RU2147010C1 - Laminated ozonizer - Google Patents

Abstract

FIELD: generation of ozone. SUBSTANCE: laminated ozonizer has two discharge elements made of grounded electrodes, dielectric plates, high-voltage electrodes placed in one horizontal plane in sealed case. Case is divided by insulation plate into two compartments: lower compartment houses discharge elements and upper compartment is used as ozone collector. Cooler is placed on outer side of case and has two pipe unions for inlet/outlet of cooling fluid. Cooler tightly tied up with high-voltage electrodes has bushings and tubes for gas flow between compartments and pipe-unions. Dried air is supplied through inlet and generated ozone is released through outlet. Dielectric spacers are laid between dielectric plates. EFFECT: simplified design, increased reliability and simplicity of attendance. 1 cl, 1 dwg

Description

 The invention relates to devices for producing ozone.

 Known ozonizer / US Pat. U.S. N3973133, (C 01 B) cl. 250-532, 1976 / with a large number of flat cooled electrodes, in a rectangular casing of insulating material, the electrodes are installed at a certain interval and connected in two groups through one. Each electrode is made of two flat metal sheets with profiled recesses of a certain configuration so that when these sheets are connected, channels are formed that cover almost the entire surface of the electrodes. Then this pair of sheets is coated externally with a layer of dielectric material, which also seals the edge of their connection on the periphery. The electrodes of each group are interconnected by two tubes passing in opposite corners of the sheets, and in each tube there are holes communicating with the channel system in the electrodes. The ozonizer body has a central chamber with electrodes, as well as a lower chamber for supplying air or oxygen for ozonation and an upper chamber for collecting and discharging ozonized gas. The electrodes are connected to the winding of a high voltage transformer, and the electrodes are cooled by means of a frion cooler.

 A disadvantage of the known ozonizer is the complex design, in which for the repair of discharge elements it is necessary to disassemble the entire package of electrodes and, in addition, the ozonizer has an ineffective air cooling system for the electrodes.

 Ozonizer / Pat. USA N3801791, cl. 250-532, 1976 /, made of rectangular rectangular metal electrodes, between which glass dielectric plates and longitudinal rails are laid, creating gap discharge gaps through which ozonized gas is passed. The entire laminated package is pulled together by a rigid mounting frame, and the electrodes are connected through one to two beams. One of them is connected to the frame, and the other is removed from the apparatus and connected to the high-potential terminal of the high-voltage power transformer / 6 - 15 kV /. The frame with the electrode package is mounted in a metal casing, and the space between the casing and the package is filled with gas-tight electrical insulating material. The frame is electrically connected to the chassis, which is grounded. To remove the heat generated in the apparatus, the electrodes of the grounded beam are made of sheets with a thickness of 15 mm and minimize thermal resistance between them and the casing, which is cooled due to the natural convention of ambient air.

The disadvantages of the known ozonizer is that it has a complex structure and is unreliable in operation. The unreliability is explained by the fact that during the operation of the ozonizer there is an uneven heating of the glass dielectric plates. In the discharge zone, the temperature reaches 80-100 ^o C, and at the edges necessary to close the discharge gap, the surface temperature does not exceed 40 ^o C. As a result, significant thermal and mechanical stress arises in the wall, which can cause mechanical destruction of the glass and the ozonizer leaves system. In this design, this is compounded by the fact that the heat sink to the thick metal electrode from the central part of the plates is carried out through a layer of air, and from the edge through longitudinal rails having a significantly higher thermal conductivity than air.

 In addition, the design of the ozonizer is so complex that in order to repair and replace any glass plate, it is necessary to completely disassemble the entire package of electrodes, having previously destroyed the layer of electrical insulation material between the casing and the package of electrodes.

 Closest to the technical nature of the present invention is selected as a prototype plate ozonizer with a central collector, which is called "Ozonizer" Otto ". / V.F. Kozhinov. Purification of drinking and industrial water. Examples and calculations, M., Ed. in the literature on construction, 1971, p. 82-85 /.

