EP3822023A1 - Device for dry ice treatment of surfaces and method for treating surfaces - Google Patents

Abstract

The invention relates to a device (1) for dry ice treatment of surfaces (12), the device (1) having a dry ice source (2) for providing dry ice, a mixing unit (3), and a compressed air source (4) connected to the mixing unit (3) in terms of flow ) and a conditioning unit (5) connected in terms of flow to the mixing unit (3) for adapting a dry ice particle / compressed air mixture (11) provided by the mixing unit (3) to application-specific conditions. The conditioning unit (5) is designed to condition the dry ice particle / compressed air mixture (11) in such a way that a predetermined or determinable proportion of the dry ice particles in the dry ice particle / compressed air mixture (11) is at a predetermined or determinable distance in front of the surface to be treated (12) ) completely sublimated.

Description

The invention relates to a device for dry ice treatment and in particular dry ice cleaning of surfaces and a corresponding method.

Devices for dry ice cleaning of surfaces are generally known. In such devices, which are sometimes also referred to as dry ice blasting systems, a dry ice blast is generated in each case, in which dry ice particles, such as dry ice pellets, are accelerated by means of compressed air to a speed of about 300 meters per second and shot at the surface to be cleaned, where they generate a punctual thermal shock. The coating to be removed, in particular contaminants, on the surface to be cleaned contracts and the subsequent dry ice particles in connection with the kinetic energy contained therein causes the contamination to flake off. The dry ice particles sublime immediately upon impact, leaving a dry surface.

Dry ice is made from liquid CO2. In a pelletizer, liquid CO2 is expanded under controlled conditions. This physical process creates dry ice snow. This is pressed through an extruder plate into round, hard pellets, which have elongated grains with a diameter of 1.7 mm to 3.0 mm. Dry ice has a temperature of approx. -79 ° C. Carbon dioxide (CO2) is an odorless, non-flammable gas that is 1.5 times heavier than air. The earth's atmosphere normally contains about 0.03% CO2. Today, CO2 is mainly a by-product of various chemical processes and is stored in tanks after extraction.

Dry ice blasting systems represent a modern alternative to conventional industrial cleaning methods. What is unique about the use of dry ice as a blasting agent is that dry ice particles change into gaseous form at the moment they hit the surface to be cleaned, i.e. sublime. This means that after treatment, the surface is left dry and clean, with no cleaning or abrasive residues. As it is a completely dry and electroless process, dry ice blasting can be used in areas where other processes are impossible. For example, electric motors and technical systems with electrical, pneumatic and hydraulic components can be cleaned without having to shut them down or dismantle them. In addition, dry ice blasting is suitable for a variety of other applications, such as cleaning machines, electrical installations, any surfaces and shapes.

When cleaning, dry ice particles are accelerated to the speed of sound using compressed air before they hit the surface to be treated. The three different factors already mentioned above contribute to the cleaning effect: firstly, when the dry ice particles hit the surface, it loosens at the speed of sound and bursts apart - kinetic effect.

On the other hand, the low temperature of the dry ice particles makes the surface brittle, leads to the formation of cracks and contributes to its detachment, since the bond between the surface and the surface below is reduced. This means that dry ice also gets under the surface - thermal effect.

Thirdly, the dry ice penetrates the surface and evaporates immediately, which results in an approx. 700 to 1,000-fold increase in volume. This explosive reaction lifts the covering off the surface - sublimation effect / explosion effect. A damp layer, such as oil or Grease - similar to high-pressure cleaning - is carried away by the air flow. In contrast to high-pressure cleaning, however, the cleaned surface is left dry and clean.

Since dry ice evaporates immediately when it hits the surface to be treated and thus leaves no waste product, only the removed layer has to be disposed of after the dry ice blasting. This can usually be swept up on the floor below the treated object or removed with the help of a vacuum cleaner.

Dry ice blasting can be seen as an alternative to high-pressure cleaning and other conventional blasting methods that use various blasting agents such as sand, water, glass or plastic granulate. It is ideal for removing glue, varnish, oil, grease, coal dust, soot, lubricants and bitumen.

No harmful chemicals or solvents are used in dry ice blasting. The operating personnel are therefore not exposed to vapors or the like during cleaning. There are also no disposal costs for such chemicals.

Even if dry ice blasting is gentle on materials and surfaces compared to high pressure cleaning and other conventional blasting methods that use various blasting agents, the areas of application of dry ice blasting technology are limited with conventional dry ice blasting systems. In particular, conventional dry ice blasting systems, in which the dry ice particles are shot at the surface to be treated at a speed of about 300 meters per second, cannot be regarded as non-abrasive for certain surfaces. This is especially true for the sensitive surfaces such as nickel, chrome and soft aluminum.

In addition to this, conventional dry ice blasting systems show limits in the treatment of textiles or other open-pored objects, plexiglass, highly polished aluminum and especially ceramics, ceramic honeycombs from 3D production, circuit boards and printed circuit boards. Due to the kinetic energy of the dry ice particles shot onto the surfaces to be treated, the application range of dry ice blasting systems is correspondingly limited.

