EP0953410A1 - Method and device for cleaning by blasting with particles - Google Patents

Abstract

The procedure consists of blasting the surface to be cleaned with a mixture of solid CO2 particles, (dry ice), mixed with crystals of sodium bicarbonate of similar mean diameter, between 200 and 800 microns. The dry ice particles are produced in a chamber (10) with an outlet pipe (11) connected to a lance by a suction pipe (12) fed with sodium bicarbonate crystals from a container (21) through a valve (23) and doser (25).

Description

The present invention is in the field of cleaning of surfaces by projection of material granules and it relates to an improved spray cleaning process as well than an apparatus for implementing this method.

A known method for cleaning surfaces consists in projecting solid particles of CO ₂ (crystalline dry ice) either in the form of granules (or pellets), or in the form of crystals originating from scraping or crushing of blocks or pieces of blocks of CO ₂ solid, formed by compression of CO ₂ crystals. The particles are projected either mechanically by centrifugal force, or pneumatically in a stream of compressed air.

This technique is illustrated for example by patents United States of America No. 4,038,786, 4,389,820 (Fong), 4,744,181 (Moore), 5.071.289, 5.288.028 (Spivak), 5.203.794 (Strafford), 4.707.951 (Gilbot), 4,965,968 (Kelsall), 5,520,572 (Opel et al).

The CO ₂ particle projection technique is a dry cleaning process, harmless to machines and respectful of the natural environment, since it uses neither solvents nor cleaning agents and the CO ₂ is directly sublimated after impact. This technique is capable of removing all kinds of residues such as chemical, of various productions, adhesives, paints, etc .... on many materials: plastic, concrete, metals, glass, wood and other composites and it finds its application in many industrial sectors: chemical, food, plastics, pneumatics, automotive, electronics, aeronautics, printing, nuclear, pharmaceutical, renovation of machines and buildings, general maintenance, etc.

The projection of CO ₂ particles on the surfaces to be cleaned weakens the dirt layer by combining significant thermal shock, large volume variation and low mechanical shock. There is therefore little risk of deterioration of the treated surfaces. In addition, as this process leaves no residue from the CO ₂ particles, it is suitable for cleaning and decontaminating production equipment "in situ", hot and in operation.

This process nevertheless has application limits. Each cleaning requires reaching a certain energy threshold to to be efficient. If this threshold is higher or very slightly lower than that available by the process (for example to remove certain paints), this process becomes either ineffective or too slow and therefore too expensive.

For oily materials, a systematic approach is necessary. We will try to push the oil and the fat towards a corner where they can be recovered with a rag, because the oil and grease withstand thermal and mechanical shock well. For oxidations, the thermal shock is ineffective because the factors of metal expansion and its oxide are very similar. In this case, the mechanical action is preponderant.

Another known method consists in spraying a pickling agent based on sodium bicarbonate, such as ARMEX® for example. This non-flammable, white, odorless, crystalline material poses no health hazard. Used in conjunction with the ACUSTRIP ^TM projection device (wet system), it eliminates a variety of coatings on flexible and rigid substrates. Regarding this process, reference can be made to United States patents No. 5,081,799, 5,083,402, 5,230,185.

• la consommation de produit décapant peut être importante (de 50 à 100 kg/h),
• utilisée à sec, la projection de particules produit une énorme quantité de très fines poussières provenant de l'éclatement des particules de bicarbonate de sodium, ce qui limite son utilisation à des zones peu sensibles, de préférence à l'extérieur,
• pour réduire cette formation de poussières, on injecte de l'eau (environ 2 à 3 l/min.) dans la tubulure de la lance (système mouillé) et dans ce cas, le système n'est plus un système de nettoyage à sec, ce qui limite son utilisation à des zones ou l'humidité est acceptée,
• sur certaines surfaces, l'utilisation d'un produit décapant peut être abrasive, et donc abímer les surfaces délicates.