 The Otto ozonizer is made of several parallel placed discharge elements, alternating in a certain sequence, namely: a grounded electrode, a dielectric, a high voltage electrode, a dielectric, a grounded electrode, etc. As an electrode, a layer of foil or metal paint is used, which is tightly adjacent to the outer surface of the hollow bars, which are low-voltage due to their grounding. Through the hollow bars, water is passed to cool the electrodes. Thin glass plates adjacent to grounded electrodes serve as dielectrics. High-voltage electrodes are made in the form of bars and the cooling system with water is electrically isolated from grounding. The electrodes and dielectric have a square cross section with a central hole.

 All elements are placed vertically in a parallelepiped-shaped housing and are closely pressed against each other. A section is formed in which the central holes form a passage communicating with the discharge fields. The gap between the high voltage electrode and the dielectric determines the width of the discharge field, which is regulated using guide rings attached to the high voltage electrode. The case of the ozonizer is tight and can consist of one, two or four sections. Each of the collectors is connected to the flat plates of the electrodes by separate tubes.

 The disadvantages of the known ozonizer are oversized housing dimensions and design complexity, namely, each collector is connected to flat electrode plates by individual tubes, the number of which is equal to the number of electrodes, and their placement inside a sealed housing requires significant free space, and, consequently, an increase in size. In addition, the ozonizer is difficult to maintain and repair, because for repair, it is necessary to disassemble the entire package of electrodes and disconnect all water supply and drain pipes. With an increase in the number of electrodes, mechanical loads increase when the package is pulled together, which reduces the reliability of the structure.

 The aim of the invention is to simplify the design, improving reliability and ease of maintenance.

 This goal is achieved by the fact that in the known device made of several discharge elements, each of which consists of dielectric plates, cooled grounded and high-voltage electrodes having central holes, and placed in a metal body having the shape of a parallelepiped, the additionally sealed housing is separated by an insulating plate into two compartments, and in the lower compartment discharge elements are located in one horizontal plane, and the upper compartment is a common ozone collector. In addition, the ozonizer has two common for all discharge elements, a flat cooler, one of which provides heat removal from low-voltage electrodes and is located on the outer side of the base of the housing, and the other from high-voltage electrodes, in which there are bushings coaxial with the central holes of the high-voltage electrodes, through which missed tubes connecting the lower and upper compartments, and the number of bushings is equal to the number of discharge elements, and the discharge elements can be of any shape and the distance between them can be It is easy to install.

 Comparative analysis with the prototype shows that the claimed device is characterized by the presence of two compartments in a sealed enclosure, as well as the location of the discharge elements in one horizontal plane, the presence of two flat coolers common to all discharge elements, one of which is on the outside of the housing base, and the other has coaxially with the Central holes of the high-voltage electrodes of the sleeve with the tubes missing in them, which serve to connect the lower and upper compartments, and the number of bushings is equal the number of bit elements.

 Thus, the claimed device meets the criterion of "novelty."

 A comparison of the proposed solutions with other technical solutions shows that the presence of two or more compartments in one building is known / pat. U.S. N3973133, C 01 B, 1976 /.

 In addition, there are known discharge elements in the form of flat metal electrodes of rectangular shape, between which glass dielectric plates and strips / gaskets / are laid, creating gap discharge gaps through which ozonized gas is passed / pat. U.S. N3801791, CL 250-532, 1976 /.

 However, only the totality of all the new features in the claimed technical solution that distinguishes it from the prototype allows us to conclude that the alleged invention meets the criterion of "significant differences".

 The invention is illustrated in the drawing, which shows the design of the proposed plate ozonizer.

 The plate ozonizer shown in the drawing has, for example, two discharge elements consisting of grounded electrodes 1, dielectric plates 2, high voltage electrodes 3 and placed in a sealed, for example, metal casing 4 in one horizontal plane. The housing 4 is divided by an insulating plate 5 into two compartments 6 and 7, with discharge elements fixed in the lower compartment 6, and the upper compartment 7 being an ozone collector. The cooling of the grounded electrodes 1 is provided by the first cooler 8, located on the outer side of the housing 4 and having two fittings 9 and 10 for the input and output of the coolant. The high-voltage electrodes 3 are cooled using a second cooler 11 tightly tightened with the high-voltage electrodes 3, in which there are bushes 12 and tubes 13 coaxially with the central holes of the electrodes 3, connecting the lower 6 and upper 7 compartments by gas, and the cooling liquid is introduced through the third fitting 14 and is discharged through the fourth fitting 15. Drained air is supplied through the inlet 16, and the obtained ozone is discharged through the outlet 17. Dielectric gaskets 18 of a certain height are laid between the dielectric plates 2, creating slotted discharge gaps through which ozonated air is passed. The size of the gap discharge gap is determined by the height of the dielectric spacers 18 of a square or round shape with dimensions, for example, 2x2 mm for a square shape and a diameter of 2 mm for a round shape.

