DE2929601A1 - High voltage transformer for ozone producer - has output from current inverter fed to prim. to control prodn. rate - Google Patents

Abstract

In appts. for the prodn. of ozone supplied with high voltage by the sec. winding of a transformer, the prim. winding is fed with a pre-selected constant current from a line-commutated controlled rectifier, and also with the output from a current inverter with associated starter and electronic control circuits. This latter control circuit is connected with devices for measuring one or more ozone prodn. parameters, and maintains the optimum settings. The amt. of ozone produced is simply and reliably controlled.

Description

Feed device for an ozone generator

The present invention relates to a feeding device for an ozone generator, which has a high-voltage transformer, its secondary winding is intended to feed the ozone generator.

It is well known that ozone is produced, among other things, by electrical discharges. Ozone generator mostly have plate-shaped or tubular electrodes with at least one Dielectric and air gap. For ozone production a Electricity supplied, with the ozone output at higher voltages and during operation increases above the grid frequency. Furthermore, the ozone output is on the one hand from the construction of the ozone generator itself, but also from the Current / voltage characteristics of its feed dependent.

There are basically different current and voltage sources for higher operating frequencies known (see Der Elektronikiker, 1971, issue No. 3 and 4, Pp. 117 ff. And 179 ff.). The known circuits are mostly with power thyristors realized.

The invention specified in claim 1 is based on the object to provide a feed device for an ozone generator, which is a simple and allows safe control of the amount of ozone to be produced.

The advantage of the invention is that the network-based, controlled Rectifier regulates a constant current in the direct current circuit, the controlled Inverter can be adjusted to the amount of ozone to be produced.

Advantageous further developments of the invention are set out in the subclaims described.

The embodiment according to claim 2 enables the current in the direct current circuit adapt to the ozone generator.

The development according to claim 3 shows an advantageous possibility the control electronics of the inverter are directly dependent on the ozone concentration to design.

The embodiment according to claim 4 also enables other process variables to consider.

The development according to claim 5 improves the operation of the Device, since the choke with the line-commutated, controlled rectifier one Generated impressed direct current, which has only a slight ripple.

The embodiment according to claim 6 describes an advantageous embodiment of the inverter.

The invention is described below with reference to schematic drawings explained in more detail.

1 shows a first exemplary embodiment of the inventive Feeding device in which the ozone concentration is measured, FIG. 2 a second embodiment of the feed device according to the invention, for example, in which a process computer is used, FIG. 3 shows an equivalent circuit diagram of an ozone generator, FIG. 4 shows the current profile at the output of the feed device and FIG. 5 shows the voltage profile at the output of the feed device according to the invention.

According to Fig. 1 is a line-commutated, controlled rectifier 1 designed single-phase. of course, this can also be known per se Way e.g.

three-phase or six-phase. The rectifier 1 is connected to an inverter 2, which is used as a thyristor inverter in Bridge circuit is designed. Between the rectifier 1 and the inverter 2, a throttle 3 is switched on, which is used to smooth the current.

The inverter 2 consists of one in this exemplary embodiment Bridge circuit with four thyristors 2.1 to 2.4. A high voltage transformer 5 is with its primary winding 5 'with the output of the inverter 2 and with its secondary winding is connected to an ozone generator 6. The thyristors 2.1 to 2.4 are ignited with the control electronics 7, which on the one hand itself the starting unit 4 and on the other hand by a device 8 for ozone target-actual comparison is dependent.

This device 8 is controlled by an ozone concentration meter 9 and controlled by a device 10 for ozone setpoint preselection. One device 11 for current-target-actual comparison with a device 12 for an adjustable current target value preselection provided and connected to the rectifier 1. This is the output voltage adaptable to the requirements of the ozone generator 6.

In Fig. 2, the same parts are provided with the same reference numerals as in FIG. 1. In this embodiment, however, a process computer 13 is used. This embodiment is more complicated than that according to FIG. 1, where, how shown above, only the ozone concentration is measured, but it allows to take into account a wide variety of other process variables; e.g. the ozone concentration, the ozone production capacity, the residual ozone content, etc.

The equivalent circuit diagram of the ozone generator 6 shown in FIG. 3 shows that an ozone generator consists of two capacities connected in series: the Capacity CD of the dielectric and the capacitance CL of the air gap. The ohmic resistance connected in parallel to the capacitance CL via a switch R is only switched on when the discharge of the ozone generator ignites.

