EP0185311A2 - Method and apparatus for controlling an electrostatic coating system - Google Patents

Abstract

When electrostatically coating large workpieces such as To avoid a voltage breakdown, vehicle bodies must be switched off automatically when the operating current rises to a threshold value which is predetermined as a function of the operating voltage which can be adjusted within a certain range. For this purpose, all the threshold values applicable to the selectable voltage values are stored together, in particular in a microprocessor, and are automatically selected during operation in accordance with the voltage set in each case.

Description

The invention relates to a method according to the preamble of claim 1 and an apparatus for performing the method.

In the electrostatic coating of workpieces, which are usually brought into a spray booth or other coating station by an automatic conveyor system and moved there relative to one or more paint atomizers, a high voltage is applied between the workpiece and each atomizer, the size of which takes into account the respective operating conditions ( Workpiece, paint type, air conditions, etc.) must be adjustable, in the case of vehicle bodies approximately between 60 and 110 kv. For safety reasons, it must be absolutely prevented during coating that the electric field strength can reach a value at which there is a risk of voltage breakdown or spark discharge. The breakthrough field strength is achieved with an impermissible reduction in the distance between the atomizer and the workpiece, that is to say with unstable workpiece guidance or, in the case of vehicle bodies mentioned, in particular when an unintentional opening of Doors and hoods. Since there is no practically usable method for directly measuring the field strength in a coating system, the operating current of the high-voltage source is instead monitored and the system is automatically switched off when a predetermined current threshold is reached, and experience shows that there is a risk of breakthrough if exceeded. Since the current flowing between the high-voltage electrodes rises steeply immediately before the breakdown field strength is reached, the risk of breakdown can be excluded as long as the operating current does not exceed the normal value measured at the start of operation by more than a predetermined amount. Accurate and reliable setting of the respective current threshold is associated with considerable difficulties because the operating current does not change linearly with the voltage, especially in the upper part of the range of selectable voltage values, and because the measured operating current is only partly the current flowing between the electrodes, but otherwise consists of additional components such as a shunt current flowing from the high voltage source via the paint supply system. The shunt current can already be significantly higher than the electrode current at the start of operation and also gradually increase during operation, for example as a result of increasing contamination of the shunt path. However, its size is not a measure of the field strength to be monitored; on the other hand, it is not readily possible to measure only the electrode current.

According to a currently customary method, in an electrostatic coating system for vehicle bodies, the high voltage of which can be changed step by step using a step switch, for example in 5 steps of 10 kV, the normal operating current for the voltage level selected in each case is measured and assigned to one of the voltage levels potentiometer, an associated current threshold is set by hand, which is a certain amount higher than the measured normal current. If the voltage changes, the process is repeated with another potentiometer assigned to the new voltage level. This method is unsatisfactory for several reasons. First of all, it would be desirable to be able to change the voltage in substantially smaller steps or virtually continuously, but this cannot be achieved with the usual method, since the number of selectable voltage stages would also increase the potentiometer assigned to them, which are not only complex, but would also take up too much space. It should be taken into account that usually several atomizers working at the same time are installed in a coating station and the high-voltage field of each atomizer requires its own monitoring. If, for example, 10 atomizers are available and if their respective operating voltage can be changed between 60 and 110 kV in 1 kV steps, a total of 500 potentiometers would have to be installed. Another disadvantage is the difficulty and possible unreliability in the manual setting of the potentiometers that determine the current threshold, which must also be protected in lockable control cabinets or in some other way against unauthorized adjustment. Finally, there may be undesirable interruptions in operation if the current threshold is reached without the risk of a breakdown simply as a result of increasing contamination of the mentioned shunt path or due to other relatively slow changes in operation (heating, air change, etc.) without the operating personnel being informed in good time.

From DE-OS 27 34 341 a current monitoring system for a system for the electrostatic coating of vehicle bodies with a continuously selectable voltage is known, in which the _S icherheitsabschaltung only with rapid current changes due to dangerous approach of body parts to the atomizer at high voltage, not to be triggered at a slow current change but as it is possible as a result of gradual contamination of the plant. For this purpose, the operating current is measured at short time intervals (every 200 ms) with the aid of a sample and hold circuit, the measured value is compared with the previous measured value stored as a reference value, and finally the current measured value is stored as a new reference value. The reference value, with which the operating current is constantly compared, therefore increases with the gradually increasing operating current. If the current increases by more than a certain adjustable difference value within the specified time interval, the shutdown is triggered. But also in this known system, which has a relatively complex circuit arrangement, in addition to the dynamic current monitoring, a predetermined limit current value, which must not be exceeded under any circumstances, is set manually by the operating personnel. Furthermore, as with the known step method, there is also no possibility of a warning for the operating personnel if the operating current approaches the static limit value, for example due to increasing contamination of the system, at which the interruption in operation is triggered, although there is no risk of breakthrough.

The invention is based on the object of enabling an automatic adaptation of the switch-off threshold to the respectively selected voltage in the case of a safety shutdown for a system with high voltage which can be changed in the smallest stages without excessive effort.