The present invention is therefore based on the object of specifying a device for dry ice treatment and, in particular, dry ice cleaning of surfaces, whereby a broader application is made possible while avoiding the disadvantages mentioned of the conventional dry ice blasting systems.

Furthermore, the invention is based on the object of specifying a corresponding method for dry ice treatment and, in particular, dry ice cleaning of surfaces.

With regard to the device, the object on which the invention is based is achieved by the subject matter of independent claim 1, with advantageous developments of the device according to the invention being specified in the corresponding dependent claims. With regard to the method, the object on which the invention is based is achieved by the subject matter of the independent patent claim 15.

Accordingly, the invention relates in particular to a device for dry ice treatment and in particular dry ice cleaning of surfaces, the device being a dry ice source for providing dry ice, in particular in the form of dry ice particles, a mixing unit fluidly connected or connectable to the dry egg source, and a compressed air source fluidly connected or connectable to the mixing unit having. According to the invention, the device further comprises a conditioning unit fluidly connected or connectable to the mixing unit for adapting a dry ice particle / compressed air mixture provided by the mixing unit to application-specific conditions before the dry ice particle / compressed air mixture is applied to the surface to be treated. The conditioning unit is designed to condition the dry ice particle-compressed air mixture in such a way that a pre-determined or determinable proportion of the dry ice particles in the dry ice particle-compressed air mixture completely sublimates at a pre-determined or determinable distance in front of the surface to be treated.

The advantages that can be achieved with the device according to the invention are obvious: by providing a conditioning unit with which a mixture of dry ice particles and compressed air provided by the mixing unit of the device can be adapted to application-specific conditions before the dry ice particle-compressed air mixture is applied to the surface to be treated, the dry ice particle-compressed air mixture can be adapted in such a way that the dry ice treatment of the surface is completely non-abrasive and therefore extremely gentle on the material and surface, as with the aid of the conditioning unit Among other things, the wear caused by the kinetic energy of the dry ice particles in conventional dry ice blasting systems can be prevented.

The mixture of dry ice particles and compressed air can be conditioned in such a way that an undesired deposit is removed from the surface to be treated without damaging the layer underneath. The device and the corresponding method can therefore also be used on sensitive surfaces such as nickel, chromium and soft aluminum. But Plexiglas and high-gloss polished aluminum can also be cleaned without the surface becoming matt.

By conditioning the mixture of dry ice particles and compressed air, the thermal load on the material to be cleaned can also be significantly reduced compared to conventional dry ice blasting systems.

On the other hand, the invention provides that the conditioning unit is designed to condition / adapt the dry ice particle-compressed air mixture before it is applied to the surface to be treated in such a way that a predetermined or determinable proportion of the dry ice particles in the dry ice particle-compressed air mixture is predefined or determinable Distance in front of the surface to be treated is completely sublimated. In this way, the kinetic load on the treated surface due to the impact of dry ice particles at high speed can be significantly reduced. On the other hand, the sublimation effect is still present, since the distance in front of the surface to be treated, in which the predetermined or determinable proportion of the dry ice particles sublimates in the dry ice particle-compressed air mixture, is selected accordingly.

It is thus conceivable, for example, that with the aid of the conditioning unit, preferably automatically and even more preferably optionally automatically, the distance between a Sublimation area in front of the surface to be treated can be adjusted according to the application. Here, the term “sublimation area” is to be understood as the area in which the previously determined or determinable proportion of the dry ice particles in the dry ice particle / compressed air mixture sublimes completely.

With the conditioning unit, all of the parameters of the dry ice particle / compressed air mixture that are essential for dry ice treatment and in particular dry ice cleaning can preferably be adapted in an application-specific manner, namely before the dry ice particle / compressed air mixture is applied to the surface to be treated.

According to embodiments of the device according to the invention, it is provided that the conditioning unit is designed to set an average size and in particular an average diameter of the dry ice particles in the dry ice particle-compressed air mixture, in particular application-specifically, preferably automatically and even more preferably optionally automatically.

According to implementations of the last-mentioned embodiment, it is provided that the conditioning unit has at least one filtration device, the dry ice particle-compressed air mixture to be conditioned being passed through this filtration device before the dry ice particle-compressed air mixture is applied to the surface to be treated. The filtration device is designed to allow only dry ice particles with a particle size that does not exceed a predetermined or determinable value to pass.

According to embodiments, a mesh size of the filtration device can be set in order to set a critical particle size of the dry ice particles in the dry ice particle / compressed air mixture, up to which dry ice particles can pass the filtration unit.

Since the particle size of the dry ice particles in the dry ice particle-compressed air mixture can be varied in an application-specific manner with the aid of the conditioning unit, the kinetic load on the surface to be treated when the dry ice particle-compressed air mixture is applied can be regulated and, in particular, reduced as required.

