DE2513382A1 - Nickel chromium alloy - for dental applications - Google Patents

Abstract

The Ni-Cr alloy has the basic compsn. 80% Ni, 20% Cr, and is chosen from the group designated SEL and is pref. SEL No. 2.4869. It is corrosion resistant, castable, and has a similar coeff. of thermal expansion as that of porcelain. The alloy can be cast centrifugally and has a hardness which lies slightly above that of gold. Used for dentures, bridges and crowns which are coated with porcelain or a synthetic material.

Description

Manufacture of dentures using a new material as well as the process used for production.

The new technology is characterized by the use of nickel-chromium steel for the economical production of crowns, bridges, etc. and that for them Manufacture of dentures using this material.

This replaces the previously common expensive precious metals Description The new procedure for dentures is based on a homogeneous connection of the nickel-chromium material with the usual porcelain, precious metal and synthetic materials, as Basic body applicable with success.

The base made by the traditional centrifugal casting process -body can be manufactured with the highest accuracy, its hardness is only low above that of gold.

The active ingredient NiCr 80/20 is already used in many industrial areas Manufacturing used. So z0B0 in the rest of the medical technology, the reactor construction , in tube technology, etc. It is therefore always guaranteed that this standard material - which some manufacturers have in their range - can be obtained relatively inexpensively at any time can be. At this point we must again expressly refer to the much lower ones Material costs are pointed out against the use of precious metals.

It seems equally important that the conventional facilities of a dental laboratory for the manufacture of dentures, using this method is sufficient and there are no new investments in this regard.

The usual coatings, such as gold paste, porcelain, etc. remain in the quality used so far. In addition, n repair work n and Any number of reworking operations can be carried out because of the high melting point of the Ni-Cr material, no changes to the base body take place.

Furthermore, it can be seen as positive that the dimensions of the base body can be kept much smaller than previously used Fabrics. Coupled with the mentioned high accuracy of the cast part and in hindsight to the possible nuaaean of the coloring of the porcelains and the application of the most diverse With coating methods, the dentist has a process in hand that allows him To offer high-quality dentures with less economic outlay than it was possible with the precious metals used up to now.

Material As mentioned, this method is based on the use of the material Marked according to SEL.-No. 2.4869 It is a material that is corrosion-resistant , high temperature resistant and easy to cast and its hardness is slightly above the of the gold: Hardness according to Brinell: KB 2.5 / 62.5 / 30 = 164 In the test, a Delivery used which showed as analysis: Cr 19.6 ffi Ni 78.2 ffi Si 1.4% Fe 0.6% In addition, traces of Mn, Al, Cu were found. These alloy elements - However, proportions are not decisive when assessing the material and do not affect the procedure either specific weight : 8.4 The melting point is approx. 14000 C. The expansion coefficient corresponds to roughly that of the materials used so far, especially porcelain and that is very important, as otherwise the dentures will be damaged when exposed to high temperatures would. That was also one of the problems when looking for the right material Since it is - as mentioned - a material from the SEL, you can procure the substance from different manufacturers. It is the author however Only in German companies did the small dimensions of 8-10 mm succeed in the desired To receive a small amount of teeth, sketch A shows the structure as an example a crown with the various coatings over the base body made of CrNi SO / 80 Sketch 3 is the illustration of the positive mold in perspective as it is usually is made from the pre-machined tooth.

Sketch C shows this mold with the modeling wax applied over it Sketch D is a schematic representation of the modeling wax casting mold for manufacture of the base body Sketch E shows the rubber die, a device that is used for the Embedding work step was designed. Sketch F is the representation of the work step : Form ring with embedded casting mold placed on the rubber die and that's it for heat treatment sketch G Schematic representation of the centrifugal casting device with attached complete mold .4 Manufacture of the base body - casting of the denture of the patient, a compression mold 1 is first made in the usual manner . There are used for this positive mold, the materials that were previously used in were used to make such impressions. The procedure also remains the corpse This mold - sketched in Figure B / 1 - is made with modeling wax overdrawn . See sketch C / 2. The processing of the modeling wax coating2, the with a thickness of about 0.07 mm should be applied as usual - with a spatula , or the like. - be brought to the final shape. It is important that this Wax form 2 a pouring nozzle 3 is put on 9 the pouring nozzle has about 1.5 - 2mm it it goes without saying that one must not forget the mold before applying the wax coating smeared with oil to make it easier to lift off the wax mold later.

The rubber die 4 of a single-bed centrifuge serves as a substructure for the Work step battening the casting mold 2 into the mold ring 5. To produce the complete Casting mold with casing is first the mold 2 reversed on the cone of the Rubber die 4 with model wax 8 put on 8 The form ring 5 is also on the rubber die 4 on top - see sketch Fe This should also be mentioned here that the wax mold 2 cleaned with alcohol before being placed on the rubber die 4 to rinse off the oil residue that has adhered from the previous operation.

The most varied of previously customary casting compounds can be used as the embedding compound 7 the known manufacturers are used.

Before the investment 7 is introduced into the mold ring 5, it must be in this an asbestos sheet6 must be inserted. This asbestos film 6 has two punctures: 1. the Investment 7 can expand during the following heat treatment and 2. the hard one The investment compound 7 can be removed more easily from the mold ring 5 after the casting process.

