmetric bore is produced in the polymer rod along the longitudinal axis of the rod. The bore can be pro duced using a suitable cutting tool, e.g., a milling cut ter or a CNC milling machine. At this stage of the manu- facturing process, the polymer rod can withstand the forces induced by the cutting tools producing the bore.

The diameter of the bore of the housing tapers off from a first end of the polymer rod in the direction of the oth er end of the polymer rod. In one embodiment of the pro cess, the gradient of the diameter of the bore is con stant over the length of the bore, i.e., the bore takes the form of a truncated cone. In a particular embodiment, the angle of aperture of the cone is in the range of from 2 to 4 degrees. In another embodiment, the gradient of the diameter of the bore varies over the length of the bore, and zones having higher gradient alternate with zones having lower gradient. As a result, the bore takes a generally frusto-conical form with one or more ledges.

In a particular embodiment, the diameter of the bore of the housing tapers off from a first end of the polymer rod in the direction of the other end of the polymer rod; reaches a minimum at a distance from the other end; and then increases again, either at a constant gradient, or at a varying gradient, so that the diameter of the bore at the other end is larger than the minimum diameter.

In a second step, a mandrel having a shape matching the shape of the bore is introduced into the bore from the first end of the rod, i.e., where the diameter of the bore is largest, thereby mounting and fastening the poly mer rod on the mandrel. The inside surface of the bore contacts the surface of the mandrel.

A fixation cover is mounted on the other end of the rod. The mandrel and the fixation cover are connected to each other and tied together by suitable fasteners. In one em bodiment, one or more bores are provided in the fixation cover, and corresponding threaded bores are provided in the end face of the mandrel. A screw is introduced into each threaded bore of the mandrel through the correspond ing bore of the fixation cover, and the fixation cover and the mandrel are screwed together. Thus, the polymer rod is pressed onto the mandrel.

In one embodiment, the fixation cover is disc-shaped and has a central bore, i.e., it takes the form of a plain washer. In another embodiment, the fixation cover is disc-shaped and has several bores equidistant to the cen ter of the disc. In one embodiment, the diameter of the fixation cover is constant over its entire height. The diameter is larger than the diameter of the bore at the end of the polymer rod the fixation cover is mounted to. In another embodiment, the diameter of the fixation cover varies over its height, to match the shape of the bore at the end of the polymer rod the fixation cover is mounted to. This embodiment can be used in cases where, viewed along the longitudinal axis of the polymer rod, the diam eter of the bore reaches a minimum and then increases again towards the end of the polymer rod the fixation cover is mounted to. The fixation cover is introduced in to the bore, and the inside surface of the bore contacts the surface of the fixation cover, further stabilizing the polymer rod from inside. This embodiment allows for more flexibility in designing the inner contour of the housing .

In one embodiment, the mandrel and the fixation cover are comprised of metal. Examples of suitable metals include aluminum, stainless steel, and brass.

After the polymer rod has been mounted on the mandrel, the mandrel is transferred to a CNC lathe. The outer sur- face of the polymer rod then is machined using the CNC lathe to produce the desired outer contour of the hous ing. The outside surface of the polymer rod can be ma chined without a risk of breaking the material, as the rod is stabilized on both ends and from within by the mandrel and the fixing cover. Furthermore, vibrations in duced by the cutting tool are minimized by this stabili zation, resulting in a smoother surface of the final housing .

In one embodiment of the process, the arithmetic average roughness R _a , measured according to DIN EN ISO 4287:2010, of the wall surface of the finished housing is less than 10 ym, for instance, in the range of from 0.2 ym to 5.0 ym, or even from 0.2 ym to 2.0 ym. Both the inner and the outer surface of the finished housing show an arith metic average roughness R _a in the aforementioned range. In contrast to that, parts produced by 3D printing gener ally exhibit much higher surface roughness, typically with an R _a in the range of from 12.5 ym to 25 ym.

The process of the present disclosure allows to produce housings having a small wall thickness, i.e. thin-walled housings. A wall thickness of less than 1 mm can be achieved. In one embodiment, the wall thickness of the final housing is in the range of from 0.5 mm to 5 mm, for instance, from 0.5 mm to 2.0 mm.

In one embodiment, the wall thickness is uniform over the whole length of the housing. In another embodiment, at least one section of the final housing has a wall thick ness that is different from the wall thickness of other sections of the housing. In other words, the wall thick ness of the housing can vary over its length. The process of the present disclosure thus is not limited to produc- ing housings with uniform wall strength as are injection molding processes. This allows for more flexibility in designing the housing.

Another advantage of the process of the present disclo sure is that it can use polymer materials that normally cannot be processed by injection molding. Examples in clude non-thermoplastic polymers like polytetrafluoroeth- ylene (Teflon ^® ) , silicone rubber, and polyurethane (PUR) .

It will be understood that the features mentioned above and those described hereinafter can be used not only in the combination specified but also in other combinations or on their own, without departing from the scope of the present invention.

The process of the present disclosure will now be further described in the following examples and referring to the attached drawings .

Figure 1 is a schematic cross sectional view of a semi finished housing 10 and some of the components involved in an embodiment of the process of the present disclo sure. A mandrel 20 having a disc-shaped base 21, a frus- to-conical part 22 matching the inner contour of a bore 11 in the semi-finished housing 10, and a threaded bore 23 in its end face is shown. The mandrel 20 is introduced into the bore 11 from the end of the housing 10 where the bore 11 has its largest diameter. A fixation cover 40 is mounted on the opposite end of the housing 10. In the em bodiment shown, the fixation cover 40 is disc-shaped and has a central bore matching the threaded bore 23 of the mandrel 20. A screw 30 is used to connect the mandrel 20 and the fixation cover 40 and tie them together. Figure 2 is a schematic cross sectional view of an assem bly of the components shown in Figure 1. The housing 10 is pinned on the mandrel 20 and fastened by the screw 30 and the fixation cover 40. The assembly as shown in Fig. 2 is transferred to a CNC lathe and the outer surface 12 of the housing 10 is machined to yield a finished housing having a desired rotationally symmetric outer contour.

List of reference signs

10 housing

11 bore

12 outer surface

20 mandrel

21 base

22 truncated cone

23 threaded bore

30 screw

40 fixation cover