IT202000032690A1 - CONDENSATE PURIFICATION METHOD AND SYSTEM - Google Patents

Description

DESCRIPTION

Attached to a patent application for INDUSTRIAL INVENTION having the title

?Condensate purification method and system?

Object of the present invention ? a method and a purification system for the condensate coming from a system for conveying a pressurized fluid, typically air.

The compressed air used in industrial plants, being mainly produced by lubricated compressors, is filtered to remove small quantities? of lubricants (commonly classified as hydrocarbons) released in the form of aerosols. Furthermore, following natural cooling within the distribution network or through special coolers, the water vapor contained passes into a liquid state, generating significant quantities of water. condensation.

Basically the compressed air systems generated by lubricated compressors, as a residue of the compression process, produce water contaminated by hydrocarbons. This water is drained outside the system for disposal.

Usually the disposal consists in the discharge of the condensate into the sewage system but being contaminated by hydrocarbons dangerous for the environment? It is known to filter it by making it pass through a compartment containing rock wool and granular activated carbon. This system does not always ensure adequate abatement of these substances and sometimes the wastewater is not? complies with the limits established by the legislation on discharge. In this context, the technical task underlying the present invention ? propose a system and a method that allows to optimize the purification of the condensate from hydrocarbons.

The technical task specified and the aims specified are substantially achieved by a purification plant and method comprising the technical characteristics disclosed in one or more of the joint claims. Further characteristics and advantages of the present invention will appear more clearly from the indicative, and therefore non-limiting, description of a preferred but not exclusive embodiment of a purification plant as illustrated in the accompanying figures, in which:

figure 1 shows a purification system according to the present invention;

figure 2 shows a detail of the purification system according to the present invention;

- Figure 3 shows a fluid conveying system comprising a purification system according to the present invention.

In the joined figures with the reference number 1 yes ? indicated a condensate purification system coming from a fluid conveying system.

The purification system 1 comprises an environment 2 in which the condensate 8 is located. This condensate 8 ? basically water with hydrocarbon particles (lubricants). The environment 2 ? an accumulation compartment 20. Eg ? a tank or buffer tank for temporary accumulation of the condensate 8. Typically ? there is an inlet and an outlet for the condensate 8 from room 2.

The purification system 1 comprises means 3 for generating ozone located in said environment 2.

The generation means 3 comprise means 31 for introducing gas containing oxygen into the environment 2. This gas? typically air. The means 31 for introducing gas comprise a mixing pump 4 placed inside the condensate. Conveniently, this mixing pump 4 draws air from outside the condensate, in particular it draws air from outside the environment 2. The mixing pump 4 conveniently comprises a first intake mouth 41; a part of the liquid 80 which forms said condensate 8 is sucked through it. The mixing pump 4 also comprises a second suction mouth 42; said gas 9 is sucked in through it from outside the condensate 8 (or from the environment 2).

The mixing pump 4 also comprises a delivery port 43 through which said part of the liquid 80 and said gas 9 are delivered, sucked in by the first and second ports 41, 42. This delivery port 43 ? inside room 2. In particular, it is found inside the condensate. The gas at the delivery ? in the form of bubbles. Typically such bubbles are microbubbles. Typically bubbles, especially microbubbles, have a diameter of less than 1 millimeter. So the mixing pump 4 can? be defined as a gas microbubble generating pump.

The generation means 3 comprise means 32 for generating ultraviolet radiations which invest both the condensate 8 and said gas 9 causing the generation of ozone.

Conveniently, the means 32 for generating ultraviolet radiation comprise a UV-C lamp. Advantageously, the means 32 for generating ultraviolet radiations emit radiations having a wavelength comprised between 180 and 190 nanometres.

The ultraviolet radiation generation means 32 are embedded in the condensate 8 inside said environment 2.

The purification takes place by creating a recirculation of the condensate inside the compartment 20 in which both the mixing pump 4 and the means 32 for generating ultraviolet radiation are immersed.

The capacity? purification of the system depends on the management of the flow of condensate in / out and the quantity? of ozone produced (mixing pump 4 output/lamp power 320 UV-C).

Object of the present invention ? furthermore, a system 10 for conveying a fluid (typically air).

The system 10 comprises means 100 for compressing the fluid. The system 10 also comprises a channel 101 for conveying the fluid located downstream of the compression means 100.

The plant 10 comprises a system 11 for recovering the condensate generated by the humidity present in the fluid that passes along the channel 101.

The plant 10 also comprises a system 1 for purifying the condensate coming from said recovery system 11. This purification system 1 has one or more? of the features described above.

