DE2949501A1 - OZONIZER WITH ROTATING SPARK RANGE - Google Patents

Abstract

An ozoniser (3) is connected to a power supply device which consists of a high-voltage transformer (8) having an earthed centre tap in the secondary circuit. Connected to the secondary winding terminals there are rectifier diodes (9), protective resistors (10), charging capacitors (11) and a spark gap (2). The spark gap (2) consists of a rotatable disc (14) made of insulating material, through which, parallel to its rotor shaft (13), at least one electroconductive rod (15, 15') is passed. Opposite the two ends of the rod (15) there are positioned, at the same radial distance from the rotor shaft (13), one pair each of ozoniser-side fixed spark-gap electrodes (16, 16') and feed-side fixed spark-gap electrodes (17, 17'). The spark gap arranged immediately at the ozoniser generates current pulses in the discharge path (7) in the range of from 10<-6> to 10<-9> seconds, which results in homogeneous discharge. <IMAGE>

Description

Ozonizer with rotating spark gap

The invention relates to an ozonizer according to the preamble of Claim 1.

Ozonizers are increasingly being used in industrial operations used because ozone is a strong oxidizing agent for wastewater purification, air improvement, Drinking water treatment, food storage, and used in medicine and chemistry will.

DE-AS 26 52 283 discloses a device for generating ozone known with controlled spark discharge, in which the energy supply of the ozone cell takes place via rod-shaped and disk-shaped spark gap electrodes. The spark discharge is achieved by approaching the stick electrodes, which rotate perpendicular to their longitudinal axis generated. The connection of each spark gap electrode to the power supply as well to one of the ozonizer electrodes is carried out via sliding contacts. With such a Although the device can use the short current pulses in the ozone yield, which are favorable for the ozone yield Nano-second range can be achieved between the ozonizer electrodes, the power supply However, sliding contacts are associated with poor energy transfer and with signs of wear and heat generation at the contact points.

In addition, with a device of this type, there are no short current paths to the ozone cell can be achieved, which increases the lead inductances and thus leads to longer current pulses.

The invention specified in claim 1 is based on the object a structurally simple and operationally reliable device with a low-wear device Execution of the spark gap to create.

The inventive design of the ozonizer can between the ozonizer electrodes with current pulses with a duration of 10 6 to 10 9 seconds as well as square wave or pulse voltages with short rise times in the nanosecond range can be generated without using sliding contacts or the like. this leads to a homogeneous discharge in the discharge gap of the ozonizer and the current pulse ends before the discharge can turn into a spark or arc discharge. Destruction of the ozone formed is thus avoided.

The subject matter of the invention also has the advantage that the setting the current pulse length to the value most favorable for the ozone product ion very easily can take place and few moving parts are provided, resulting in a high level of operational reliability is achieved.

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

By designing the invention according to the claims 2 and 3 the pulse repetition rate can either be set differently Speeds of the rotatable disc or by fastening several movable ones against each other offset electrodes on this to the most favorable value for ozone production can be set. According to claims 4 and 5, the spark gap can be ignited quickly can be achieved in the shortest possible way with the voltage that is optimal for the ozonizer. The design of the spark gap electrodes according to claim 6 is cheap and technical easy to implement. The solution specified in claim 8 enables a quick Reloading of the ozonizer electrodes and a relatively loss-free power supply shortest way. The energy required for homogeneous discharge is generated by the capacitors according to claim 9 and transmitted the spark gap very quickly in the ozonizer.

According to claim 10 can be a good power transmission from the voltage source on the ozcnisatorelectrodes, with losses that occur when using longer leads would occur can largely be avoided.

In claim 11 is a particularly space-saving and robust design of the ozonizer according to the invention described.

The invention is illustrated below with reference to one in the drawing Embodiment explained in more detail.

Fig. 1 shows a schematic representation of an inventive Ozonizer with a device for energy supply, Fig. 2a and FIG. 2b shows diagrams of the idealized time course of voltage and current the ozonizer electrodes, Fig. 2c on an enlarged scale the approximate temporal Course of the current between the ozonizer electrodes, Fig. 3 and Fig. 4 an embodiment an ozonizer according to the invention with a device for energy supply, which contains a rotating spark gap.

The ozonizer 3 shown in Fig. 1 consists of two to each other parallel, plate-shaped, electrically conductive electrodes 4, 5, which by a Dielectric layer 6 running parallel to these and of uniform thickness and are separated from one another by a discharge gap 7. The dielectric Layer 6 is arranged on the electrode 4 so that the discharge gap 7 between the dielectric layer 6 and the electrode 5 of the ozonizer 3 runs. the Electrode 5 is grounded and connected to both the negative pole of a DC voltage source 1 as well as to the positive pole of a further DC voltage source 1 '.

The second electrode 4 is via a fast switching switch 2 either to the positive pole of DC voltage source 1 or to the negative pole of the other DC voltage source 1 'connected.

