WO2008125648A1 - Apparatus and method for particle radiation by frozen gas particles - Google Patents

Abstract

The invention relates to an apparatus for vapor blasting by means of a mixed stream of particles of a frozen gas and a carrier gas, with a jet housing which encloses an outer and an inner cavity of which the inner cavity represents an expansion chamber which has available at the upstream longitudinal end thereof an inlet for introducing a liquefied gas into the expansion chamber and an outlet opening at the downstream longitudinal end, wherein said outlet opening has a substantially larger cross-sectional area than the inlet, and of which the outer cavity at least partly surrounds the inner cavity at least in the area of the outlet opening, and with at least one liquefied gas supply which is connected to the inlet of the expansion chamber, with a carrier gas supply which is connected to the outer cavity, and with an acceleration jet which connects upstream to the outlet opening of the expansion chamber and to the outer cavity and then narrows in the direction of flow and which has a carrier gas inlet which serves as outlet of the outer cavity and which is located to the side of the outlet opening of which the cross-sectional area is adjustable in size.

Description

 Apparatus and method for particle blasting using frozen gas particles

The invention relates to an apparatus and a method for pressure blasting by means of a mixture jet of frozen gas particles and a carrier gas. In particular, the invention relates to an apparatus and a method for CO ₂ - snow blasting by means of a mixture jet of frozen CO ₂ gas particles and a carrier gas.

Frozen gas particles are particles of a substance that is gaseous at ordinary ambient temperature and pressure.

The blasting with solid carbon dioxide has been able to establish itself in the most diverse fields of application in recent years. As soon as sensitive surfaces have to be stripped or cleaned or secondary contamination by blasting media is undesirable, this technology can bring its advantages to advantage.

The low hardness of solid carbon dioxide enables the damage-free processing of a wide range of materials and the sublimation of the Blasting agent must be disposed of only the removed, sorted coating or contamination.

When blasting by means of frozen gas particles, the blasting agent is pneumatically accelerated and applied to the surface to be processed. In contrast to the purely mechanical effect of other blasting agents, blasting with frozen gas particles is based on three different mechanisms of action. The low temperature of the blasting medium causes the thermal stress between coating and contamination of the substrate. Furthermore, the kinetic energy of the frozen gas particles leads to a mechanical separation, which is supported by the third effect, the pressure surge due to the sudden sublimation of the frozen gas particles.

Such devices and methods are basically known and there are a variety of different types, which give the mixture jet of frozen gas particles and the carrier gas different properties in relation to, for example, speed, volume flow, size, number and expression of the frozen gas particles, so during operation a desired effect on the workpiece or the surface can be achieved.

In particular, two different basic principles are distinguished in design. The first type, which is also referred to as a dry ice blaster, differs from the second type, which is also referred to as a snow blaster, in that first of the solid phase and second of the liquid phase produces the blended streams. For dry ice blasting, the blasting agent is produced in a separate process in the form of pellets or blocks and then added to the compressed air stream in a blasting system.

Since an object of the present invention is to provide a device for pressure jets with frozen gas particles, which has a small size and thus can be easily integrated into machinery and equipment, the present invention relates to a device for Compressive blasting by means of a mixture jet of frozen gas particles and a carrier gas according to the second type. Accordingly, in the devices described here, the blasting agent, in particular CO ₂ , held in liquid form under pressure.

Also in this type of construction, also referred to as a snow blaster, a distinction is again made between two construction variants: the two-part ring nozzle and the blasting nozzle with agglomeration chamber.

In the Zweistoffringdüse the liquid gas is released at the nozzle outlet to ambient pressure. The resulting snow particles are bundled and accelerated by a sheath jet of super-fast compressed air.

The frozen gas particles formed in the Zweistoffringdüse have in comparison to the jet nozzle with agglomeration chamber a smaller diameter and thus a low kinetic energy at the same speed. Therefore, the particles that are produced according to this construction variant, have little abrasive and therefore such devices are mainly used for the purification of finely structured, highly sensitive components. Such a device is described in DE 199 26 119 C2.