The voltage curve U2 according to FIG. 5 corresponds to the current curve I2 according to FIG. 4. The period is denoted by Tg, the current flow period by TI.

For a more detailed description of the function and regulation of the network-based Rectifier 1 can be dispensed with, since this is commercially available power converter devices can be used. In order to ensure the simplest and most reliable control of the produced To obtain the amount of ozone, the inverter is operated at a constant frequency. This frequency is optimized so that the most favorable conditions in terms of Current, voltage, ozone yield, energy requirement, etc. can be achieved. After one of those Adjusting the frequency is no longer changed during operation.

The current flow duration TI is varied to influence the ozone production. The ratios of the current I2 and the voltage U2 are from the comparison of Fig. 4 and FIG. 5 can be seen. At nominal production of the ozonizer the current flow time is TI selected as 0.5 of the period Tg. The control electronics 7 determine the duration of the current flow as a function of the desired ozone production.

After the current flow duration TI has elapsed, a free-wheeling circuit is established in the inverter 2 resp. Short circuit formed by all thyristors of a branch, i.e. 2.1 and 2.3 or 2.2 and 2.4, are ignited at the same time. Through this will the primary winding 5 'of the high-voltage transformer 5 is de-energized. Since only ever one branch of inverter 2 is switched through, the primary circuit is open, so that the charge of the ozone generator 6, i.e. the capacities Ct and CD, are maintained remain. At the beginning of the next current half-wave, switching on the corresponding Thyristor in the currentless branch of the inverter 2, the commutation process first initiated. Assuming that the thyristors 2.2 and 2.3 are conductive, proceed as follows: By switching on the thyristor 2.4 after the current flow duration TI has elapsed, the high-voltage transformer 5 is on the primary side de-energized and the thyristor 2.7 switches to the blocking state. Switching on of the thyristor 2.1 after half a period T0 / 2 leads to commutation and to block the thyristor 2.2. The thyristors 2.1 and 2.4 are now carrying current and the process can be reversed in the next half-period.

It is noteworthy that the commutation always runs at the same speed, because constant current is used in the direct current circuit. The inverter 2 can be optimized for these conditions, which on the one hand reduces the circuit complexity becomes low and, on the other hand, the functional reliability of the device increases.

There is a start circuit for switching on the feed device which works according to the following principle: In a first Step is the direct current via a free-wheeling circuit in the inverter 2 on the Nominal value built up. As soon as the nominal value is reached, the will be released Operation of the inverter 2 via the control electronics 7, which at the same time the Forced deletion of the free-running circuit via the starter unit 4 is triggered.

The inventive device enables the ozone generator in to operate the most favorable operating area. In the DC circuit is independent of the amount of ozone produced is regulated by a constant current, so that the mpolung of the Ozone generator 6 always takes place with rated current.

This means that the unproductive phase is passed through quickly.

The direct current circuit and thus also the choke 3 is at rated current optimized, whereby a smaller size of the throttle 7 is made possible.

Claims (6)

Claims 1. Feed device for an ozone generator, which has a high-voltage transformer, its secondary winding for supply of the ozone generator is intended, characterized in that a network-controlled, controlled rectifier (1) an inverter (2) with associated control electronics (7) and starter unit (4) is connected, the output of the inverter (2) is connected to the primary winding (5 ') of the high-voltage transformer (5). 2. Feed device according to claim 1, characterized in that that the line-commutated rectifier (1) to a device (12) for current setpoint preselection connected. 3. Feed device according to claim 1 or 2, characterized in that that this contains an ozone concentration meter (9), which has a device ! 8j for ozone target / actual 7 equal to the control electronics (7) of the inverter (2) is connected, the device (8) for ozone target / actual comparison to a contraption (10) is connected for ozone setpoint preselection. 4. Feed device according to claim 1 or 2, characterized in that that this contains a process computer (13) which is connected to the control electronics (7) of the Inverter (2) is connected and inputs (14) for several measured values, such as Ozone concentration, ozone production, residual ozone content, etc. 5. Feed device according to at least one of claims 1 to 4, characterized in that the line-commutated, controlled rectifier (1) the inverter (2) is connected via a choke (3). 6. Feed device according to at least one of claims 1 to 5, characterized in that the inverter (2) is a thyristor inverter is in bridge circuit.