This object is achieved by the invention characterized in the claims.

The invention eliminates the manual setting of the switch-off threshold and its likewise manual voltage-dependent change using a large number of potentiometers.

According to the invention, there is also the possibility of pre-warning the operating personnel when the operating current approaches the switch-off threshold as a result of changing operating conditions which do not lead to an increased risk of breakthrough.

• _Fig. 1 den Stromverlauf in Abhängigkeit von dereinstellbaren Betriebsspannung einer elektrostatischen Beschichtungsanlage für Fahrzeugkarosserien; und
• _Fig. 2 eine schematische Darstellung einer Anordnung zur Betriebsüberwachung der Beschichtungsanlage.

The invention is explained in more detail below using an exemplary embodiment. The drawing shows:

• _F ig. 1 shows the current profile as a function of the adjustable operating voltage of an electrostatic coating system for vehicle bodies; and
• _F ig. 2 shows a schematic representation of an arrangement for monitoring the operation of the coating system.

If you measure the operating current I _{B of} the high-voltage source in the spray booth, for example of an electrostatic coating system for vehicle bodies supplied in series by an automatic conveyor system, depending on the high voltage freely selectable in the range up to, for example, 110 kV between the spraying device and the body to be coated, typically one obtains that 1 curve for this current I _B. It essentially consists of two components, namely a shunt current IN, which flows from the high-voltage source to the earth bypassing the spray device (conventionally at high-voltage potential) via its paint supply line and other shunt paths, and the one to be added to this in Fig. 1 the vertical distance between the curves of the currents IN and I _B corresponding electrode current between the spray device and the workpiece. Neither the electrode current nor the shunt current IN can be easily measured individually. The curves of the currents IN and I _B apply to a given electrode distance between the workpiece and the spraying device and for normal operation conditions. In reduction of the electrode spacing of the electrodes current and therefore the operating current would I _B to a breakdown value rise of the curve (not shown) as a function of the set voltage to a similar located as the operating current itself. In order to avoid the _D urchbruchgefahr it is well known, required switch off the high-voltage system when a predetermined current threshold is reached in accordance with curve I _AS . But even without changing the electrode spacing, i.e. without the risk of breakdown, the operating current I _B can increase significantly during operation, namely by reducing the shunt resistance to earth with a corresponding increase in the shunt current IN, for example as a result of increasing contamination and / or by other changes. This increase, for example, to the curves I _N 'and I _B ', for which the switch-off curve I ' _AS would then apply, can lead to a disruptive, but practically unavoidable, interruption in operation during the coating process in the known systems.

Furthermore, voltage / current curves which run significantly differently can also result for changed normal conditions, for example for other electrode normal distances or other paint types. In the case of different types of lacquer, which can differ greatly in terms of their electrical resistance, the normal operating current can correspond, for example, to the curve of the current I _B in one case and to the curve I ' _B in FIG. 1 in the other case.

According to the monitoring method described here, the resulting value of the operating current I _{B is} measured under normal conditions for each of the selectable voltage values, which are preferably set in small steps of, for example, 1 kV or 0.5 kV, that is to say virtually continuously, before the actual coating operation begins . The operating current values are preferably binary coded and fed to a microprocessor μP (FIG. 2), which calculates the current threshold values belonging to the various voltage values according to curve I _AS by enlarging them by a predetermined amount (for example by 30%). Here, the measured in a data memory of the microprocessor stored operating current values and / or the threshold values calculated therefrom and accordingly the calculations are carried out before, during or after the storage, or possibly only when the data is subsequently output.

The values of different, for different normal conditions such as e.g. Different varnish types of applicable voltage / current curves are saved and later selected according to the applicable conditions.

Regardless of the other possibilities mentioned, it makes sense to immediately store the threshold values calculated by the microprocessor. For reading, the memory can be addressed by a binary code supplied at A (FIG. 2) and corresponding to the voltage value selected in each case. During the coating operation, the read bits of the threshold value, which also consists of a binary code, are fed in parallel to a binary comparison switch (not shown) which is contained in the control circuit ST and which, at its other inputs, carries the bits of an operating current measured in parallel by an A / D converter I _is receiving corresponding further binary codes. When the operating current I _{has reached} the stored threshold value, the microprocessor controlled by the comparison switching mechanism generates a switch-off signal Ab for the high-voltage source HS.

The microprocessor can receive commands from a higher-level process controller, which include an on / off signal, the selected voltage at input A, a "change" signal for controlling the transfer of the voltage code at input A from a data bus of the process controller and at an input W signals for the selection if necessary _. stored different voltage / current curves. On the basis of the voltage code at input A, the microprocessor in turn can forward a corresponding analog control signal U _soll to the high-voltage source HS via a D / A converter. Furthermore, the microprocessor can receive fault messages from the high-voltage source HS or generate them for process control.

