DE2309518A1 - MEASURING ARRANGEMENT FOR DETERMINING ELECTRICAL PARAMETERS OF BINDERS FOR ELECTRIC DIP PAINTING - Google Patents

Description

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Johannesgasse H (Austria)

Measurement set-up for determining electrical parameters of binders for electrodeposition

The invention relates to a measuring arrangement for determining electrical parameters of for Electrocoating binders used. This makes it possible to use the main electrical Determine parameters of binders that are used for the electrodeposition process quickly and reliably. These parameters include the electrodeposition equivalent (or Goulomb yield), the measurement the peak currents occurring at the beginning of the separation as well as the measurement of the electrical energy used for the coating.

The meaning of these key figures is in the following In-rz summarized:.

Dnπ electrochemical deposition equivalent indicates what amount of charge has to be expended in order to deposit one milligram of a binder (Cb / mg). The reciprocal is called

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Coulomb yield called. From this the economic efficiency the separation, but also the degree of neutralization of the resin. The measurement for Production control, i.e. to determine deviating cookings with e.g. higher and lower acid numbers or Presence of foreign electrolytes.

Knowledge of the peak current occurring at the start of the coating is of decisive importance when comparing EC resins under different conditions, or is used for Determination of the critical current density at which the film breaks up during the coating.

The peak current is also used for sizing electrical Systems important (rectifier elements, thyristors, surge current load from electrical systems such as laboratory rectifiers i.a.).

Knowledge of the electrical required for coating Energy allows the calculation of electricity costs as well as the costs of installing ETL systems such as transformers and cooling systems.

The Coulomb measurement, i.e. the metrological determination of the The amount of charge that has flown has hitherto been associated with great difficulties. When coating under constant tension, If there is a current peak at the beginning of the deposition and then a rapid current reduction, whereby one can speak of an exponential decrease in the current flow. The classic method of measuring coulombs with the help of the silver coulometer had to be eliminated from the outset. because the silver deposition at the high currents that occur (up to 20 A for surfaces of 200 cm to be coated) is measured technically light e ^ skterfaßbar and the evaluation of the measurement results cumbersome and is time consuming.

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As another method of measurement, the XY recorder offered, which registers the current change on a running strip of paper. Here, however, it was found that the mechanical recording of the current / time curve is too slow, so that the first deposition phase is only recorded imprecisely. In addition to the one was forced by cutting out the curve, and weighing the paper weight in comparison with the paper weight Coulombmengen known to determine the number of the flown Coulomb, wherein a measurement error was up to 10% can not be avoided.

In the case of integrating recorders, the laborious cutting out and weighing were no longer necessary, but the mechanical inertia of the writing system still had to be taken into account and a source of error that should not be neglected, since such a recorder needs at least 1 second to reach the maximum deflection.

A frequently used method to determine the number of Coulomb by deposition under constant current, has the disadvantage that the film is built up under fundamentally different conditions. The measurement time is also limited, because as the coating due to the building up insulating paint film Abscheidvmgs- the voltage increases until it comes to leave the film on exceeding a certain voltage, and thereafter no deposition defined more.

The measurement of the peak current occurring at the beginning of the coating process is associated with particular difficulties , since after a short time the current inflow is extremely greatly reduced by the film resistance that builds up. Experience shows that with normal voltages the deposition current only reaches half of its initial value after 2-3 seconds of coating time. An exact measurement of this peak current could only be made with the help of a memory oscilloscope , which alone is capable

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one-off processes, such as deposition of EDL binders on the screen. The recording of the change in current with the electron beam a Oscillograph tube is almost inertia. However, it is working with such an oscilloscope very complex and time-consuming and requires trained personnel. Apart from that, oscillographic peak current measurements can only be carried out with a stabilized DC voltage, since the half-waves of the rectified AC voltage of a rectifier commonly used for ETL coating of almost the same The order of magnitude of the duration of the peak current itself (half-wave width 10 msec, peak current duration 200 100 msec).

The energy to be used for coating can be derived from the deposition voltage and the amount of coulomb that has flowed be determined. This is problem-free in the case of a coating under constant DC voltage. One has however, there is almost never one available, because of the high voltages and currents involved in the ETL coating occur, the necessary equipment is much too expensive. In addition, there would be a deposition below such prerequisites far too little practical.

Some of the rectifier systems in use have internal resistances and cannot be neglected in addition, voltage and current distortions occur that cannot be detected with volt and amp meters, if the electrical regulation takes place via a thyristor control. In practice, therefore, the electrical energy that is expended in the coating can only be determined approximately.

It is the object of the present invention to develop a measuring arrangement or a measuring method which corresponds to those mentioned Does not have any disadvantages and allows a quick and precise determination of the mentioned + e ^ sizes.

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The invention consists in that, in order to achieve digital measurement results, a measuring arrangement consisting of a measuring resistor Ry (1), a voltage-frequency converter (2), associated counting unit (3), buffer unit (A) and display unit (5) for display the Coulomb yield, a timing element (6) to interrupt the pulse sequence coming from the voltage-frequency converter (2) after 50 - 100 msec, an associated counting unit (7), buffer unit (8), display system (9), a multiplier stage (11) which multiplies the voltages occurring at the measuring resistor Rj (1) and at the voltage divider Ry _S (10) with one another in an analog manner; a voltage-to-frequency converter (12) is turned on for the conversion of the analog product of the multiplier stage (11) in pulses, a counting unit (13), an intermediate storage unit (14) and a Status indicators system (15) in the Abseheidungsstromkreis.