In particular, according to implementations of the device according to the invention, it is provided that the conditioning unit is designed, preferably automatically and more preferably optionally automatically, the distance of the sublimation area from the surface to be treated as a function of an average size and in particular as a function of an average diameter of the dry ice particles in the dry ice particles -Adjust the compressed air mixture.

1. (a) dem zehn- bis sechsfachen des mittleren Durchmessers der Trockeneispartikel in dem Trockeneispartikel-Druckluftgemisch entspricht; oder
2. (b) dem sechs- bis vierfachen und insbesondere dem 4,5-fachen des mittleren Durchmessers der Trockeneispartikel in dem Trockeneispartikel-Druckluftgemisch entspricht; oder
3. (c) weniger als dem vierfachen des mittleren Durchmessers der Trockeneispartikel in dem Trockeneispartikel-Druckluftgemisch entspricht; oder
4. (d) mindestens dem fünffachen des mittleren Durchmessers der Trockeneispartikel in dem Trockeneispartikel-Druckluftgemisch entspricht.

According to implementations of the last-mentioned embodiment, the conditioning unit is designed to condition the dry ice particle-compressed air mixture, preferably automatically and even more preferably, optionally, automatically, in such a way that the distance between the sublimation area and the surface to be treated is preferably:

1. (a) corresponds to ten to six times the mean diameter of the dry ice particles in the dry ice particle-compressed air mixture; or
2. (b) corresponds to six to four times and in particular 4.5 times the mean diameter of the dry ice particles in the dry ice particle-compressed air mixture; or
3. (c) is less than four times the mean diameter of the dry ice particles in the dry ice particle-compressed air mixture; or
4. (d) corresponds to at least five times the mean diameter of the dry ice particles in the dry ice particle-compressed air mixture.

In this context, it is particularly conceivable that an interface device is provided for preferably manual selection and setting of one of the distance ranges (a) to (d). It is advisable here for the interface device to be arranged on a spray gun for applying the conditioned mixture of dry ice particles and compressed air to the surface to be treated.

Because the conditioning unit is designed, preferably automatically, and more preferably optionally, automatically, the distance of the sublimation area from the surface to be treated as a function of an average size and in particular as a function of an average diameter of the To set dry ice particles in the dry ice particle / compressed air mixture, the sublimation effect used for surface treatment and in particular surface cleaning can be selected to be particularly gentle on the material and, in particular, to be application-specific. The sublimation effect is lowest (and in this way also a material load on the surface to be treated) when the distance of the sublimation area from the surface to be treated corresponds to ten to six times the mean diameter of the dry ice particles in the dry ice particle-compressed air mixture.

If, on the other hand, the distance of the sublimation area from the surface to be treated is less than four times the mean diameter of the dry ice particles in the dry ice particle-compressed air mixture, the surface to be treated lies completely in the sublimation area, i.e. in the area of the volume expansion of the dry ice particles during the sublimation process. In this way, a particularly intensive, but nonetheless gentle surface treatment is possible.

According to developments of the device according to the invention, it is provided in particular that the compressed air source of the device is designed to supply a predetermined or determinable amount of compressed air to the mixing unit per unit of time, the amount of compressed air supplied to the mixing unit per unit of time being in particular an amount supplied to the mixing unit per unit of time depends on dry ice particles. In this way, the jet pressure of the dry ice particle / compressed air mixture can be set variably and in particular selected in such a way that an undesired deposit is removed from the surface to be treated without damaging the layer underneath.

In order to enable a particularly variable and fine adjustment of the jet pressure, it is provided according to further developments of the last-mentioned embodiment that the compressed air source is also designed to supply the dry ice particle / compressed air mixture with a predetermined or definable amount of compressed air per unit of time as additional compressed air. This additional compressed air serves as transport air, the amount of additional compressed air supplied to the dry ice particle / compressed air mixture per unit of time, in particular, being independent of the amount of dry ice particles supplied to the mixing unit per unit of time.

According to preferred implementations, the conditioning unit is designed in particular to control or regulate the amount of additional compressed air supplied per unit of time from the compressed air source of the mixing unit and / or the amount of additional compressed air supplied per unit of time from the compressed air source in such a way that the total pressure and / or the dynamic and / or static pressure of the dry ice particle-compressed air mixture can be set variably in a range between 0.1 bar to 24 bar at the predetermined or definable distance in front of the surface to be treated.

In a further development of the device according to the invention, the compressed air source is also designed to supply the dry ice particle / compressed air mixture with additional compressed air, which primarily does not serve as additional compressed air for transport, but as shaping air. For example, it is conceivable that the dry ice particle / compressed air mixture is surrounded as a core jet by a sheath flow of shaping air. In this context, it is particularly conceivable that the temperature of the shaping air is different from the temperature of the dry ice particle-compressed air mixture, i.e. different from the core jet. In particular, the sheath flow (which is formed by the shaping air) can have a temperature of +20 ° C to +80 ° C, in particular +60 ° C to +80 ° C. This allows the surface to be treated to be heated.