In a device of the type of the second construction variant, the liquefied gas is introduced together with the carrier gas stream into an agglomeration chamber and expanded. Compared to the two-nozzle nozzle, larger snow particles are generated, which accelerate with the compressed air in a subsequent nozzle, resulting in a significantly higher abrasiveness. Such a method and such a device is described in DE 102 43 693 B3.

While the first construction variant with two-nozzle nozzle has the disadvantage of having a low abrasiveness, the second design variant of the pressure-jet apparatus with agglomeration chamber has the disadvantages that a high pressure consumption can be recorded during operation. In addition, inside the agglomeration chamber, frozen gas particles deposit on the outer walls and - A -

detach themselves at irregular intervals and in undefined size from the outer walls. This results in impulsive higher removal rates and thus in an inhomogeneous spray pattern.

From DE 202 14 063 U1 a CC> ₂ -Kaltgasdüse for pressure blasting by means of a mixture jet of CO ₂ particles and compressed air is known.

The aim of the present invention is therefore to provide a mixture jet technology, which is not covered by the known types and construction variants.

The deficit of previous approaches is to cause a high abrasiveness of the mixture jet with low compressed air consumption. Such a device could be connected even with a required high abrasiveness to conventional workshop compressed air networks.

Moreover, the object of the present invention is the abrasiveness, i. H. In particular, the size of the frozen gas particles, as well as the amount adjustable and thus to make their Abrasivität variable.

This object is achieved by a device for particle blasting with frozen particles, which holds the blasting medium in liquid form and thus belongs to the group of snow blasting.

According to the invention, the device has a nozzle housing which encloses an outer and an inner cavity.

The inner cavity thereby constitutes an expansion space having an inlet connected to the liquefied gas supply for introducing a liquefied gas at its upstream longitudinal end and an orifice at its downstream longitudinal end. The mouth opening has a substantially larger cross-section than the inlet. This inner cavity is at least in the region of its mouth, surrounded by an outer cavity which is connected to at least one carrier gas supply.

Preferably, the inner cavity and the outer cavity have substantially round cross-sections.

An initially tapering acceleration nozzle adjoins the opening of the relaxation space and the outer cavity in the flow direction, which has a carrier gas inlet located laterally, in particular on all sides of the opening, as an outlet of the outer cavity.

As an aim of the present invention, as already described above, is to reduce the abrasiveness, i. H. In particular, the size of the frozen gas particles, as well as their amount adjustable and thus to make their Abrasivität variable, the cross section of the carrier gas inlet according to the invention variably adjustable.

In a transition region between the feed for liquefied gas and the expansion space is a metering device, which represents the inlet of the expansion space and is preferably formed as a relaxation or needle nozzle preferably with a variably adjustable inner diameter. In the flow direction behind the metering device, the flow diameter of the inner diameter of the metering device expands suddenly to the inner diameter of the expansion space. As a result, the liquefied gas relaxes in the expansion space, forming a mixture of frozen gas particles and gas.

During the flow of the mixture of frozen gas particles and gas through the expansion space, individual particles agglomerate with each other, so that an increase in the size of the particles takes place downstream in the expansion or agglomeration space. Preferably, the diameter of the expansion space is designed so that the cross-section of the expansion space increases steadily downstream.

This cross-sectional expansion of the expansion space in the direction of the nozzle outlet ensures a continuous flow and thus a safe removal of the resulting snow particles. With a constant cross-section immediately after the injection of the liquefied gas due to fluidic "dead spaces" deposits and accumulation of solid gas particles in the "dead spaces." These deposits dissolve at irregular intervals, making it an inhomogeneous and pulsating jet pattern The comparatively large particle agglomerations have a higher kinetic energy and therefore have a stronger effect on the irradiated surface, and this effect can be negatively evaluated for the reproducible use of the snow blasting technique the accumulation of frozen gas particles lead to a blockage of the jet nozzle.

To the abrasiveness, d. H. In particular, to make the size of the frozen gas particles, as well as their amount adjustable, both the volume flow of the flowing into the expansion space liquefied gas, and the inflowing into the outer cavity carrier gas flow is variably adjustable.

