Technical Field The invention relates to the field of apparatus and methods for washing and sterilising industrial plants.

Background Art Especially, though not exclusively, the invention is usefully applied in plants in the pharmaceutical industry, such as for example granulation, mixing, dissolving, coating solid particles, bins, tanks etc.

The main aim of the present invention is to provide an especially efficient process for automatic washing, drying and sterilising of the treated surfaces of an industrial plant.

An advantage is that even the parts which do not come into direct contact with the washing liquid spraying the plant during cleaning operations are fully sterilised.

A further aim is to provide a simple and economical apparatus for realising the above-cited process.

A further aim of the invention is simply and practically to sterilise the apparatus using cold fluids.

These aims and advantages and others besides are all attained by the invention as it is characterised in the appended claims.

Disclosure of Invention Further characteristics and advantages of the present invention will better emerge

from the detailed description that follows of a preferred but non-exclusive embodiment of the invention, illustrated purely by way of a non-limiting example in the accompanying figure of the drawing, in which: figure 1 is a diagram of an apparatus realised according to the invention.

With reference to the figure of the drawing, 1 denotes in its entirety a plant comprising two combined apparatus which cooperate with one another. A first apparatus is for drying and sterilising industrial plants and a second apparatus is for washing industrial plants.

The apparatus comprises a tank 2 containing a washing liquid (for example, water) connected, through a high-pressure feed line 3 comprising a pipe including a pump 4 (for example a high-pressure pump), to one or more washing terminals 5 (for example water wand-type nozzles) which are associated with the surfaces of the plant which are to be treated. In the illustrated embodiment there is also a batcher 6 which feeds the line 3 with measured amounts of a detergent at a point upstream of the pump 4.

A short line 7 is attached to the tank 2, which will join up with an external line supplying the washing fluid, for example the municipal water supply. A further short line 8, also removably connectable to the water supply, joins the high- pressure feed line 3 at a three-way switch valve 9 predisposed (upstream of the high-pressure pump and at a non-pressurised point) selectively to connect the high-pressure feed line 3 with the tank supply 2 or with the municipal water supply through the connecting line 8. Both short connecting lines 7 and 8 are provided with an intercept valve.

The apparatus 1 comprises means for introducing a sterilising gas into the tank 2, which gas mixes with the washing liquid. The means for introducing the sterilising gas comprise a gas feed line which includes an ozoniser 10 (provided with a high-voltage generator). The ozoniser 10 takes oxygen from a tank 11 and

transforms it into ozone. Any fixed supply line of oxygen can be used. The oxygen supply line terminates inside the tank 2 with an injector 12 located close to the bottom of the tank 2 which releases the ozone (a sterilising gas) into the washing liquid, thus obtaining a mixture of the two substances.

The apparatus comprises a secondary automatic sterilising line 13 predisposed to connect selectively the tank 2 with parts of the apparatus which during normal functioning are not crossed by the washing liquid, so that these parts too can be sterilised. In the illustrated embodiment these non-contact parts are the two short water lines 7 and 8 which supply the washing liquid (water) to the tank, and the high-pressure feed line 3. During automatic sterilisation the ends of the short lines 7 and 8 are detached from the municipal water supply and joined up to the secondary automatic sterilising line 13. The secondary line 13 exhibits at one end a removable and selective connection with the short lines 7 and 8; while at its other end it exhibits a connector for selective and removable connection with a subsidiary draining line 14 of the tank 2, provided with a draining pump 15, which can on demand be used both for draining liquid remaining in the tank 2 and for automatic sterilisation of parts of the apparatus.

The drying apparatus comprises a drying line 16 predisposed to supply a drying gas to the treated surfaces of the industrial plant (of known type and not illustrated).

The drying line 16 is connected through a three-way switch valve 17 to the feed line which introduces the sterilising gas into the tank; this connection enables the sterilising gas-ozone-to be mixed with the drying gas-air. The drying line 16 is provided with a feed line which removes air from the atmosphere; along the feed line means for moving the air are arranged (for example an aspirating fan), a heater 19 and a filter 20.

The drying gas is sent towards the plant to be dried in the direction of arrow G.

The drying line 16 is connected through a conduit and a valve 17 to a gas feed line on which an ozonizer 10 (provided with a voltage generator) is provided.

The ozoniser 10 takes oxygen from a tank 11 and transforms it into ozone. Any fixed supply line of oxygen can be used. In the illustrated embodiment the valve is a three-way switch valve 17 to the feed line which introduces the sterilising gas into at least one user (in this embodiment the second washing apparatus, as will be better explained herein below), as well as enabling the sterilising gas-ozone- to be mixed with the drying gas-air before the mixture is sent on to the surfaces to be treated. Predisposing at least one further user for use with the sterilising gas supply is optional, preferable but not necessary.

The drying line 16, like the short lines and 8, is associated to a secondary recycling line 21 which is selectively connectable to the drying line 16, to create a closed automatic sterilising circuit of the drying line 16. The secondary recycling line 21 is basically a by-pass for performing, when so desired, an automatic sterilisation of the drying line 16.

The various above-mentioned parts of the apparatus 1-in particular the tank 2, the high-pressure feed line 3, the pump 4, the washing terminals 5 and the means for introducing sterilising gas, but also the drying system as well as the auto- sterilising systems with ozonised water and ozonised air-are mounted on a mobile washing unit with wheels (not illustrated).

The apparatus enables automatic sterilisation and cleaning of structural components with no need to dismount them: this is realised by means of the on- site production of sterilising gas (ozone) which is mixed with the washing liquid and thus conveyed at low temperature to the inside of the hydraulic circuit of the apparatus. The same solution is applied to the pneumatic drying circuit, with the difference that the sterilising gas is mixed with the drying gas. This solution means that the same control unit can be programmed to command both the

washing/drying operations and the automatic sterilising cycle.

Cold automatic sterilising (instead of, for example, sterilising using heated steam) of the washing and drying apparatus means that relatively-cheap parts of the apparatus itself can be used in the operation, as no compatibility with high temperatures is required.

Production and introduction of sterilising gas into the tank 2 and the pneumatic circuit are controlled (using known techniques) so that the saturation level of sterilising gas (in this embodiment ozone) mixed with the washing liquid (in this case water) or in the drying fluid (in this case air) is never exceeded, so no over- production of ozone obtains.

It has been seen that by using a high-pressure washing liquid and a mixed-in sterilising gas (i. e. in the present embodiment ozonised water) an extremely efficient wash and sterilisation is obtained of all of the treated surfaces of the plant. In the case of ozonised water, high-pressure delivery over the surfaces to be treated accelerates the transformation of the ozone contained in the water into active oxygen, which is able to sterilise even those parts of the machine which are not directly sprayed by the jets of pressurised liquids.

The invention has the advantage of concentrating the washing, the drying and sterilising operations in a single compact apparatus which is self-sufficient and mobile in that it can be mounted on wheels. It also enables a final printing of a single non-changeable report to be made of all the washing, drying and sterilisation process.

The invention also consists in the actuation of a drying and sterilising process for industrial plants in which a drying gas is taken from a source, for example the atmosphere, and sent through one or more conduits twoars at least one surface of a plant to be dried and sterilised, which is struck by the drying gas flow. The process introduces a sterilising gas into the conduits, which is mixed with the

drying gas.

The drying gas comprises ozone.

The process, which is preferably performed by an apparatus such as the one described, automatically sterilises a part of the apparatus with the drying gas flow in a closed circuit.