EP1842598A1 - Blasting discharge jet - Google Patents

Abstract

The nozzle has an inflow section (1) converging in a flow direction, and a transverse section (2), a cylindrical section (4) and a section (5) with a transverse surface attached to the inflow section consecutively, where the surface increases in the direction. The length of the cylindrical section is 20 millimeter, and a conveying section (3) diverging in the direction is attached to the transverse section in-front of the cylindrical section. A ratio of lengths between the section (5) and the cylindrical section is 4:1.

Description

The invention relates to a Strahlmittelaustragsdüse, in particular for dry ice blasting.

Such Strahlmittelaustragsdüsen be used in discharge devices of particle beam devices. Out EP 0414863 B1 and from DE 2064003 Strahlmittelaustragsdüsen are known with a converging in the flow direction of the inlet portion, followed by a narrowest cross-section in the flow direction and a diverging in the flow direction follower section.

This Strahlmittelaustragsdüsen be used especially for particle beam devices in which a mixture of compressed air and blasting medium is discharged.

With the mixture of compressed air and blasting agent, for example, soiled surfaces are cleaned. In particular, dry ice particles are used as blasting agents. With these dry ice particles, a particularly gentle cleaning of soiled surfaces is made possible. When using dry ice blasting equipment for cleaning is a particularly gentle method, because the surfaces of the dry ice particles from the dirt, but by the soft nature of the particles and the dissolution of the ice crystals in the atmosphere is prevented from damaging the surface immediately after hitting the surface.

In such particle jet cleaning devices, especially in dry ice blasting equipment, the formation of the blasting agent discharge nozzles is of particular importance, because the impact direction and speed of the dry ice particles are decisively influenced by the internal geometry of the discharge nozzles.

The previously known from the prior art Strahlmittelaustragsdüsen have substantially a converging inlet zone and a diverging exit zone with an intermediate narrowest cross-section. This gives the particles an uneven acceleration, different in direction and speed. This is particularly noticeable in dry ice particles, which rely on a uniformly aligned carrier air flow due to their relatively low mass for a uniform discharge from the nozzle. With the jet media discharge nozzles known hitherto from the state of the art, therefore, only an unsatisfactory spray pattern and thus a rather low area cleaning performance could be achieved with dry ice blasting devices.

Object of the present invention is to develop a Strahlmittelaustragsdüse of the type mentioned in such a way that it has an improved spray pattern and thus an increased surface cleaning performance.

According to the invention a Strahlmittelaustragsdüse, in particular for dry ice blasting proposed, with a converging in the flow direction inlet portion, followed in the flow direction a narrowest cross section, a cylindrical portion and a portion with increasing cross-sectional area in the flow direction, wherein the length of the cylindrical portion is at least 20 mm ,

By this cylindrical portion is achieved that the particles are carried on a minimum length within the Strahlmittelaustragsdüse on a rectified in the cylindrical portion carrier air flow and thus experience a uniform acceleration on this minimum distance.

This leads to a stabilization of the blasting agent flow, so that the particles flow much more stably on the last section of the blasting agent discharge nozzle in front of the discharge opening, than would be the case with a blasting agent discharge nozzle without cylindrical section or with a significantly shorter cylindrical section. The surface to be cleaned is therefore acted upon by the particles after discharge from the nozzle with a more uniform impact pressure, so that over the illuminated surface area a uniform and intensive cleaning takes place.

A particularly high area performance even with the use of compressors with lower mileage results when, at the narrowest cross section in front of the cylindrical portion connects a diverging in the flow direction section.

Particularly good results are achieved in the case of jet discharge nozzles in which the ratio of the lengths between the section with the cross-sectional area increasing in the direction of flow and the cylindrical section is at most 4: 1, preferably at most 2.5: 1.

