NO151706B - N-PHOSPHONOMETHYLGYLINE COMPOUNDS WITH HERBICIDE EFFECT AND USE thereof IN HERBICIDE PREPARATIONS - Google Patents

Description

Device for producing ozone.

The present invention relates to a device for the production of ozone using an ozone generator which contains two electrodes which are connected to a current source and between which a relatively narrow through-flow channel is formed which serves as a discharge space. Between the electrodes, a relative

show high voltage, for example 10-20 kV and when air or other gas containing oxygen is passed through the channel between the electrodes, this high voltage causes a flash discharge whereby part of the oxygen is converted into ozone. The ozone generator that occurs most often is of the so-called tube type and consists of two cylindrical electro-

where one of them with a space surrounds the other concentrically. A cylindrical dielectric that generally functions

rer as a carrier for one electrode up-

takes up part of the annular space, while the remaining part forms

down the glimmer discharge room.

To extract ozone satisfactorily

those yielded, it is necessary to use dry air. The drying now takes place in general

hot by cooling the air so that the moisture that occurs is removed by freezing. Since ozone is rather unstable all-

ready at slightly elevated temperatures

rer, the ozone yield is also highly dependent on the temperature being kept as low as possible in the generator. The electrodes are of course exposed to a strong heating during the discharge and they heat up

by again the air that passes. In order to reduce the disadvantages, it is previously known to allow cold air to pass through the discharge chamber

met, while the ozone generator is cooled externally with cooling water or chilled air. Until now, however, it has not been possible in practical operation at reasonable costs to lower the temperature so low that a particularly significant increase in the ozone concentration in the gas mixture leaving the generator has been achieved.

Present invention that builds

on the principles set out above,

involves making it possible to carry out efficient and economical cooling of the ozone generator, while at the same time extracting a gas mixture with a high ozone concentration.

As the amount of cooling air that is not sucked into the ozone generator constantly circulates, no particular cooling effect is lost, and the cooling air can therefore be given such a large volume that the heat given off by the electrodes causes a fairly reasonable increase in temperature. The generator hol-

is effectively cooled in this way so that the air that passes through the discharge room has a high ozone concentration

tion. As an example, it can be mentioned that the air coming from the cooling system can have a temperature between 4-10 and -4-15°C, and of this air, for example, 2-5 per cent can be taken out through the generator, while the rest of the cooling air quantity gets circulate. The temperature in the generator's reaction room can drop below

such conditions lie at approx. 0°C, in any case below +10°C. In previous production of ozone, it has usually not been possible to avoid a temperature of 20-30°C in the reaction room, so that the ozone yield was correspondingly worse.

The invention thus includes a device for the production of ozone and the device consists of one or more ozone generators that each contain two electrodes that are connected to a current source and between which there is a relatively narrow flow channel that serves as a discharge chamber and one end of which is open while the other end can be connected to a point of consumption through a wire. The peculiarity of the invention is that the ozone generators and a cooling battery are built into two separate, preferably heat-insulated chambers that are connected to each other through two channels arranged at each end of the cooling battery, that a fan is arranged to to cause a current of air to circulate through the two chambers, and that the cooling battery chamber is also in communication with the external air through an opening located at a distance from the said channels.

The attached drawing shows fig. 1 schematically shows an embodiment of the device according to the invention in a vertical section, while fig. 2 and 3 show vertical sections through the upper or lower end of a tube-type ozone generator.

In fig. 1 denotes 4 a house which by means of a vertical and a horizontal dividing wall 5 respectively. 6 is divided into three chambers 7, 8, 9, one of which 7 encloses a number of ozone generators 10, in the shown embodiment 2 pieces, as well as a high-voltage transformer 11. The chamber 8 contains a cooling compressor 12 which through pipelines 13, 14 is connected to a cooling battery 15 which is built into the chamber 9. The chambers 7 and 9 are preferably thermally insulated, and the chamber 9 has an opening 16 at the top through which it is in contact with the outside air.