Since the abrasiveness also decisively depends on the particle size, and this also depends on the length or the volume of the expansion space or agglomeration space, the volume of the agglomeration space can also be variably adjusted according to a preferred embodiment of the invention.

Preferably, the volume of the agglomeration space can be changed by moving the metering device, which is located in the transition region between the supply of the liquefied gas and the expansion space, in the transition area and parallel to the flow direction. that can change that the length, or the volume of the agglomeration space.

According to a further embodiment of the invention, the agglomeration space can also be designed to be displaceable in the longitudinal axis, so that in this case too, the relative position of the metering device is displaceable in the transition area and thus the volume of the agglomeration space is variable.

According to a further embodiment of the invention, the volume of the expansion space can also be designed to be variable by means of a differently adjustable inner diameter of the expansion space.

Due to the variably adjustable volume flows of liquid gas supply and carrier gas supply and beyond also by the variable length of the agglomeration space, the flow conditions, as well as the size of the frozen gas particles can also be very different in the region of the inlet of the acceleration nozzle. In the case of unfavorable flow conditions, the frozen gas particles may sublime when mixed with the carrier gas and before they can unfold the desired effect on the workpiece. To prevent this, an essential aspect of the invention is that the opening cross section of the carrier gas inlet, which is formed between the outer contour of the expansion space and the inner contour of the inlet of the acceleration nozzle, is variably adjustable.

Preferably, the device for pressure blasting by means of a mixture jet of frozen gas particles and a carrier gas is formed so that the mouth cross-section can be varied in that the relaxation space relative to the accelerating nozzle in the axial direction, relative to the longitudinal axis of the accelerating nozzle can be moved. According to other embodiments of the invention, the said opening cross-section is designed to be variably adjustable in that the expansion space is displaced in the orthogonal direction relative to the longitudinal axis of the acceleration nozzle. that can. According to a further embodiment of the invention, the orifice cross-section at the said point can be varied in that the inner contour of the inlet of the acceleration nozzle and / or the outer contour of the outlet of the expansion space are designed to be variable at least on a portion of its circumference.

Further features and advantages of the present invention are described below with reference to the accompanying drawings.

The sole FIGURE 1 shows a preferred embodiment of the invention in a cross-sectional view.

The illustrated apparatus for pressure blasting has a nozzle housing 4 which includes an outer cavity 6 and an inner cavity 2.

The inner cavity 2 is connected to a supply 7 for the introduction of liquefied gas into the inner cavity 2. The outer cavity 6 in turn communicates with a supply 3 for the introduction of pressurized carrier gas into the outer cavity 6.

The inner cavity 2 is delimited at its one longitudinal end by an inlet 8, which is given according to the embodiment shown by the inner diameter of a metering device 1. The metering device 1 is arranged in a transition region between the feed 7 and the inner cavity 2. The metering device 1 is formed in the illustrated preferred embodiment as a needle nozzle and preferably has a diameter between 0.1 and 2 mm. To the metering device 1 as the inlet 8 of the inner cavity 2, the inner cavity 2 connects itself with a much larger diameter of 3 mm to 50 mm. As a result of the diameter jump directly behind the inlet 8 to the diameter of the inner cavity 2, the liquefied gas abruptly evaporates on entry into the inner cavity 2 with the generation of cold, and part of the liquefied Gases freeze to small particles. For this reason, the inner cavity 2 is also called relaxation space.

The inner cavity 2 is delimited at its other longitudinal end by a mouth 9 which is located downstream. From the inlet 8 of the inner cavity 2 to the mouth opening 9, the diameter of the expansion space 2 widens continuously in the flow direction and is preferably between 5 and 70 mm at the mouth opening 9. During the passage through the inner cavity 2, individual particles agglomerate with other particles. Therefore, the inner cavity 2, which represents the relaxation space, also referred to as agglomeration space.

Immediately to the mouth opening 9 of the relaxation space 2 and the outer cavity 6 is followed by an accelerating nozzle 5, which initially tapers in the flow direction and into which the mouth opening 9 of the expansion space 2 protrudes. The accelerating nozzle 5 has at its narrowest point a diameter of preferably between 2 and 20 mm. Because the outer contour of the expansion chamber 2 has a smaller diameter in the area of its orifice 9 than the diameter of the inner contour in the transitional region between the inner contour of the outer cavity 6 and the inlet of the acceleration nozzle 5, an annular carrier gas inlet 10 results in the acceleration nozzle 5, which is simultaneously Outlet of the outer cavity 6 is.