The investment 7 is premixed under vacuum as usual and then carefully inserted into the mold ring 5 with the "casting mold 2" integrated in it The Gwimiimatrize 4 with the attached, filled mold ring 5 is on a Brought vibrator and there the investment 7 is compacted. This takes about 30 minutes to complete Then the molded ring 5 and its contents are placed in a laboratory oven and slowly heated to approx. 8000 0. It is important that this warming is very slow takes place ° and about 100 in about 8 minutes. It should not go unmentioned that the molded ring 5 and its contents are placed in the oven with the conical incision facing downwards must be, because during the heating the wax should be removed from the investment 7 from flowing so that the cavity for the casting, the base body 3 is created. at The investment 7 is also hardened during this process, holding time: around 30 minutes. in the furnace The casting of the base body 13 As already mentioned, the base body 13 can be manufactured using the S ¢ h extrusion casting process on a normal centrifugal casting machine in such a way that the casting channel of the casting mold 2 exactly with the bore of the casting device sketch G is aligned Cr-Ni - material with a size corresponding approximately to the volume of the later Base body13 is placed on the hotplate of the casting device. To the determination des Volunes of the basic body certainly does not need to be entered after this Material section 9 heated to approx. 14000C by means of an acetylene burner, i.e. to melt the centrifuge is set in motion and the material flows into the mold 2. and fills the cavity 0 When everything is cold, it will Gußteil13 broken from the investment.

The pouring nozzle 3 is removed and the casting 13 plastered. the Whole with a stone with a medium grain size. Ban will the part is cleaned of all adhering dirt and no longer with the Hands touched. The coating with porcelain, or the like.

Repair work before coating with porcelain should be reflected One can expect corrosion to occur at some points on the casting mold 13 use the casting 13 for the production of the base body 13 anyway. One must just first put the part in an oven and place it under a vacuum with 75 mm water column heat to 900 - 1100 C This is how all gases evaporate. Used after cooling you gold paste and fill in the imperfections, the gold paste is with 900 - 1000 C a -baked and you can then apply the desired porcelain coating 11 and 12 Manufacturing of the porcelain coatings 11 and 12 The washed after pouring and "messing up" Base bodies 132 are placed in a laboratory furnace under a vacuum of 75 mm, better 10 Torr and are held there for some time at 8000 C, and then - again below Vacuum to be brought to about 10500 C. Then the vacuum is removed and the parts cool down. This causes a small amount of oxide to form on the surface of the die The surface then looks light gray to light blue-gray. With the material Ni-Cr 80 / 20 this could contribute to a better adhesion of the subsequent coatings. In contrast to the oxidation phenomena on precious metals, these have a negative effect on the adhesiveness of the coating layers.

However, it should not go unmentioned that also with the nickel-chromium active ingredient a bare surface can be achieved, namely when the cast base body 13 cool under vacuum. However, a higher vacuum would then be desirable so that all impurities evaporate on the surface of the part and thus a certain "fine porosity" is artificially created and the to be applied Coatings (11 and 12) adhere better. You can then also apply a additional OPALA -layer 11- which is described below - dispense with the Parts with a discolored surface must always have an opaque OPAKA - Keep the layer, otherwise the darker surface would show through the porcelain This opaque layer is applied and applied in the known manner . First dried at approx. 3000 C and then slowly heated to 1000 C and baked If the dark surface still shines through after the first coat, then this step can be repeated.

But there is still another possibility, a surface that adheres well even when cooling under vacuum. You mix OPACA powder with it Oil and coat the surface with a layer of this mixture.

The parts are placed in the laboratory oven at 7000C for a period of time held and slowly heated to approx. 1000 - 1050 C under vacuum in the specified size.

After cooling it can be seen that the surface is relatively rough has arisen, which gives the subsequent porcelain coating 12 good adhesion As mentioned at the beginning, a wide variety of porcelain coatings can be applied.

The manufacturers are known. The different qualities of porcelain require different baking temperatures or hardening temperatures.

The so-called low-melting porcelains melt at 900 - 1000 C, the highest melting a little over 13000 C All these temperatures are however still below the melting point of the Ni-Cr-Werkatoffes Therefore one can also several times Apply layers without damaging the basic model or, better, the basic body 13.

This in turn enables the most specified work one can do achieve a wide variety of natural-looking color nuances and shades if you apply ceramic, gold paste and bake in a laboratory oven at 900 - 10500 C. Thin porcelain layers 12 are then applied and fired. One repeats the coating until you have achieved the appropriate color. Plastic coatings Plastic coatings of any known type can be applied to the cleaned base body can also be applied. The instructions of the ACRYLIC manufacturers apply here.

The adhesion of these coatings is also impeccable0 repair and completion of crowns and bridges All previously made by this process Denture molds can easily be reworked.

It is expedient to use gold paste for this purpose. The one to be added part is supplemented with gold paste, which is cleaned with a spatula. The mass is pre-dried at approx. 400 C and then in a laboratory oven under vacuum at 900 - 1000 C hardened.

This process can be repeated as often as required

Claims (1)

The following claims 1) result from what has been described Use of the material NiCr 80/20, SEL.Nr, i.e. material No. 2. 4869 2) The described methods for applying porcelain and other coatings . The repair of the dentures results from it and was also described.