The pickling agent based on sodium bicarbonate allows cleaning and pickling on site. It removes dirt, oil, grease, paint and oxides from surfaces in one operation. However, this process has various drawbacks:

• the consumption of stripper can be significant (from 50 to 100 kg / h),
• used dry, the projection of particles produces a huge amount of very fine dust from the bursting of sodium bicarbonate particles, which limits its use to insensitive areas, preferably outdoors,
• to reduce this formation of dust, water is injected (approximately 2 to 3 l / min.) into the nozzle of the lance (wet system) and in this case, the system is no longer a dry cleaning system , which limits its use to areas where humidity is accepted,
• on certain surfaces, the use of a stripping product can be abrasive, and therefore damage delicate surfaces.

The Japanese patent application published under the number 09011132 (filed on June 23, 1995) proposes a method and a device in which is used, without specifying the proportions, a mixture of dry ice pellets, sodium bicarbonate powder and sodium ash, glued together beforehand.

The invention aims to eliminate, by an improved process, the disadvantages of known techniques.

This process according to the invention consists in adding to the stream of solid CO ₂ particles, a relatively small predetermined quantity of an etching agent, in particular sodium bicarbonate, by choosing for this purpose solid CO ₂ particles whose diameter medium is of the same order of magnitude as that of sodium bicarbonate crystals. This average diameter is preferably between 200 and 800 micrometers. This choice allows the most rational use of a given volume of solid CO ₂ because each particle of this size is active before subliming, unlike what occurs with larger granules or pellets, a large mass of each has no contact with the surface to be cleaned and is therefore wasted.

The higher efficiency of solid CO ₂ , due to this choice of size and therefore to a reduced flow rate of solid CO ₂ required, is further supplemented by significantly less, if not zero, cooling compared to the known processes of fragile elements under the film of material to be removed.

The amount of pickling agent added is for example from 0 to 50 g / minute for a flow of CO ₂ particles of 100 to 1,500 g / minute approximately. Even at very low dosage, the addition of the stripping agent allows a marked increase in the mechanical cleaning action by the CO ₂ particles, and allows for example the stripping of paints, the removal of oxides or the elimination of very resistant covers. The addition of the stripping agent, even at very low doses, also allows degreasing of the treated surfaces, which is not possible with CO ₂ particles alone.

As the dosage of the stripping agent is very low, this process can be used dry without adding water, and without any significant production of dust. In fact, the amount of product stripper added generally remains less than or at most equal to the amount of dirt removed.

The method of the invention provides, in a particular embodiment, that the particles of solid CO ₂ are mixed with the sodium bicarbonate crystals as the mixture is consumed. Therefore, one can easily adapt, reduce or stop the intake of sodium bicarbonate at any time, when it proves unnecessary during operation. This further reduces the production of dust during cleaning.

The invention also relates to an apparatus intended for the implementation of the method according to the invention.

Other details and features of the invention will emerge secondary claims and the description of the drawings which are annexed to this memorandum and which illustrate, by way of example not limiting, the method and particular embodiments of the device according to the invention.

Figure 1 schematically illustrates the implementation of the invention in a first embodiment.

Figure 2 schematically illustrates the implementation of the invention in a second embodiment.

Figure 3 shows, on a larger scale, a detail of the device shown in figure 2.

In the various figures, the same reference notations designate identical or analogous elements. The implementation of the process according to the invention is done according to the system of incorporation of the particles of solid CO ₂ in the flow of compressed air.

In a first case, illustrated by FIG. 1, the solid particles of CO ₂ (coming from scraping or crushing a block or pieces of blocks of compressed dry ice or pellets) are sucked into the stream compressed air by passing it through a venturi located just upstream of the spray lance. Referring to FIG. 1, the reference sign 10 designates an apparatus for producing these particles, known per se, having a collecting pipe 11, hereinafter referred to as (outlet) nozzle 11, for solid CO ₂ particles, the reference sign 12 designates the suction line for the particles to a lance 15, the reference sign 14 designates a compressed air inlet pipe in the lance 18. The pipes 12 and 14 open in the associated venturi with a spear.