If necessary, heating the surface to be treated can have significant advantages in surface treatment, since the heating does not or only slightly cools the heat capacity due to the extraction of heat due to the core beam when the dry ice particles transition from the solid to the gaseous state. In this context, it makes sense that the sheath flow adjusts the dry ice particle-compressed air mixture, which preferably has a temperature between -10 ° C and -130 ° C, in a parallelizing or focusing manner in order to enable a particularly efficient and targeted surface treatment.

1. (i) ein Abstand der Sprühpistole zu der zu behandelnden Oberfläche;
2. (ii) eine Geschwindigkeit des konditionierten Trockeneispartikel-Druckluftgemisches am Düsenauslass der Sprühpistole;
3. (iii) einen Gesamtdruck und/oder statischen und/oder dynamischen Druck des konditionierten Trockeneispartikel-Druckluftgemisches am Düsenauslass der Sprühpistole; und/oder
4. (iv) eine Temperatur des konditionierten Trockeneispartikel-Druckluftgemisches am Düsenauslass der Sprühpistole.

According to implementations of the device according to the invention, it has at least one manual or automatic spray gun for applying the conditioned mixture of dry ice particles and compressed air to the surface to be treated. In this context, it is conceivable that the at least one A corresponding sensor system is assigned to the spray gun, with which at least one of the following application-specific parameters can preferably be recorded automatically:

1. (i) a distance from the spray gun to the surface to be treated;
2. (ii) a velocity of the conditioned dry ice particle-compressed air mixture at the nozzle outlet of the spray gun;
3. (iii) a total pressure and / or static and / or dynamic pressure of the conditioned dry ice particle / compressed air mixture at the nozzle outlet of the spray gun; and or
4. (iv) a temperature of the conditioned dry ice particle-compressed air mixture at the nozzle outlet of the spray gun.

• eine mittlere Größe und insbesondere einen mittleren Durchmesser der Trockeneispartikel in dem Trockeneispartikel-Druckluftgemisch;
• eine Geschwindigkeit des Trockeneispartikel-Druckluftgemisches;
• einen Gesamtdruck und/oder statischen und/oder dynamischen Druck des Trockeneispartikel-Druckluftgemisches;
• eine Temperatur des Trockeneispartikel-Druckluftgemisches; und/oder
• einen Anteil der Trockeneispartikel in dem Trockeneispartikel-Druckluftgemisch.

In a preferred development of the last-mentioned embodiment, the device according to the invention has at least one control or regulating device which is designed to control the conditioning unit, the dry ice source and / or the compressed air source in such a way that, depending on at least one parameter detected with the aid of the sensor system, at least one of the following parameters of the dry ice particle / compressed air mixture can preferably be set automatically and controlled:

• a mean size and in particular a mean diameter of the dry ice particles in the dry ice particle-compressed air mixture;
• a speed of the dry ice particle-compressed air mixture;
• a total pressure and / or static and / or dynamic pressure of the dry ice particle / compressed air mixture;
• a temperature of the dry ice particle-compressed air mixture; and or
• a proportion of the dry ice particles in the dry ice particle-compressed air mixture.

1. (i) zwischen 10 % bis 90 % aller im Trockeneispartikel-Druckluftgemisch enthaltenen Trockeneispartikel entspricht; oder
2. (ii) zwischen 20 % bis 80 % aller im Trockeneispartikel-Druckluftgemisch enthaltenen Trockeneispartikel entspricht; oder
3. (iii) zwischen 30 % bis 70 % aller im Trockeneispartikel-Druckluftgemisch enthaltenen Trockeneispartikel entspricht; oder
4. (iv) zwischen 40 % bis 60 % aller im Trockeneispartikel-Druckluftgemisch enthaltenen Trockeneispartikel entspricht.

Finally, according to embodiments of the present invention, it is provided that the previously determined or determinable proportion of dry ice particles in the dry ice particle-compressed air mixture is preferably adjustable in such a way that the proportion:

1. (i) corresponds to between 10% and 90% of all dry ice particles contained in the dry ice particle / compressed air mixture; or
2. (ii) corresponds to between 20% and 80% of all dry ice particles contained in the dry ice particle-compressed air mixture; or
3. (iii) corresponds to between 30% and 70% of all dry ice particles contained in the dry ice particle / compressed air mixture; or
4. (iv) corresponds to between 40% and 60% of all dry ice particles contained in the dry ice particle-compressed air mixture.

In summary, it can therefore be stated that the device according to the invention can automatically or optionally automatically set all parameters essential for the treatment and in particular cleaning of surfaces in such a way that the treatment can be carried out particularly efficiently and specifically, but nevertheless extremely gently. In this way, the dry ice treatment process can also be used, for example, in the manufacture of semiconductors or in the treatment of open-pored, relatively sensitive surfaces.

