DE4401896A1 - Control of shining action on cobalt@- chromium@ dental alloys - Google Patents

Abstract

To polish cobalt-chromium cast dental alloys, the measured values are combined by a fuzzy logic control to give the optimum current density, the temp. and shine time. Also claimed is an appts. with a control (27) which combines the values for the shining process, as a fuzzy logic control, to set the current (14), the heater (9), cooler (10) and the motor (11).

Description

The invention relates to a method for electrolytic polishing (polishing) of cobalt-chromium Dental casting alloys according to the preamble of claim 1, also a gloss device for the cobalt Chromium dental casting alloys according to the preamble of claim 8.

The electrochemical processing of metals and semiconductors with an external power source in electroche Mixing bath systems (EC bath systems) is in the modern manufacturing technology through a number of Process has been in use for a long time. The "anodic removal" is the "dissolution" more electrically conductive or semiconducting materials (VDI Guideline 3401 Sheet 2).

DE 39 41 820 A1 describes the composition of cobalt-chromium dental casting alloys Manufacture of dental prostheses known to be laser welded.

So far no automatic method is known, based on the surface and the number of cobalt-chrome dental casting alloys as well as the condition of the electrolyte Current density and gloss time. So far, this task has been performed by experienced operating personnel carried out.

The invention has for its object to provide a polishing process or a polishing device that the polishing process is automated. This object is characterized by the invention according to the 8 resolved drawing features of claims 1 and 8 respectively.

The inventive method with the features mentioned in claim 1 and the device according to claim 8 have the advantages over the prior art that the shine in op guaranteed current density, the gloss time is set automatically, the gloss time mini lubricated and thus the electrolyte consumption is reduced.

By using the fuzzy logic control, various boundary conditions can be taken into account and can be realized in an automatic glossing process without the effort to realize the Ver driving significantly. The glossing process remains transparent and traceable.

In a preferred embodiment of the method, current and temperature are between the Electrodes, or in the glossy liquid, as well as their time derivatives.

Furthermore, the state of the electrolyte is based on the time integration over the current measured and saved. Based on the maximum current, the number and the Surface of cobalt-chrome dental casting alloys are closed. With the help of relatively less Si A good automatic glossing process can already be realized.

Also preferred is an embodiment of the method in which various gloss processes a distinction can then be made as to whether one or two cobalt-chrome dental casting alloys are shiny and whether the size of the cobalt-chrome dental casting alloy is between very small and very large varies. In addition, various gloss processes are due to the previous consumption of Electrolyte affected. Furthermore, by regulating the temperature by means of a heater and  Cooling ensures that the polishing machine always works in the correct temperature range. Through the Taking these measured values into account is not simply an automatic glossing process ren, but also a minimal consumption of the gloss liquid can be ensured, since with almost optimal current density is shined.

Further embodiments result from the remaining subclaims.

A preferred embodiment of a gloss device for cobalt-chrome dental casting alloys is characterized in that a fuzzy processor is provided. By using such a The processor is suitable for the cobalt-chrome dental casting alloys minimal time to shine and thus minimize the electrolyte consumption.

The use of the method or of the shining device has proven to be particularly advantageous Shine of cobalt-chrome dental casting alloys proven.

The invention is explained in more detail in the following appendix to the drawing. It shows

Fig. 1 is a block diagram of a Glänzgeräts,

Fig. 2 is a diagram illustrating the implementation of the method for polishing of cobalt chrome Dentalgußlegierungen,

Fig. 3 membership functions of the linguistic variables at the inputs and

Fig. 4 membership functions of the linguistic variables at the outputs.

Fig. 5 fuzzy rules.

Fig. 1 shows a schematic block diagram of an electrolytic Glänzgerätes 17 mix for electrochemical polishing of cobalt-chromium-Dentalgußlegierungen sixteenth The gloss device can be connected to a suitable power supply. The tapped voltage is smoothed by a rectifier 18 and a filter circuit 19 and fed to a current control 14 , which is implemented by pulse width modulation (PWM). Their output signal is then fed via the gloss electrodes 22 to the cobalt-chromium dental casting alloys 16 fastened in a gloss bath 23 . The cobalt-chrome dental casting alloys 16 are connected to a motor 11 via a linkage and can be moved in the gloss bath 23 . The motor 11 is connected to the microcontroller 1 via a relay 25 and can be switched on and off via it. For current measurement 12 of the current flowing in the gloss bath 23 , the voltage across the measuring resistor 21 is measured and fed to the microcontroller 1 . The polishing unit 17 includes a heating and cooling apparatus 10 9 which are also connected via relay 25 to the microcontroller 1, whereby the single heating or cooling, and may be turned off. The heating device 9 heats electrically. The cooling device 10 includes a valve 26 which is connected to the relay 25 and is controlled thereby. The cooling device 10 consists of a line system 27 which is connected to the external water supply. Of course, the heating and cooling devices are chosen here only as examples. Their definition can be adapted to the corresponding environmental conditions. The gloss bath 23 is provided with a temperature resistor 24 , the voltage drop of which is measured 13 and also supplied to the microcontroller 1 .