 If an increase in ozone output is needed, the proposed plate ozonizer designs can be connected both in parallel and in series. The design of such an ozonizer will remain simple, reliable and uncomplicated for prevention and repair.

 An example of a specific implementation of plate ozonizer.

 In the proposed plate ozonizer, the housing 4 is made of sheet aluminum of the AMG brand. On the outside of the base of the housing 4, a casing of the cooler 8 of the grounded electrodes is welded, which has fittings 9 and 10 for the input and output of the coolant. Fittings are welded on one of the walls of housing 4: 16 for supplying drained air and 17 for draining the ozone-air mixture. In the upper part of the housing 4 on the outer side of the walls around the perimeter a shell is welded for mounting the housing cover. The sealing of the housing 4 was carried out using a polyvinyl chloride gasket installed around the perimeter of the housing 4 between the upper shell and the cover of the housing 4. On the inner surface of the housing 4, an inner shell was welded around the perimeter to fasten the insulating plate 5, which ensures gas separation of the chamber 6 and the ozone collector 7. The plate 5 is made of sheet of vinyl plastic and has, coaxially with the Central holes of the high voltage electrodes 3, holes for the passage of tubes 13. On grounded electrodes 1, fixed to the base of the body and 4, through a heat-conducting paste based on beryllium oxide dielectric plate set 2 from ceramic based on aluminum oxide to 1 mm thick, on which are fixed the dielectric layer 18 of the same material with dimensions of 2x2 mm. The dimensions of the dielectric plates 2 are larger than the size of the electrodes, which ensures the prevention of corona discharges outside the working area. The cooler of the high-voltage electrodes 11 has nozzles 14 and 15 for the input / output of the coolant and welded sleeves 12 through which tubes 13 pass, which allow the removal of ozone from the working zone into the ozone collector 7. High-voltage electrodes 3 with central holes are attached to the base of the cooler 11, on which dielectric plates 2 are mounted, having central holes smaller than the holes of high voltage electrodes 3, which prevents corona discharges and increases the reliability of the entire device.

 In this case, water was used as a coolant.

 Dismantling the ozonizer for repair or maintenance is simple and is carried out in the following order.

 The housing cover 4 is removed, fastened with screws to the outer shell. The insulating plate 5 is removed, tubes designed for supplying and discharging coolant are removed from the fittings 14 and 15. Then the cooler of the high-voltage electrodes 11 is removed, together with the high-voltage electrodes 3 and dielectric plates 2 fixed to it. Thus, access is provided for replacing or cleaning the dielectric plates 2.

 After carrying out repair work, installation is carried out in the reverse order.

 Thus, all of the above allows us to conclude that the design of the proposed ozonizer is simple, reliable and easily accessible for repair and maintenance. And due to the fact that the pairs of electrodes are located in a horizontal plane, their pairwise coupler does not cause significant mechanical and thermal overvoltages.

Claims (2)

 1. A plate ozonizer made of several discharge elements, each of which consists of two dielectric plates, cooled grounded and high voltage electrodes having central holes and placed in a sealed box shaped like a parallelepiped, characterized in that the sealed box is divided into two by an insulating plate compartment, and in the lower compartment discharge elements are located in one horizontal plane, and the upper compartment is a common ozone collector, while the ozonizer has two common for all discharge elements of a flat cooler, one of which provides heat removal from low-voltage electrodes and is located on the outside of the base of the casing, and the other from high-voltage electrodes, the latter having bushings coaxial with the central holes of the high-voltage electrodes through which tubes connecting the lower and upper compartments, the number of bushings being equal to the number of discharge elements.  2. The ozonizer according to claim 1, characterized in that the discharge elements can be made of any shape.