The invention also relates to a method for treating surfaces, in particular for cleaning and / or refining surfaces, a device of the type according to the invention preferably being used for this purpose. In particular, the process for cleaning and / or refining surfaces has the following process steps:
A dry ice particle / compressed air mixture is provided and conditioned to application-specific conditions, the conditioned dry ice particle / compressed air mixture then being applied to the surface to be treated. In particular, it is provided that the provided dry ice particle / compressed air mixture is conditioned in such a way that a predetermined or determinable proportion of the dry ice particles in the dry ice particle / compressed air mixture completely sublimated at a predetermined or determinable distance in front of the surface to be treated.

An exemplary embodiment of the device according to the invention is described in more detail below with reference to the drawings.

FIG. 1a-c

schematisch das erfindungsgemäße Verfahren zur Behandlung von Oberflächen, insbesondere zur Reinigung und/oder Veredelung von Oberflächen; und

FIG. 2

schematisch eine exemplarische Ausführungsform der erfindungsgemäßen Vorrichtung zur Behandlung von Oberflächen, insbesondere zur Reinigung und/oder Veredelung von Oberflächen.

Show it:

FIG. 1a-c

schematically, the method according to the invention for treating surfaces, in particular for cleaning and / or refining surfaces; and

FIG. 2

schematically an exemplary embodiment of the device according to the invention for treating surfaces, in particular for cleaning and / or refining surfaces.

In the FIG. 2 The schematically shown exemplary embodiment of the device 1 according to the invention has a dry ice source 2 for providing dry ice, in particular in the form of dry ice particles, a compressed air source 4 and a mixing unit 3, the mixing unit 3 being connected in terms of flow to the dry ice source 2 on the one hand and the compressed air source 4 on the other serves to generate a dry ice particle / compressed air mixture 14 from the dry ice provided by the dry ice source 2 and the compressed air provided by the compressed air source 4.

According to the invention, a conditioning unit 5 is also used, with which a dry ice particle / compressed air mixture 14 provided or to be provided by the mixing unit 3 can be adapted to application-specific conditions before the dry ice particle / compressed air mixture 14 is applied to the surface to be treated.

In the FIG. 2 The dry ice source 2 shown schematically can have a device 1 for generating solid CO2 particles, this device 1 comprising, for example, a snow chamber which has an inlet for CO2 and a compressor for compressing CO2 snow located in the snow chamber having. In this context it is conceivable that the snow chamber is closed on one side by a matrix provided with openings.

As an alternative to this, however, it is also conceivable that the dry ice source 2 of the device 1 according to the invention has a storage container for storing dry ice particles the size of rice grains, so-called CO2 pellets.

The CO2 pellets are produced by taking liquid carbon dioxide from an insulated tank, in which the carbon dioxide is usually stored at a pressure between 12 and 22 bar, and releasing it to atmospheric pressure via nozzles in a snow chamber. When the liquid carbon dioxide is expanded, a mixture of CO2 snow and cold CO2 gas is created. The gas phase is separated from the CO2 snow and the CO2 snow material is compressed by a compressor. A piston compressor, for example, is used for this purpose. The resulting block of dry ice is then pressed through a die to generate solid strands of CO2, which are then cut into pellets about the size of a grain of rice using a suitable breaking tool.

The dry ice particles provided by the dry ice source 2, such as dry ice pellets, are metered into a compressed air flow provided by the compressed air source 4 in the mixing unit 3 and conveyed with this to a jet nozzle. In the device 1 according to the invention, the compressed air flow has a pressure between 0.1 bar to 24 bar, while the dry ice particles (CO2 pellets) are present at atmospheric pressure. For metering the dry ice particles into the air pressure stream, a pressure lock is preferably used, which is shown in the schematic drawing according to FIG FIG. 2 is not shown.

When the dry ice particle-compressed air mixture 14 generated in the mixing unit 3 of the device 1 according to the invention is applied to the surface 12 to be treated, the dry ice particles in the dry ice particle-compressed air mixture 14 are accelerated with the aid of the compressed air provided by the compressed air source 4, and the dry ice particle compressed air flow is - as in FIG. 1a indicated - directed at the surface 12 to be cleaned or treated. According to the invention, it is provided in this context that the dry ice particle-compressed air mixture 14 is conditioned with the aid of the conditioning unit 5 in such a way that a predetermined or determinable proportion of the dry ice particles in the dry ice particle-compressed air mixture 14 is at a predetermined or determinable distance from the surface 12 to be treated completely sublimated. This so-called sublimation area 15, that is to say the area in which the predetermined or determinable proportion of the dry ice particles in the dry ice particle / compressed air mixture 14 is completely sublimated, is shown in FIG FIG. 1a indicated accordingly.

In this context, it is particularly provided that not only the proportion of dry ice particles in the dry ice particle-compressed air mixture 14, which sublimates completely in the sublimation area 15, but also the distance of the sublimation area 15 from the surface 12 to be treated is preferably variably adjustable.