The mode of action is as follows: Through the discharge gap 7 an oxygen-containing gas mixture or pure oxygen flows. The switch 2 connects the second electrode 4 of the ozonizer 3 to the positive pole of the DC voltage source 1, whereby positive voltage is applied to the ozonizer electrodes 4, 5. When switching from the voltage source 1 to the negative pole of the further voltage source 1 ' a brief negative current pulse occurs between the ozonizer electrodes 4, 5 on, with a duration of about 10 6 to 10 9 seconds.

The changeover switch 2 then switches from the negative pole of the other Voltage source 1 'to the positive pole of the voltage source 1, whereby between the ozonizer electrodes 4, 5 a brief positive current pulse occurs, such as it is shown in Fig. 2c. With a switching frequency of approx. 100 Hz this results idealized at and between the ozonizer electrodes in Fig. 2a and 2b shown time curve of the voltage or the current.

Due to the short-term current pulse, part of the oxygen-containing Gas mixture or the pure oxygen existing oxygen molecules to atomic Oxygen split, which becomes with the still existing molecular oxygen Ozone connects.

The device shown in Fig. 3 and 4 for generating ozone consists of a voltage source 1 with a switching device 2, which as a rotating spark gap is formed, and a tubular ozonizer 3. A high-voltage transformer 8 with a grounded center tap is over at both ends of its secondary winding each with oppositely polarized diodes 9 and one each Protective resistance 10 to a first supply-side fixed spark gap electrode 17 and a second supply-side fixed spark gap electrode 17 'is connected and via one each parallel to the feed-side spark gap electrodes 17, 17 'connected charging capacitor 11 with a grounded outer electrode 5 of the Tubular ozonizer 3 connected. In the interior formed by the external electrode 5 of the tube ozonizer 3 is an end facing away from the voltage source 1 at its end closed tube concentric. arranged to the longitudinal axis of the ozonizer 3 and to form a discharge gap 7 from the outer electrode 5 in a certain Distance distant.

The inner surface of the tube, which is closed on one side, made of a dielectric 6, for example glass, is covered with an electrically conductive layer, for example made of silver or aluminum, which represents the inner electrode 4 of the ozonizer 3. This is attached to a support arm 19 via a connecting rod 18 with two Ozonizer-side spark gap electrodes 16, 16 'connected. The protective resistors 10 can also be replaced by inductors or other current-limiting components will.

The ozonizer-side spark gap electrodes 16, 16 'and the feed-side Spark gap electrodes 17, 17 'are rods arranged next to one another in pairs made of tungsten, for example, with the first and second ozonizer-side Spark gap electrodes 16, 16 'in their axial direction from the first and second, respectively feed-side spark gap electrode 17, 17 'at a certain distance are distant. Between the facing ends of the spark gap electrodes 16, 16 'and 17, 17' a movable electrically conductive body 15 or 15 'in the form of a rod, e.g. made of tungsten, which runs vertically through a rotatable disk 14 is passed through.

The rotating disk 14 has a parallel to the longitudinal axis of the Rods 15, 15 ', 16, 16', 17, 17 'extending rotor shaft 13, which with a drive motor 12 is connected.

The bars 15, 15 ', 16, 16', 17, 17 'are at the same radial distance arranged by the rotor shaft 13 of the rotating disk 14. This consists of insulation material, preferably made of plastic.

The ozonizer-side spark gap electrodes 16, 16 'are over the connecting rod 18 is connected directly to the inner electrode 4 of the ozonizer 3.

The mode of operation of the arrangement described above is as follows: An oxygen-containing gas mixture, e.g. air or, flows through the discharge channel 7 pure oxygen referred to below as feed gas.

The high voltage transformer 8 supplies the required alternating voltage, which is rectified by the diodes 9. The protective resistors 10 are used for current limitation.

The rectified voltage causes the charging capacitors 11 charged with a certain positive or negative amount of charge. With help of the drive motor 12, the rotatable disk 14 is set in rotation, wherein the Rod 15 revolves at a certain speed and between the facing Ends of the fixed Spark gap electrodes 16, 16 ', 17, 17' is passed through. If the rod 15 approaches as a result of the rotation of the disk 14 the spark gap electrodes 16, 17, then forms at a certain position of the disk 14 an arc between the feed-side spark gap electrode 17 and the rod 15 or 15 'and the spark gap electrode on the ozonizer side 16 an arc, whereby the inner electrode 4 of the ozonizer 3 instantly is connected to the voltage source 1. The charging capacitors 11 provide the for rapid charging of the ozonizer 3 acting as a capacitor. The arcs between the rod 15 and the feed-side spark gap electrode 17 and the spark gap electrode 16 on the ozonizer side only burn during the very short time in which a current flows. As the disc rotates 14, the rod 15 approaches the spark gap electrodes 16 ', 17' and the inner electrode 4 is created by arcing between the spark gap electrodes 16 ', 17' and the rod 15 reloaded to negative potential. Through the above described Ignition of the rotating spark gap 2 occurs at the ozonizer electrodes 4, 5, the rectangular voltage curve shown idealized in FIG. 2a.