In Ig.1 _F I _B and the trip curve lAS is another curve I shown _ZS between the curve of the operating current. These are intermediate threshold values which, like the switch-off threshold values according to curve IAS, are calculated by the microprocessor on the basis of the initially measured normal values of the operating current I _B , stored and constantly compared with the actual operating current I _ist . If the intermediate _{threshold values} of curve I _{ZS are} exceeded (which may be 15% higher than the normal operating current I _B ), however, the high-voltage source HS is not switched off, but an acoustic and / or optical warning signal for the operating personnel only at the output V of the control circuit ST generated. This gives the operating personnel the opportunity to check the system if the operating current increases gradually at a suitable point in time, such as after a body has been completely coated, and if necessary, to restore normal operation before continuing the coating operation in the event of advanced contamination or other relatively slow changes in operation. This makes it easy to avoid surprising interruptions in operation at an unfavorable time, which would not be necessary due to the risk of breakthrough. The warning area corresponding to the vertical distance between the curves I _ZS and I _AS in FIG. 1 is so large that the personnel have enough time to wait for a suitable time for the check.

If the operating current I _B , which is only valid for certain normal conditions, and consequently the curves I _ZS and I _AS, which are based thereon, change due to changed operating parameters, such as, in particular, another coating material whose influence on the operating current is known, it is not absolutely necessary to restart the operation to determine normal operating current values by measuring. In such cases, the calculator is a lot more possible to calculate the now applicable threshold values yourself and save different curves for the different operating parameters. The different curves are selected as required by the signals at input W already mentioned.

In the case of the device described here, the personnel still have other verification options that have not existed to date. In particular, a display device AZ controlled by the computing and control circuit ST is provided, with which the operating current I measured in each case _, together with the stored threshold values associated with the respectively selected high voltage, and also the actual voltage U _{ist can be} optically displayed. The actual values are converted into binary information by A / D converters. The display device can be a digital display device and / or a display device in the form of a monitor, to which the information to be displayed is supplied in the form of parallel bits at the output Z of the control circuit ST. For this purpose, the control circuit receives command signals at input _B to output the desired information. The operating personnel can therefore get an idea of the respective operating state, especially when the warning signal appears at the output V.

_D a for each existing atomizer whose own high voltage is to be monitored, it is expedient to install a circuit board for each atomizer, which is equipped, among other things, with the microprocessor .mu.P and the control circuit ST containing integrated circuits and can be implemented with little effort.

The system described here of automatically adapting a switch-off current threshold to the voltage selected in each case can be easily combined with other safety switch-off systems, in particular with the system known from the (mentioned above) DE-OS 27 34 341. Accordingly, it may be necessary to switch off the high voltage of the coating system before the shutdown current threshold is reached, namely, for example, if the current changes faster, ie within a given period of time, by a larger amount or percentage than is permissible for safety reasons.

Claims (7)

1.Procedure for monitoring the operation of an electrostatic coating system operated with an optionally changeable high voltage for large workpieces, in particular supplied by an automatic conveyor system, such as vehicle bodies, the normal operating current of the high-voltage source and a higher current threshold being determined for the various selectable high-voltage values If there is a risk of a voltage breakdown between the coating system and the workpiece, and then the operating current is continuously measured during coating and the high voltage is automatically switched off when the current threshold that is dependent on the selected high voltage is reached,
characterized,
that the current normal values measured before coating for the respective voltage values and / or the threshold values determined on the basis of the normal values are stored together, and that the operating current measured during the coating is compared in each case with the stored value automatically selected in accordance with the set voltage. 2. The method according to claim 1, characterized in that the normal or threshold values of the current are stored as binary data, and that the current threshold values are calculated digitally from the normal values. 3. The method according to claim 1 or 2, characterized in that an intermediate threshold value lying between the normal value and the switch-off threshold value is automatically set on the basis of the stored values as a function of the selected voltage values, and a warning signal is generated if these are exceeded. 4. The method according to any one of claims 1-3, characterized in that the respective normal or threshold values for different varnish types or other operating conditions are stored together and the stored values are selected on the basis of the conditions applicable in operation. 5. Device for performing the method according to any one of claims 1-4, characterized in that a computing and control circuit (ST) is provided which has a microprocessor (gP) and a memory addressable by the selected high voltage values for the predetermined normal values and / or contains threshold values corresponding binary data, and that a binary comparison circuit is connected to the data outputs of the memory, to which the measured operating current (I _ist ) _is fed via an A / D converter. 6.) Device according to claim 5 for performing the method according to claim 3 or 4, characterized in that the memory contains both the intermediate threshold values and the switch-off threshold values as binary data calculated on the basis of the measured normal values, and that the control circuit (ST) on the basis of the Comparison with the measured current (I _ist ) when the respective intermediate threshold value _is reached or exceeded, the warning signal (output V) for the operating personnel and when the respective switch-off threshold value _is reached, the switch-off signal for the high-voltage source (HS) is generated. 7.) Device according to one of claims 2 to 5, characterized in that a display device (AZ) controlled by the computing and control circuit (ST) is provided with which the respectively measured operating current (Iactual) and the high voltage selected in each case belonging stored threshold values are optically displayable.

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