Thus, according to implementations of the device 1 according to the invention, it is provided that the pre-determined or determinable proportion of dry ice particles in the dry ice particle-compressed air mixture 14 is preferably adjustable such that the proportion corresponds to between 10% to 90% of all dry ice particles contained in the dry ice particle-compressed air mixture 14, or corresponds to between 20% to 80% of all dry ice particles contained in the dry ice particle / compressed air mixture 14, or corresponds to between 30% to 70% of all dry ice particles contained in the dry ice particle / compressed air mixture 14, or corresponds to between 40% to 60% of all dry ice particles contained in the dry ice particle / compressed air mixture 14.

Of course, other ranges for the proportion of dry ice particles are also conceivable.

With regard to the distance of the sublimation area 15 from the surface 12 to be treated, it is provided according to the exemplary embodiment of the device 1 according to the invention that the conditioning unit 5 is designed to preferably automatically and more preferably optionally automatically condition the dry ice particle-compressed air mixture 14 in such a way that optionally the distance of the sublimation area 15 from the surface to be treated 12 corresponds to ten to six times the mean diameter of the dry ice particles in the dry ice particle / compressed air mixture 14, or to six to four times and in particular 4.5 times the mean diameter of the dry ice particles in the dry ice particle / compressed air mixture 14, or less than four times that corresponds to the mean diameter of the dry ice particles in the dry ice particle-compressed air mixture 14, or corresponds to at least five times the mean diameter of the dry ice particles in the dry ice particle-compressed air mixture 14.

In particular, it is thus provided that the distance between the sublimation area 15 and the surface 12 to be treated can be set as a function of an average size and in particular as a function of an average diameter of the dry ice particles in the dry ice particle / compressed air mixture 14 with the aid of the conditioning unit 5.

The distance between the sublimation area 15 can be set variably in particular by varying the mean size and in particular the mean diameter of the dry ice particles in the dry ice particle / compressed air mixture 14, and / or by varying the amount of compressed air supplied per unit of time from the compressed air source 4 to the mixing unit 3 accordingly becomes.

In order to set the mean size of the dry ice particles in the dry ice particle / compressed air mixture 14, the device 1 according to the invention has according to FIG FIG. 2 a filtration device 7, wherein the dry ice particle-compressed air mixture 14 to be conditioned is passed through this filtration device 7, and wherein the filtration device 7 is designed to allow only dry ice particles with a particle size that does not exceed a predetermined or determinable value to pass.

In this context it is conceivable, for example, that a mesh size of the filtration device 7 can be set in order to be able to set a critical particle size of the dry ice particles in the dry ice particle / compressed air mixture 14.

The compressed air source 4 of the device 1 according to the invention is not only used to generate a predetermined or determinable amount of compressed air per unit of time Mixing unit 3, the amount of compressed air fed to the mixing unit 3 per unit of time depending in particular on an amount of dry ice particles fed to the mixing unit 3 per unit of time, but also on a predetermined or definable amount of compressed air per unit of time as additional compressed air 8 to that of the mixing unit 3 generated dry ice particle-compressed air mixture 14 to be metered. This additional compressed air 8 is used in particular to vary the jet pressure and / or to set a speed of the dry ice particle / compressed air mixture 14.

According to developments of the device 1 according to the invention, the compressed air source 4 is also designed to supply shaping air 9 to a manual or automatic spray gun 6, which is used to apply the conditioned dry ice particle-compressed air mixture 14 to the surface 12 to be treated, in order, for example, to form a sheath flow which the Dry ice particle-compressed air mixture 14 envelops and acts parallelizing or focusing.

1. (i) einen Abstand der Sprühpistole 6 zu der zu behandelnden Oberfläche 12;
2. (ii) eine Geschwindigkeit des konditionierten Trockeneispartikel-Druckluftgemisches 14 am Düsenauslass der Sprühpistole 6;
3. (iii) einen Gesamtdruck und/oder statischen und/oder dynamischen Druck des konditionierten Trockeneispartikel-Druckluftgemisches 14 am Düsenauslass der Sprühpistole 6; und/oder
4. (iv) eine Temperatur des konditionierten Trockeneispartikel-Druckluftgemisches 14 am Düsenauslass der Sprühpistole 6.

The spray gun 6 can - as in FIG. 2 indicated - have a corresponding sensor system 10 in order to preferably automatically detect at least one of the following application-specific parameters:

1. (i) a distance from the spray gun 6 to the surface 12 to be treated;
2. (ii) a velocity of the conditioned dry ice particle-compressed air mixture 14 at the nozzle outlet of the spray gun 6;
3. (iii) a total pressure and / or static and / or dynamic pressure of the conditioned dry ice particle / compressed air mixture 14 at the nozzle outlet of the spray gun 6; and or
4. (iv) a temperature of the conditioned dry ice particle / compressed air mixture 14 at the nozzle outlet of the spray gun 6.