The inner cavity 2 is designed to be displaceable in the axial direction with respect to the longitudinal axis of the accelerating nozzle 5 and opens into the accelerating nozzle 5 tapering there. The cross section of the carrier gas inlet 10 can thereby be varied into the accelerating nozzle 5 by longitudinal displacement of the inner cavity 2. The carrier gas inlet (10) preferably faces transversely to the longitudinal axis of the device, depending on the position of the orifice (9) within the device between the outer edge of the mouth (9) of the inner cavity (2) and the inner wall of the outer Cavity (6) or the acceleration nozzle (5) has a variably adjustable distance of between 0 and 2 mm.

Claims

Claims:

1. A device for pressure blasting by means of a mixture jet of particles of a frozen gas and a carrier gas, with

a nozzle housing including an outer cavity (6) and an inner cavity (2),

of which the inner cavity (2) is a relaxation space having at its upstream longitudinal end an inlet (8) for introducing a liquefied gas into the expansion space (2) and an orifice (9) at its downstream longitudinal end, wherein the mouth opening (9) has a much larger

Cross-section than the inlet (8) and

of which the outer cavity (6) at least partially surrounds the inner cavity (2) at least in the region of the mouth opening (9),

at least one LPG supply connected to the inlet (8) of the expansion space (2),

a carrier gas supply (3), which is connected to the outer cavity (6), and

a downstream of the mouth opening (9) of the relaxation space (2) and the outer cavity (6), in the flow direction initially tapered acceleration nozzle (5), the one side of the mouth opening (9) located carrier gas inlet (10) as Outlet of the outer cavity (6), whose cross section is adjustably variable.

2. Apparatus according to claim 1, characterized in that the diameter of the carrier gas inlet (10) by a relative displacement of the internal cavity (2) with respect to the accelerating nozzle (5).

3. Apparatus according to claim 2, characterized in that the displacement of the expansion space (2) in the axial direction with respect to the longitudinal axis of the acceleration nozzle (5).

4. Device according to one of claims 1 to 3, characterized in that the inner diameter of the expansion space (2) increases continuously in the flow direction from its upstream longitudinal end to its downstream longitudinal end.

5. Device according to one of claims 1 to 4, characterized in that the outer cavity (6) and the inner cavity (2) have substantially round cross-sections.

6. Device according to one of claims 1 to 4, characterized in that the inlet (8) in the expansion space (2) of the inner diameter of a metering device (1) is formed in the form of a flash nozzle, which has a much smaller diameter, as the inner diameter of the expansion space (2).

7. Device according to one of claims 1 to 6, characterized in that the carrier gas inlet (10) transversely to the longitudinal axis of the device between see the outer edge of the mouth opening (9) of the inner cavity (2) and the inner wall of the outer cavity ( 6) or the accelerating nozzle (5) has a variably adjustable distance of between 0 and 2 mm.

8. Device according to one of claims 1 to 7, characterized in that the expansion space (2) has an inner diameter of the mouth opening (9) between 5 and 70 mm.

9. Device according to one of claims 1 to 8, characterized in that both the volume flow of the liquefied gas, and that of the carrier gas can be varied.

10. Device according to one of claims 1 to 9, characterized in that the device has a variable adjustable volume of the relaxation space (2).

1 1. Device according to one of claims 1 to 10, characterized in that the volume of the agglomeration space (2) is formed variable adjustable thereby, that the metering device (1), which in the LJ transition region between the supply of the liquefied gas (7 ) and the expansion space (2), so can be moved in the transition region and parallel to the flow direction that changes the length, or the volume of the agglomeration space (2).

12. A method for cleaning or pretreating surfaces by means of a mixture jet of frozen gas particles, in particular CO ₂ particles, and a carrier gas, wherein the mixed jet is produced by means of a device according to claim 1.