In accordance with the invention, a quantity of pickling agent is added at a low dose to the flow of the CO ₂ particles. To this end, to the particle production apparatus 10 is added a device 20 essentially comprising a reservoir 21 preferably with a conical base, containing for example approximately 5 kg of pickling agent. Under the cone of the reservoir 21 is a closing valve 23, manual or pneumatically controlled. In the case of a pneumatic control, this can be connected directly in parallel to the pneumatic control circuit coming from the trigger of the lance.

The valve 23 communicates with a metering device 25 for the pickling agent, which device communicates by a transparent pipe 26 with a T-connector 27, placed between the nozzle 11 and the suction pipe 12. When the opening of the valve 23, the pickling agent whose flow rate is regulated by the metering device 25, falls by gravity into the pipe 12, where it is sucked with the CO ₂ particles towards the venturi of the lance 15, before being sprayed, mixed with CO ₂ , on the surface to be treated. The transparent pipe 26 between the metering device 25 and the connector 27 makes it possible to visualize for the operator the flux of pickling agent and, if necessary, a blockage by a foreign body in the metering device.

If, for example, the pickling agent is not excellent particle size, it is possible to place against the wall of the tank 21 a small pneumatic vibrator 22, controlled at the same time as the valve 23 and which, by its vibrations, prevents the formation of a material bridge in the reservoir 21.

The entire device 20 is designed so that it can be quickly connected to the particle production device 10 without the need for any special tool. This converts to a few minutes an existing device in device for the implementation of the invention.

In another application mode, illustrated in FIG. 2, the particles of solid CO ₂ coming from the apparatus 10 are introduced into the flow of compressed air by a lock system located on the apparatus for producing particles, usually under the container containing or producing the CO ₂ particles.

In this case, the particle production apparatus 10, known per se, has an outlet nozzle 11 which delivers the flow of compressed air charged with CO ₂ particles. The device 30 according to the invention is fixed to the apparatus 10 for producing particles, just above the connection of the suction line 12 to the lance.

The tank 31 containing the pickling agent is designed to withstand the maximum pressure allowed in the compressed air system of the projection device. The outlet port 33 of the tank communicates with a metering device 25 fixed by a pipe 26 to a fitting in T 27 placed between the nozzle 11 and the pipe 12 towards the lance. On this same line 12, and following the connection 27, there is a second T-connector 28 to which a flexible pipe 29 connected to a compressed air inlet 35 from the reservoir 31.

This compressed air inlet 35 is connected to a hollow slide 36 (see Figure 3) on which a cone 37 is mounted closing the filling orifice 38 of the reservoir 31.

When the suction line 12 is pressurized, the pressure communicated by the line 29 lifts the cone 37 and pushes it firmly against the filling orifice 38 of the reservoir. As the cone 37 then slightly emerges from its slide 36, the compressed air coming from the pipe 12 puts the reservoir 31 under pressure. In fact, a pressure balance takes place between the line 12 and the reservoir 31 containing the pickling agent. This can then escape through the metering device 25 to be incorporated into the compressed air flow, containing the CO ₂ particles, which passes through the suction line 12.

If, for example, the pickling agent is not excellent particle size, it is possible to place against the wall of the tank 31 a small pneumatic vibrator 32 which, by its vibrations, prevents formation of a material bridge in the tank.

The entire device 30 is designed so that it can be connected to the projection device without the need for tools particular, and with fast connections. This converts to a few minutes an existing projection device in device for the implementation of the invention.

The embodiments illustrated in the drawings and described above are non-limiting examples used to illustrate the principle of implementation of the method according to the invention. Variants are possible and fall within the normal competence of the skilled person.

As they are arranged, the devices of the invention mix the particles of solid CO ₂ with the sodium bicarbonate crystals as the mixture is consumed, directly before it enters the associated projection lance.