• eine mittlere Größe und insbesondere einen mittleren Durchmesser der Trockeneispartikel in dem Trockeneispartikel-Druckluftgemisch;
• eine Geschwindigkeit des Trockeneispartikel-Druckluftgemisches 14;
• einen Gesamtdruck und/oder statischen und/oder dynamischen Druck des Trockeneispartikel-Druckluftgemisches 14;
• eine Temperatur des Trockeneispartikel-Druckluftgemisches 14; und/oder
• einen Anteil der Trockeneispartikel in dem Trockeneispartikel-Druckluftgemisch.

The device 1 advantageously has an in FIG. 2 control or regulating device, not explicitly shown, which is designed to control the conditioning unit 5, the dry ice source 2 and / or the compressed air source 4 in such a way that that at least one of the following parameters of the dry ice particle / compressed air mixture 14 can preferably be set in a regulating manner as a function of at least one parameter detected with the aid of the sensor system 10:

• a mean size and in particular a mean diameter of the dry ice particles in the dry ice particle-compressed air mixture;
• a speed of the dry ice particle-compressed air mixture 14;
• a total pressure and / or static and / or dynamic pressure of the dry ice particle / compressed air mixture 14;
• a temperature of the dry ice particle-compressed air mixture 14; and or
• a proportion of the dry ice particles in the dry ice particle-compressed air mixture.

As already explained, it is provided in the method according to the invention that a pre-determined or determinable proportion of the dry ice particles in the dry ice particle-compressed air mixture 14 sublimes completely at a pre-determined or determinable distance in front of the surface 12 to be treated (= sublimation area 15). In this way, the surface 12 to be treated is largely spared, since the dry ice particles in the dry ice particle / compressed air mixture 14 no longer or at least for the most part no longer impinge on the surface 12 to be treated.

Nevertheless - as in FIG. 1b and 1c shown - with the method according to the invention, an optimal cleaning or treatment of the surface 12 takes place, since the sublimation area 15 is preferably selected such that - although the dry ice particles no longer hit the surface 12 directly - the low temperature of the sublimed dry ice to crack the coating 13 leads to the surface 12 to be treated and thus leads to the detachment of the covering 13.

In addition, the sublimation area 15 is preferably selected in the immediate vicinity of the surface 12, so that it is due to the sublimation effect or is cleaned due to the explosive effect when subliming the dry ice particles.

The invention is not limited to the embodiment shown in the drawings, but results from an overview of all the features disclosed herein.

List of reference symbols

1

Device for dry ice treatment

2

Dry ice source

3

Mixing unit

4th

Compressed air source

5

Conditioning unit

6th

Spray gun

7th

Filtration device

8th

Additional compressed air

9

Forming air

10

Sensors

11

Dry ice particle-compressed air mixture

12th

surface

13th

deposit to be removed (contamination)

14th

Dry ice particle-compressed air mixture

15th

Sublimation area

Claims (15)