An EPROM 3 , which contains the fuzzy logic control, is connected to the microcontroller 1 . Furthermore, the current flowing through the cobalt-chrome dental casting alloys 16 , the temperature of the glossy liquid and the pushbutton 7 are connected to the microcontroller as input signals. As output signals, the current control 14 , the relays for controlling the heating 9 , the cooling 10 and the motor 11 as well as LEDs 8 and a display 6 are connected. The states of the glossing process are output on the display 6 . Furthermore, external inputs can be made on the control via the button 7 . The microcontroller 1 is also connected to accumulators 5 (quiescent current supply) in order to supply the microcontroller with current after the mains supply voltage has been switched off. This allows him to save the quality of the glossy liquid and other states even after the mains voltage has been switched off.

The input signals are picked up by the microcontroller 1 and processed for further processing. The time derivative of the temperature and the current is generated. In addition, the signals are smoothed during signal processing in order to ensure further error-free processing. The microcontroller 1 , or its fuzzy logic control, calculate the optimal current density and the gloss time on the basis of the maximum current in the gloss bath, the temperature of the gloss liquid and / or the derivation of current and temperature according to the time and the state of the gloss liquid . The surface of the cobalt-chromium dental casting alloy and the number of cobalt-chromium dental casting alloy are determined from the maximum flowing current. The microcontroller also regulates the temperature of the glossy liquid.

The method for glossing cobalt-chromium dental casting alloys is explained in more detail with reference to the functional diagram shown in FIG. 2.

When the polishing device 17 in FIG. 1 is started up, the polishing process is started in a first step 31. First of all, an initialization takes place, which serves to put the glossing device into a ready-to-use state.

In a second step 33, it is determined on the basis of the stored electrolyte state that whether the electrolyte is still usable. If not, the electrolyte must be replaced in step 35 become. The serviceability of the electrolyte is determined by taking up the electrolyte mene current over time is integrated (charge) and it is checked whether this value is a maximum exceeds the specified value.

If this is not the case, it is determined in step 37 whether cobalt-chromium dental casting alloys in the Glossy bath are attached. If there are no cobalt-chromium dental casting alloys in the gloss bath, so must be attached in step 39. A voltage is applied to the electrodes for checking  created. If there are no cobalt-chrome dental casting alloys attached, no current can flow. For The current supplied must be recorded and its derivation formed.

In step 41 it is checked whether the temperature of the glossy bath is in the working area. If this is not the case, the temperature is brought into the working area in step 43 using fuzzy rules 4-6 ( FIG. 5) by heating or cooling. To do this, the measured value of temperature must be recorded and its derivation formed.

If the temperature is in the working range, the number and the surface of the cobalt-chromium dental casting alloy are determined in step 45. For this purpose, the maximum voltage is set on the PWM (pulse width modulation) 2 ( FIG. 1) for 30 seconds. The number and surface area of the cobalt-chromium dental casting alloys can be determined in a suitable manner from the resulting maximum current.

In the subsequent step 47, the gloss time t _max and the control voltage to be applied to the PWM 2 are determined from the number and surface area of the cobalt-chrome dental casting alloy with the aid of fuzzy rules 7-16 ( FIG. 5), in order to set the optimum current density . The fuzzy rules determine a basic gloss time on the basis of the number and surface area of the cobalt-chromium dental casting alloys. This basic gloss time is increased depending on the state of the electrolyte (fuzzy rules 13-16 , Fig. 5).

Furthermore, the cobalt-chromium dental casting alloy t _max seconds is shined at an optimal current density, it being checked in step 49 whether the determined gloss time t _{max has been} exceeded. If this is not the case, step 51 checks whether the temperature is in the working range. If this is not the case, the temperature is brought into the working area in step 53 using fuzzy rules 4-6 . According to the fuzzy rules 1-3, no voltage may be applied to the electrodes. If the temperature is in the working range, the control voltage is applied to the electrodes in step 55 and the timing is increased. The value of the charge taken up by the electrolyte during the glossing process is stored in the RAM of the microcontroller 1 ( FIG. 1).

From Fig. 1 it can be seen that the microcontroller with fuzzy logic control processes various input signals and adjusts the output signals accordingly. The inputs and outputs leading from the control unit are also designated.