Occurs between the inner electrode 4 and the outer electrode 5 brief current pulse through the discharge channel 7, with a duration from 10 to 10 seconds according to FIGS. 2b and 2c. As a result of the brief current pulse becomes part of the oxygen-containing gas mixture or pure oxygen existing oxygen molecules split to atomic oxygen, which is with the remaining molecular oxygen converts to ozone binds. The current pulse ends before the discharge turns into a spark or arc discharge can, which would lead to a local heating of the gas mixture and thus to a destruction of the ozone formed. As a result of the brief current pulse a homogeneous discharge in the discharge channel 7 with a relatively low expenditure of energy ignited. To produce one kilogram of ozone, air is used as the feed gas typically 8 to 12 kWh and for oxygen 4 to 7 kWh. The rise times the pulses generated at the ozonizer electrodes 4, 5 are in the nanosecond range. A higher pulse repetition frequency can be achieved by increasing the speed the rotating disk 14 as well as a larger number passed through it Rods 15, 15 'can be achieved. Due to the arrangement of the rotating spark gap 2 directly at the ozonizer 3, very short current paths can be achieved, whereby the desired short current pulses by reducing the lead inductance can be generated.

Of course, the ozonizer described above cannot be designed only as a tube ozonizer but also as a plate ozonizer.

Claims (11)

Patent a n p r ü c h e 1. Pulsed ozonizer with at least two Electrodes, a high voltage source and a spark gap with fixed and relative to the fixed movable spark gap electrodes for up and down Reloading of the electrodes of the ozonizer, characterized in that the high voltage source (1) has three terminals (la, lb, lc), of which the first terminal (lc) with the the first electrode (5) is connected to the ozonizer (3) and the other terminals (la, lb) have a different potential compared to the first terminal (lc), two supply-side fixed spark gap electrodes (17, 17 '), each are connected to one of the named clamps, two ozonizer-side fixed Spark gap electrodes (16, 16 ') which are connected to each other and to the second Electrode (4) of the ozonizer (3) are connected, the fixed (16, 16 ', 17, 17') and / or the movable electrode (15) are arranged and designed in this way are that when approaching the movable electrode (15) one after the other electrically Conductive connection between the supply and ozonizer-side spark gap electrode pairs (16, 17; 16 ', 17') as a result of spark discharge. 2. Ozonizer according to claim 1, characterized in that the movable Electrode (15) is mounted on a rotatable disc (14). 3. Ozonizer according to claim 1 and 2, characterized in that a plurality of offset against one another in the circumferential direction of the rotatable disk (14) movable electrodes (15, 15 ') is attached to the disc (14). 4. Ozonizer according to claim 1 and 2, characterized in that the rotatable disc (14) in the space between the feed and ozonizer sides fixed spark gap electrodes (16, 16 ', 17, 17') is arranged. 5. Ozonizer according to claim 1, 2 and 4, characterized in that both the feed and ozonizer side spark gap electrodes (16, 16 ', 17, 17 ') and the movable electrode (15) at the same radial distance are arranged from the axis of rotation of the rotatable disc (14). 6. Ozonizer according to claim 1 and 2, characterized in that the feed-side and / or the ozonizer-side spark gap electrodes (16, 16 ', 17, 17') and / or the movable electrode (15) designed as rods are, the longitudinal axis of which runs parallel to the axis of rotation of the rotatable disc (14). 7. Ozonizer according to claim 1, 2, 5 and 6, characterized in that that the supply and / or the ozonizer side spark gap electrodes (16, 16 ', 17, 17') and / or the movable electrode (15) than in the direction their longitudinal axis displaceable rods are carried out. 8. Ozonizer according to claim 1, 2 and 4, characterized in that the feed (17, 17 ') and the ozonizer-side spark gap electrodes (16, 16 ') on both sides of the rotatable disc (14) in pairs opposite one another are arranged. 9. Ozonizer according to claim 1 and 8, characterized in that the supply-side fixed spark gap electrodes (17, 17 ') via two Series-connected charging capacitors (11) are connected, the connecting line the charging capacitors (11) is connected to zero potential. 10. Ozonizer according to claim 1 and 9, characterized in that the ozonizer-side fixed spark gap electrodes (16, 16 '), the movable one Electrode (15), the feed-side spark gap electrodes (17, 17 ') and the Charging capacitors (11) are arranged in the immediate vicinity of the ozonizer (3). 11. Ozonizer according to claim 10, characterized in that the Fixed spark gap electrodes (16, 16 ') on the ozonizer side with the ozonizer (3) form a structural unit.