Device (1) for dry ice treatment and in particular for dry ice cleaning of surfaces (12), the device (1) having the following: - A dry ice source (2) for providing dry ice, in particular in the form of dry ice particles; - A mixing unit (3) that is fluidly connected or connectable to the dry ice source (2); - A compressed air source (4) which is fluidly connected or connectable to the mixing unit (3); and - A conditioning unit (5) fluidly connected or connectable to the mixing unit (3) for adapting a dry ice particle / compressed air mixture (11) provided by the mixing unit (3) to application-specific conditions before the dry ice particle / compressed air mixture (11) is applied to the surface to be treated (12), wherein the conditioning unit (5) is designed to condition the dry ice particle / compressed air mixture (11) in such a way that a predetermined or determinable proportion of the dry ice particles in the dry ice particle / compressed air mixture (11) completely sublimed at a predetermined or determinable distance in front of the surface to be treated (12). Device (1) according to claim 1,
with the aid of the conditioning unit (5), preferably automatically and more preferably optionally automatically, the distance of a sublimation area (15) from the surface (12) to be treated can be adjusted in a specific manner, the sublimation area (15) being an area in which the previously determined or definable proportion of the dry ice particles in the dry ice particle-compressed air mixture (11) completely sublimed. Device (1) according to claim 2,
wherein the conditioning unit (5) is designed, preferably automatically and more preferably optionally automatically, the distance of the sublimation area (15) from the surface to be treated (12) as a function of an average size and in particular as a function of an average diameter of the dry ice particles in the dry ice particles - Adjust the compressed air mixture (11). Device (1) according to claim 2 or 3,
wherein the conditioning unit (5) is designed to condition the dry ice particle-compressed air mixture (11) preferably automatically and more preferably optionally automatically in such a way that the distance between the sublimation area (15) and the surface (12) to be treated is preferably: (a) corresponds to ten to six times the mean diameter of the dry ice particles in the dry ice particle-compressed air mixture (11); or (b) corresponds to six to four times and in particular 4.5 times the mean diameter of the dry ice particles in the dry ice particle / compressed air mixture (11); or (c) corresponds to less than four times the mean diameter of the dry ice particles in the dry ice particle-compressed air mixture (11); or (d) corresponds to at least five times the mean diameter of the dry ice particles in the dry ice particle-compressed air mixture (11). Device (1) according to claim 4,
wherein an interface device is provided for preferably manual selection and setting of one of the distance ranges (a) to (d), the interface device preferably on a spray gun (6) for applying the conditioned dry ice particle-compressed air mixture (11) to the surface to be treated (12) is arranged. Device (1) according to one of claims 1 to 5,
wherein the conditioning unit (5) is designed to set an average size and in particular an average diameter of the dry ice particles in the dry ice particle-compressed air mixture (11), in particular application-specifically, preferably automatically and more preferably optionally automatically. Device (1) according to one of claims 1 to 6 and in particular according to claim 6, wherein the conditioning unit (5) has at least one filtration device (7), the dry ice particle-compressed air mixture (11) to be conditioned being at least partially passed through the filtration device (7) and wherein the filtration device (7) is designed to allow only dry ice particles with a particle size that does not exceed a predetermined or determinable value to pass. Device (1) according to claim 7,
a mesh size of the filtration device (7) being adjustable for setting a critical particle size of the dry ice particles in the dry ice particle-compressed air mixture (11) up to which dry ice particles pass the filtration device (7). Device (1) according to one of claims 1 to 8,
wherein the compressed air source (4) is designed to supply a predetermined or determinable amount of compressed air to the mixing unit (3) per unit of time, the amount of compressed air supplied per unit of time to the mixing unit (3) in particular from a unit of time supplied to the mixing unit (3) Depends on the amount of dry ice particles. Device (1) according to claim 9,
wherein the compressed air source (4) is further designed to supply the dry ice particle-compressed air mixture (11) per unit of time with a predetermined or determinable amount of compressed air as additional compressed air. Device (1) according to claim 9 or 10,
wherein the conditioning unit (5) is designed to control or regulate the amount of additional compressed air supplied per unit of time from the compressed air source (4) of the mixing unit (3) and / or the amount of additional compressed air supplied per unit of time from the compressed air source (4) so that the dynamic and / or static pressure of the dry ice particle / compressed air mixture (11) can be set variably in a range between 0.1 bar to 24 bar at the predetermined or definable distance in front of the surface to be treated (12). Device (1) according to one of claims 1 to 11,
wherein the predetermined or determinable proportion of dry ice particles in the dry ice particle-compressed air mixture (11) is preferably adjustable such that the proportion: (i) corresponds to between 10% to 90% of all dry ice particles contained in the dry ice particle / compressed air mixture (11); or (ii) corresponds to between 20% to 80% of all dry ice particles contained in the dry ice particle / compressed air mixture (11); or (iii) corresponds to between 30% to 70% of all dry ice particles contained in the dry ice particle / compressed air mixture (11); or (iv) corresponds to between 40% to 60% of all dry ice particles contained in the dry ice particle / compressed air mixture (11). Device (1) according to one of claims 1 to 12,
wherein the device (1) has at least one manual or automatic spray gun (6) for applying the conditioned dry ice particle-compressed air mixture (11) to the surface to be treated (12), wherein the device (1) further includes one of the at least one spray gun (6) has assigned sensors for the preferably automatic detection of at least one of the following, in particular application-specific parameters: (i) a distance from the spray gun (6) to the surface (12) to be treated; (ii) a speed of the conditioned dry ice particle-compressed air mixture (11) at the nozzle outlet of the spray gun (6); (iii) a static and / or dynamic pressure of the conditioned dry ice particle / compressed air mixture (11) at the nozzle outlet of the spray gun (6); and or (iv) a temperature of the conditioned dry ice particle / compressed air mixture (11) at the nozzle outlet of the spray gun (6). Device (1) according to claim 13,
wherein the device (1) has at least one control or regulating device which is designed to control the conditioning unit (5), the dry ice source (2) and / or the compressed air source (4) in such a way that depending on at least one with the aid of the sensors detected parameters at least one of the following parameters of the dry ice particle-compressed air mixture (11) can be adjusted, preferably in a regulating manner: an average size and in particular an average diameter of the dry ice particles; - a speed of the dry ice particle-compressed air mixture (11); - A static and / or dynamic pressure of the dry ice particle-compressed air mixture (11); - A temperature of the dry ice particle-compressed air mixture (11); and or - A proportion of the dry ice particles in the dry ice particle-compressed air mixture. A method for treating surfaces (12), in particular for cleaning and / or refining surfaces (12), wherein a device (1) according to one of claims 1 to 14 is preferably used for this purpose, and wherein the method has the following method steps: - Providing a dry ice particle-compressed air mixture (11); - Conditioning the provided dry ice particle / compressed air mixture (11) to application-specific conditions; and - applying the conditioned dry ice particle-compressed air mixture (11) to the surface to be treated (12), wherein the provided dry ice particle-compressed air mixture (11) is conditioned in such a way that a predetermined or determinable proportion of the dry ice particles in the dry ice particle-compressed air mixture (11) completely sublimes at a predetermined or determinable distance in front of the surface to be treated (12).

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