Object of the present invention ? furthermore a method of purification from lubricating substances of a condensate coming from a fluid conveying system. This method? suitably implemented by a purification system 1 comprising one or more? of the features described above. The method comprises the step of introducing gas 9 containing oxygen inside the condensate 8. This gas ? typically air. Gas 9? introduced into an accumulation compartment 20 in which ? said condensate 8. This accumulation compartment 20 ? typically a tank. This condensate comes from the fluid compression system.

The method also comprises the step of investing the condensate 8 and said gas 9 placed inside the condensate 8 with ultraviolet radiations 7 generating the production of ozone. Therefore, ultraviolet radiations perform both a sanitizing function from biological agents and the production of ozone starting from said oxygen-containing gas. This ozone is used for its oxidative effects on polluting agents (both chemical and biological).

The phase of investing the condensate 8 and said gas 9 placed inside the condensate 8 with ultraviolet radiations 7 takes place inside said tank 20. The formation of ozone takes place inside the condensate.

The step of introducing gas 9 containing oxygen into the condensate 8 involves a mixing pump 4 immersed in the condensate 8 which sucks:

- a part of the liquid 80 which forms said condensate 8 through a first suction mouth 41; And

- said gas 9 from outside the condensate 8 by means of a second suction mouth 42.

The mixing pump 4 releases said part of the liquid 80 and said gas 9, sucked in by the first and second mouths 41, 42, inside the condensate 8 in which said mixing pump 4 ? immersed.

The ultraviolet radiations 7 preferably, but not necessarily, have a wavelength of between 180 and 190 nanometres. This wave length is in fact particularly optimized for the production of ozone starting from the gas containing oxygen (particularly from the air).

The present invention achieves important advantages.

First of all, it allows efficient purification of lubricant residues in a condensate. In particular, it allows the use of two systems (use of ozone and ultraviolet radiation) which taken individually have known capacities? of sanitization, but combining them together to have a synergistic effect. In particular, ultraviolet radiation also makes it possible to generate ozone. The ozone is therefore obtained on site with considerable advantages. Furthermore, the production of ozone inside the condensate improves the capacity? of purification, in particular thanks to the microbubbles.

The invention so? conceived ? susceptible to numerous modifications and variations, all falling within the scope of the inventive concept which characterizes it. Furthermore, all the details can be replaced by other technically equivalent elements. In practice, all the materials used, as well as? the dimensions may be any, depending on the needs.

Claims (10)

1. Method of purification from lubricating substances of condensate coming from a system for conveying a pressurized fluid comprising the phases of: - introduce gas (9) containing oxygen into the condensate (8); - invest the condensate (8) and said gas (9) located inside the condensate (8) with ultraviolet radiation (7), generating the production of ozone. 2. Method according to claim 1, characterized in that said gas (9) is air. 3. Method according to claim 1 or 2, characterized in that the phase of investing the condensate (8) and said gas (9) placed inside the condensate (8) with ultraviolet radiations (7) takes place inside a compartment ( 20) for accumulation of condensate (8). 4. Method according to any one of the preceding claims, characterized in that a mixing pump (4) immersed in the condensate (8) sucks: - a part of the liquid (80) which forms said condensate (8) through a first suction mouth (41); And - said gas (9) from outside the condensate (8) by means of a second suction mouth (42); said mixing pump (4) releasing said part of the liquid (80) and bubbles of said gas (9), inside the condensate (8) in which said mixing pump (4) ? immersed. 5. Method according to any one of the preceding claims, characterized in that said ultraviolet radiations (7) have a wavelength comprised between 180 and 190 nanometres. 6. Condensate purification system from a pressurized fluid conveying system comprising: i) an environment (2) in which the condensate (8) is found; ii) means (3) for generating ozone in the condensate; said ozone generation means (3) being placed in said environment (2) and comprising: - means (31) for introducing gas containing oxygen into the environment (2); - means (32) for generating ultraviolet radiations which invest both the condensate (8) and said gas (9) determining the generation of ozone. 7. System according to claim 6, characterized in that said environment (2) is a storage compartment. 8. System according to claim 6 or 7, characterized in that the means (32) for generating ultraviolet radiations comprise a UV-C lamp which emits a wavelength comprised between 180 and 190 nanometres. 9. System according to any one of claims from 6 to 8, characterized in that said ultraviolet radiation generation means (32) are embedded in the condensate (8) inside said environment (2); said means (31) for introducing gas containing oxygen into the environment (2) comprising a mixing pump (4) placed in the condensate (8) and which draws air from the outside. 10. A fluid handling system comprising: - fluid compression means (100); -a fluid conveyance duct placed downstream of the compression means (100); -a system (11) for recovering the condensate generated by?humidity? present in the fluid that passes through the canalization; -a system (1) for purifying the condensate coming from said recovery system (11); said purification system according to any one of claims 6 to 9.