The cooling battery 15 has a vertical through-flow channel 17 whose lower end is open. From the upper end of the channel 17, a channel 18 exits which opens into the upper part of the generator chamber 7. A fan 19, which is placed in the channel 18, sucks air upwards through the cooling channel and leads the cooled air into the chamber 7. From in the lower part of the generator chamber 7, a vertical channel 20 exits which opens into the cooling battery chamber 9 close to the inlet end of the channel 17.

The ozone generators 10, which are preferably of the tube type, have their outer and inner electrodes connected to the high-voltage transformer 11 through lines 21 or 22. The outer electrode can consist of a metal coating 23 on a glass tube 24 which serves as a dielectric, while the inner electrode can consist of an aluminum tube 25, fig. 2 and 3. The two ends of the inner tube are closed by means of lids 26 which are held in place by means of nuts 27 which are screwed onto the ends of a connecting rod 28 which passes axially through the tube and is led out through central holes in the lids. An externally threaded sleeve 29 is threaded onto each of the ends of the outer tube 24 and an internally threaded coupling sleeve 30 is fitted with a sealing ring 31 which engages against the glass tube 24 screwed onto the sleeve 29. The inner tube 25 is held coaxially in the outer tube in that the two end caps 26 have externally threaded edge flanges 32 which are screwed into the coupling sleeves 30. In this way, the entire ozone generator is held together by means of simple means, so that it can be easily dismantled if necessary for possible replacement of parts . In order for the air to be able to flow through the annular space 33 between the outer tube 24 and the inner tube 25, the edge flanges 32 on the lids are provided with a large number of perforations or recesses 34. Optionally, the flanges can be designed as a tan around the lids. The connection sleeves must of course be made of insulating material, suitable plastic.

The coupling sleeves 30 at the lower ends of the generators are attached to jacks 35, fig. 3, which protrudes from one wall of the chamber 7. The upper coupling sleeves 30 are sealingly connected to a common collection box 36 from which a pipeline 37 goes to the suction side of a pump which is not shown and which is designed to carry ozone gas the mixture further to a point of consumption.

As is essentially already clear from what has been said above, this device works so that the fan 19 brings air to pass through the cooling coil into the upper part of the chamber 7 where the air, which has been cooled to -=-10 or + 15°C, sinks downwards during flushing around the electrode tubes 23, 24. A smaller fraction of the air is sucked into the discharge spaces 33 between the electrodes 23, 25 in order, after ozone formation, to flow out through the line 37, while the largest part of the air is led back to the cooling battery chamber 9 through the channel 20. Through the opening 16, fresh air is sucked in in an amount that

corresponds to the ozone gas mixture that is carried

away through the wire 37.

As mentioned, the facility is appropriate

dimensioned so that at most approx. 5 percent of it

cold air supplied by the fan

19 is taken out through the ozone generators. The cold air that circulates in large excess also causes an effective cooling of the electrodes with the resulting large ozone formation. At the same time, energy consumption is low

as no cooling air is lost which

not used.

The device described can

obviously varies when it comes to details.

Thus, for example, the fan can be placed in another place, and it was also possible

be possible to allow the air flow to circulate in

opposite direction, i.e. from the bottom up

in the generator chambers.

Claims (2)

1. Device for the production of ozone, consisting of one or more ozone generators that each contain two electrodes that are connected to a current source and between which there is a relatively narrow flow channel that serves as a discharge space and one end of which is open while the other end can be connected to a point of consumption through a line, characterized by ozone the generators (10) and a cooling battery' (15) are. built into two separate, preferably heat-insulated chambers (7 and 9), which are connected to each other through two channels (18, 20) which are arranged at the opposite ends of the cooling battery, that a fan (19) is arranged to bring a air flow to circulate through the two chambers (7, 9) and that the cooling battery chamber is also connected to the outside air through an opening (16) which is located at a distance from the channels (18, 20). 2. Device as stated in claim 1 where the ozone generators are arranged vertically with their open ends at the bottom, characterized in that the cooling battery (15) has a vertical flow channel (17) which is open at the bottom and whose upper end through the connection channel (18) is connected to the upper part of the generator chamber (7), and that the channel (20) which exits from the lower part of the generator chamber (7) opens into the battery chamber (9) near the lower end of the cooling battery, the fan (19) being designed to drive the air flow upwards in the through-flow channel (17) in the cooling battery.