Measuring and testing – Specimen stress or strain – or testing by stress or strain... – By loading of specimen
Reexamination Certificate
1999-09-02
2001-01-23
Noori, Max (Department: 2855)
Measuring and testing
Specimen stress or strain, or testing by stress or strain...
By loading of specimen
C623S022290
Reexamination Certificate
active
06176140
ABSTRACT:
The invention relates to a method for testing ceramic sockets for hip joint endoprostheses according to the preamble of claim
1
.
Systems with a modular design are normally used today for artificial hip joints, in other words a ball head is placed on a metal shaft with a pin, said head generally articulating with a socket made of polyethylene. The unavoidable abrasion, especially of the polyethylene, causes osteolysis that results in a loosening of the prosthesis and hence a repair operation.
This situation can be improved considerably if ceramic ball heads are used instead of metal ball heads. This is best accomplished by allowing ball heads made of aluminum oxide ceramic to articulate with socket inserts made of aluminum oxide ceramic.
Components of implants intended to be used in human beings must meet especially strict safety requirements. This also applies to ceramic components. Since ceramic materials are generally brittle, inhomogeneities in the material that concentrate stress lead especially easily to a fracture. This means that all parts containing defects that could result in fracture under application conditions must be detected and eliminated prior to use.
In quality control before now, only parts with defects on the surface could be eliminated by visual inspection. The known methods for non-destructive testing, such as x-ray fluoroscopy or ultrasonic testing, can theoretically be used for ceramic materials as well, but they are unable to detect defects of an extent that is small enough to be relevant for the required level of safety.
The primary goal of a final check however must be reliably to eliminate possibly defective parts in order to minimize any risk to the patient.
A requirement for the applicability and relevance of a proof test is that the load in the proof test must simulate as closely as possible the stress distribution that occurs in the part during use and also that no damage to the item being tested takes place as a result of handling while performing the proof test.
Thus for example a proof test in which the socket insert to be tested is inserted into an actual metal back is not possible, since it is not possible to remove the insert from the metal back after testing without damaging it.
A test would be possible in which the ceramic ball head is pressed into the ceramic socket or the ceramic socket insert with an overload (proof test). However, this test is not indicative since it merely results in a pointwise contact between the ball head and the ceramic socket insert, in other words not all of the contact areas between the ball head and socket can be adjusted during the test.
The goal of the invention is to provide a method for testing ceramic socket inserts that provides assurance that any defective socket inserts will be detected and eliminated during the quality check without there being any danger of damaging the socket inserts.
This goal is achieved according to the invention by the following:
All of the volume elements of the socket that are under load in the physiological load case are loaded;
Stresses are generated in the socket or in the socket insert that are higher by a specific factor than the stresses that are developed in the physiological load case.
Hence, the invention relates to a proof test device or method in which the ceramic socket inserts can be subjected to the necessary specific overload and in which the sockets can be removed from the device without damage.
The advantage of this method is that all of the ceramic sockets in which there are critical defects in the volume or on the surface will fail under load. Hence, this method is not only a test that discovers defective parts but also destroys all the defective parts.
The stress distribution in ceramic sockets is known from the results of a calculation of stress using the finite element method.
The ceramic sockets or socket inserts preferably consist of high-strength biocompatible ceramic, so-called bioceramic. In particular, these are aluminum oxide ceramic (medical-grade aluminia), zirconium oxide ceramic of the Y-TZP type, materials based on zirconium oxide/aluminum oxide, non-oxide ceramics such as silicon nitride, silicon carbide, and silicon aluminum nitride.
A preferred version is characterized by the fact that a hemisphere made of a deformable material is pressed under load into the socket.
Advantageously, the deformable material of the hemisphere is a polymer or a plastic.
In an alternative, especially preferred version, the interior of the socket is loaded by a fluid under pressure. This can produce fracture patterns that match those from bursting tests with hip joint balls. It can then be assumed that loading by a fluid pressure closely simulates the loading in a burst test.
Advantageously, a test punch is placed on the socket which seals off the interior of the socket from the outside by a sealing element and has a supply line for the fluid.
To reduce the fluid volume required, the test punch advantageously projects by a bulge into the socket and leaves only a gap for the fluid.
Logically, the socket to be tested is placed in a holder, so that according to the invention the holder supports the socket only at its conical upper end by means of a sealing element. The socket is anchored in the metal shell of the hip joint endoprosthesis by this conical part.
According to the invention, the fluid is a fluid suitable for high pressure, for example water or glycerin.
REFERENCES:
patent: 4187033 (1980-02-01), Zukowski
patent: 4722631 (1988-02-01), Tagami
patent: 4840631 (1989-06-01), Mathys
patent: 4840632 (1989-06-01), Kampner
patent: 4966108 (1990-10-01), Bentz et al.
patent: 5649779 (1997-07-01), Martin et al.
Autenrieth Ralph
Pfaff Hans-Georg
Richter Herbert
Willmann Gerd
Wimmer Martin
Antonelli Terry Stout & Kraus LLP
Cerasiv GmbH Innovatives Keramik-Engineering
Noori Max
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