Fig. 3 shows the inputs for the so-called linguistic variables and their fuzzy sets and membership functions. From top left to bottom right, these are the temperature of the glossy liquid, the surface of the cobalt-chrome dental casting alloy, the number of cobalt-chrome dental casting alloys and the condition of the electrolyte. The membership of a certain value on the x-axis to a fuzzy set, which is defined by the membership function, is always in the interval [0,1]. The corresponding division and the designation of the fuzzy sets or membership functions for the inputs can be found in FIG. 3.

Fig. 4. shows the linguistic variables and their membership functions for the outputs. From the top left to the bottom right, these are the gloss time, the increase in the gloss time, the size of the control voltage for the current density, the switching on of the voltage, the heating and the cooling. The corresponding classification and the designation of the fuzzy sets or membership functions for the outputs can be found in FIG. 4.

Of course, the numerical values for the areas of membership functions are only here chosen as an example. They can be fixed to the shiny cobalt-chrome dental casting alloys be adjusted.

By using the fuzzy logic it is possible to determine the gloss time and the optimal current density on the Basis of the temperature, surface, number and condition of the electrolyte adjust. It is possible to acquire knowledge from experienced operators and in the form of Fuzzy rules, linguistic variables and their membership functions on the microcontroller map. By linking terms, for example the number and the surface of the Cobalt-chrome dental casting alloys, as well as taking into account the electrolyte state is on everyone Case ensured that under different conditions always an optimal current density is set so that a uniformly good gloss is achieved with minimal consumption of electrolyte becomes.

Preferably, the measured values of the current and the tem temperature and their time derivative over several measurement cycles are averaged to one if possible to ensure an even shine.

By recording the various boundary conditions, an automatic Shining process minimizes the shining time and the quality of the cobalt-chrome dental casting alloys be improved.

From the above it is readily apparent that both the method and the explanation tert glossing device are very well suited for the glossing of cobalt-chrome dental casting alloys.

Claims (13)

1. A process for the shining of cobalt-chromium dental casting alloys, in which the current flowing in the shining bath, the temperature of the shining liquid and / or the derivation of current and temperature are measured over time and the condition of the shining liquid, the surface of the cobalt Chromium dental casting alloys and the number of cobalt-chromium dental casting alloys are determined in order to set the optimum current density, the temperature and the gloss time, characterized in that the measured values are linked to one another in the manner of the fuzzy logic control. 2. The method according to claim 1, characterized in that the respective electrolyte state ge is stored and the current, the temperature and their derivation after the time recorded and, based on the maximum current and electrolyte state, the surface and the number of cobalt-chrome dental casting alloys can be determined. 3. The method according to claim 1 and 2, characterized in that the cases "temperature low rig", "temperature normal" and "temperature high" are distinguished in order to turn the gloss process and the motor ( 11 ) on and off and continue to A distinction must be made between "temperature too low", "temperature medium" and "temperature too high" to switch the heating and cooling on and off. 4. The method according to any one of claims 1 to 3, characterized in that the cases "number of cobalt-chrome dental casting alloys one "and" number of cobalt-chrome dental casting alloys two "as well as the cases" surface of the cobalt-chrome dental casting alloys very much small "," surface of the cobalt-chrome dental casting alloys small "," surface of the cobalt Chrome dental casting alloys medium large "," Surface of the cobalt chrome dental casting alloy large "and" surface area of the cobalt-chrome dental casting alloys very large " be divorced. 5. The method according to any one of claims 1 to 4, characterized in that the cases "Electrolyte state bad", "Electrolyte state good", "Electrolyte state medium" and A distinction can be made between "bad electrolyte state". 6. The method according to any one of claims 1 to 5, characterized in that the number and the Surface of the cobalt-chrome dental casting alloys based on the maximum Current and the electrolyte state can be measured. 7. The method according to any one of claims 1 to 6, characterized in that the state of Electrolyte is determined from the charged charge and stored. 8. Shining devices for cobalt-chrome dental casting alloys with means for detecting the current and / or the temperature in the shining bath and with a control unit influencing the shining process, in particular for carrying out a shining process according to one of claims 1 to 7, characterized in that the Control unit ( 27 ) is designed so that the variables relevant to the gloss process according to the type of fuzzy logic control for setting the current ( 14 ), the heater ( 9 ), the cooling ( 10 ) and the motor ( 11 ) can be linked are. 9. Shining devices according to claim 8, characterized in that in the control device ( 27 ) the current and temperature and their derivation are associated with the signals associated with each other. 10. Gloss devices according to claim 8 and 9, characterized in that current and temperature in several successive measurements are detectable and preferably indirect. 11. Gloss devices according to claim 8 to 10, characterized in that the control device ( 27 ) is designed with a microcontroller ( 1 ). 12. Gloss devices according to claim 8 to 11, characterized in that the control device ( 27 ) is designed with a fuzzy processor ( 1 + 3 ). 13. Use of a gloss device according to one of the preceding claims 8 to 12 for Shine of cobalt-chrome dental casting alloys.