By this arrangement, the volume or weight ratio of the solid CO ₂ particles and the sodium bicarbonate crystals can be modified at any time, until the flow rate of the latter is canceled.

Means, not shown in the above-mentioned apparatus 10, for injecting dry compressed air either into the outlet nozzle 11 or into the hopper upstream of this nozzle, can be provided to thereby prevent the humidity of the ambient air sucked by the venturi of the lance through this hopper, at the same time as the CO ₂ particles, condenses on contact with them and promotes agglutination of the bicarbonate to itself, either in the fitting 27 where it is joined to the CO ₂ particles either in the venturi of the lance.

Claims (11)

Method for cleaning surfaces by spraying solid CO ₂ particles, in which a predetermined quantity of pickling agent particles, in particular sodium bicarbonate crystals, is mixed with the stream of solid CO ₂ particles, characterized in that that for this purpose solid CO ₂ particles are chosen whose average diameter is of the same order of magnitude as that of the sodium bicarbonate crystals. Process according to Claim 1, characterized in that sodium crystals and solid CO ₂ particles are chosen whose average diameter is between 200 and 800 micrometers. Process according to either of Claims 1 and 2, characterized in that the particles of solid CO ₂ are obtained either by scraping or by crushing of blocks or pellets of CO ₂ . Process according to any one of Claims 1 to 3, characterized in that the particles of solid CO ₂ are mixed with the sodium bicarbonate crystals as the mixture is consumed, in particular in the pipe which brings the mixture to the spray lance of it on a surface to be cleaned. Process according to Claim 4, characterized in that, during the projection of the mixture, the volume or weight ratio of the particles of solid CO ₂ and of the sodium bicarbonate crystals is modified, until the flow rate of the latter is canceled. . Process according to any one of Claims 1 to 5, characterized in that the dosage of the sodium bicarbonate crystals is in the range from approximately 0 to 50 g / minute for a flow rate of CO ₂ particles from 100 to 1,500 g / minute approximately. Apparatus for carrying out the method according to any one of Claims 1 to 6, characterized in that it comprises an apparatus for producing solid CO ₂ particles (10) having an outlet nozzle (11) for the flow of solid CO ₂ particles, and a working lance connected by a pipe (12) to said outlet nozzle and to a pipe (14) for supplying compressed air, characterized in that it further comprises a device (20) arranged to introduce into the stream of solid CO ₂ particles a predetermined quantity of sodium bicarbonate crystals as a pickling agent. Apparatus according to claim 7, characterized in that the above-mentioned device (20) for introducing the predetermined quantity of sodium bicarbonate crystals comprises a reservoir (21) for containing them and having a closing valve (23), and a metering device (25) connected between the closing valve (23) and a fitting (27) between the aforementioned outlet nozzle (11) and the pipe (12) sucking the flow of CO ₂ particles towards the lance. Apparatus according to either of Claims 7 and 8, characterized in that it comprises means for injecting compressed air dry in the nozzle (11) or the hopper which precedes it. Apparatus for carrying out the method according to any one of Claims 1 to 6, characterized in that it comprises an apparatus for producing solid CO ₂ particles (10) having an outlet nozzle (11), for the solid CO ₂ particles entrained in a stream of compressed air, and a working lance connected by a suction pipe (12) to said outlet nozzle (11), characterized in that it further comprises a device ( 30) arranged to introduce into the flow of compressed air entraining the aforementioned CO ₂ particles a predetermined amount of sodium bicarbonate crystals as a stripping agent. Apparatus according to claim 10, characterized in that the above-mentioned device (30) for introducing the predetermined quantity of sodium bicarbonate crystals comprises a reservoir (31) containing these, said reservoir (31) having an outlet orifice (33 ) communicating with a metering device (25) connected to a first connector (27) between the aforementioned outlet nozzle (11) and the pipe (12) sucking the flow of compressed air and CO ₂ particles towards the lance, said tank (31) further having a compressed air inlet (35) connected by a line (29) and a second connector (28) to the suction line (12) leading to the lance.

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