Purely for the measurement of the various variables, in all cases the signals analogous to the change in current or voltage over time are converted into pulses, which are then counted and stored. As an analog signal, a voltage changing with the time change of the current at a measuring resistor is chosen. This is then used to control the feedback of a square wave generator in such a way that the frequency of its pulses is proportional to the voltage and thus to the current.

The impulses are counted, saved and visibly mowed on digit display eyes. Thus, the quantity of electricity in coulombs, the aufrretene peak current in amps or the applied power can be read in Watt seconds immediately on conclusion of the measurement. These values can also be processed directly and used for process control by controlling control loops or by feeding them into a computer.

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The following are the individual measuring functions of the device explained on the basis of the block diagram (Fig. 1).

a) Coulomb measurement

The voltage drop across the measuring resistor R _T (1) generates a frequency-proportional pulse train in the DC-AC converter (2). The negative pulses appearing at the output of the converter are converted into positive pulses in a gate, then counted in decimal counter units, consisting of decimal counters (3), buffers (4), decoders / drivers and display tubes (5) and the sum is recorded after the measurement has been completed . The counting frequency is advantageously chosen so that a charge amount of 1 coulomb, corresponding to a preselected voltage drop across the measuring resistor R (1), corresponds to a frequency of 100 Hz. The smallest amount of charge displayed is therefore 0.01 coulomb.

b) Peak current measurement

The peak current measurement is based in principle on the same method as the Coulomb measurement. The at the measuring resistor R (1)

The falling voltage generates pulses in the converter (2) and these are counted. In contrast to the Coulomb measurement, however, the counting process is aborted after 50 - 100 msec. The meter that appears on the display system now shows the amount of charge that has flowed in the first 50-100 msec. This amount of charge (coulomb) that has flowed in the first 50-100 msec is the peak current to be multiplied by a factor of 10. At a selected frequency of 100 Hz per 1 Asec a peak current of 1 A corresponds to one displayed on the display system 10. The smallest peak current which can be detected is 100 mA. The time constant of 50 - 100 msec was chosen because Spitzensti'ommessungen have shown by means of a storage oscilloscope that the duration of the peak current in the order of 50 - located msec 200th

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The timing element (6) works in the following way: Before starting the measurement, a bistable multivibrator must be put into the state that the potential 1 (= + 5 V) appears at its output. The input of a gate is opened by this potential. If the current begins to flow at the measuring resistor R _T (1) and the first pulse appears at the output of this gate, it can switch on via another gate and a monostable multivibrator. This jumps at its output from potential O (= OV) to 1 and thus opens a third gate. The distance between the 1st gate and 3rd gate is therefore permeable for the time for which the monostable multivibrator was set (50 msec) for the impulses coming from the converter (2) and these with decimal counters (7), intermediate storage (8) , Decoder / driver and display tubes (9) are counted.

However, to prevent the monostable multivibrator from being switched off by a new pulse coming from the input is switched on again, the first pulse that was used to switch on is used to activate the to switch bistable multivibrator so that the 2nd gate is blocked for further pulses. A new commissioning the timer (6) can only be done externally by pressing a button.

c) Energy measurement

The energy measurement takes place in such a way that with the help of a multiplier stage (11) the deposition current and -voltage proportional, at the measuring resistor R (1) and at

Voltage divider R ^ (10) falling voltages with each other be multiplied. The product, which is again in the form of a voltage at the output of the multiplier stage (11) appears, is converted in a converter (12) into pulses, which in decimal counter units consisting of decimal counters (13), buffers (14), decoders / drivers and display tubes (15) are counted and the total after completion of the measurement is being held.

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The energy measurement level can ζ. B. be designed so that a Energy of a maximum of 6000 W.s per second corresponding to a voltage of 300 V and a current of 20 A measured can be. The lowest measurable energy is 10 W.s per second. In order to achieve these measured values, an input " the multiplier stage (11) with the measuring resistor R (1)

connected, the other connected to a voltage divider R _TTC (10)

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closed. The current is measured at the measuring resistor R (1) and the voltage is measured via the voltage divider R _n "(10).

The energy measurement is carried out according to the method according to the invention with the elimination of voltage fluctuations and distortions due to the internal resistance of rectifier systems and sawtooth pulses, which occur with thyristor controls.

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Claims (1)

Claim Measuring arrangement for determining electrical parameters for electrodeposition painting binders used, in particular the deposition equivalent, the peak currents and the energy required for coating, characterized in that to achieve digital measurement results a measuring arrangement consisting of a measuring resistor Rj (1), a voltage-frequency converter (2), associated counting unit (3), intermediate storage unit (4) and display unit (5) for displaying the Coulomb yield, a timing element (6) for interruption the pulse train coming from the voltage-frequency converter (2) after 50 - 100 msec, an associated one Counting unit (7), intermediate storage unit (8), display system (9), a multiplier stage (11), which the measuring resistor Rj (1) and the voltage divider Rgg (10) occurring tensions with each other multiplied analogously, a voltage-frequency converter (12) for converting the analog product the multiplier stage (11) in pulses, a counting unit (13), a buffer unit (14) and a display system (15), switched on in <fen deposition circuit will. 309841/0790 Blank page