In order to avoid having to renew or replace the entire nozzle in the case of signs of wear on individual regions of the nozzle or with desired different jet characteristics, it is favorable if the nozzle is constructed in several parts, wherein at least part of the cylindrical section and the section with increasing cross-sectional area in the flow direction are combined to form an assembly. This makes it possible to use this expensive to manufacture and therefore expensive assembly of the nozzle in various combinations.

It is particularly advantageous if at least a part of the cylindrical section and the section with increasing cross-sectional area in the flow direction are combined to form a first assembly and the converging in the flow direction inlet section with in the flow direction following narrowest cross-section and possibly diverging in the flow direction following section to a second module are. As a result, for example, by using the same first assembly with different second assemblies, the second assemblies differ from each other by the narrowest cross-section, different impact pressures are selected depending on the sensitivity of the surface to be cleaned.

A construction that is particularly inexpensive to produce results when the first assembly has two identical half-shells.

In order to obtain the widest possible outlet opening with a relatively narrow height, it is advantageous if the section adjoining the cylindrical section in the flow direction increases in width in the flow direction in the direction of flow and decreases in height.

In the case in which the section adjoining the cylindrical section has grooves on its flat inner surfaces in the longitudinal direction, which diverge radially and symmetrically with respect to the longitudinal axis of the nozzle in the flow direction up to the nozzle cut-out edge, the particle flow is additionally uniformed and thus an even clearer delimited cleaning field becomes uniform irradiated with particles.

It is particularly advantageous if the grooves have their common starting point on the center of the boundary line between the cylindrical portion and subsequent section.

An advantageous construction results when the nozzle contains means to connect it with its converging inlet section to the gun or the outlet hose of a particle unit, in particular a dry ice blasting unit.

It is particularly advantageous if the first assembly with a cylindrical portion and with the portion with increasing cross-sectional area in the flow direction in the region of the cylindrical portion has a cylindrical outside shape and can be connected by means of a union nut to the second assembly.

In particular, when using a pistol with handle, it is for optimum selection of a desired beam direction of advantage when the first assembly is rotatably fastened to the second module.

The invention also relates to a particle beam device for dispensing a mixture of compressed air and dry ice, wherein the particle beam device is connectable to a source of compressed air and has a supply of particles and a metering device, with which the particles of the compressed air can be admixed, and a discharge device to which a supply line for compressed air and particles can be connected, wherein the discharge device has a Strahlmittelaustragsdüse of the aforementioned type.

It is particularly advantageous if the particles of the particle beam device are dry ice particles.

Especially when cleaning with dry ice particles, the advantages of the invention come particularly to advantage.

Figur 1:

eine Draufsicht auf eine erfindungsgemäße Strahlmittelaustragsdüse;

Figur 2:

einen Längsschnitt der Strahlmittelaustragsdüse längs der Linie 2-2 in Figur 1;

Figur 3:

eine Seitenansicht der Strahlmittelaustragsdüse;

Figur 4:

eine Vorderansicht der Strahlmittelaustragsdüse;

Figur 5:

eine Schnittansicht der Strahlmittelaustragsdüse längs der Linie 5-5 in Figur 3;

Figur 6:

eine schematische Darstellung einer erfindungsgemäßen Trockeneisstrahlvorrichtung.

The invention will be described in more detail below with reference to preferred exemplary embodiments. Show it:

FIG. 1:

a plan view of a Strahlmittelaustragsdüse invention;

FIG. 2:

a longitudinal section of the Strahlmittelaustragsdüse along the line 2-2 in Figure 1;

FIG. 3:

a side view of the Strahlmittelaustragsdüse;

FIG. 4:

a front view of the Strahlmittelaustragsdüse;

FIG. 5:

a sectional view of the Strahlmittelaustragsdüse along the line 5-5 in Figure 3;

FIG. 6:

a schematic representation of a dry ice blasting device according to the invention.

In the figures 1 to 5 a Strahlmittelaustragsdüse invention is shown schematically. As evident from FIG. 2 and FIG. 5, the Strahlmittelaustragsdüse invention has a converging in the flow direction inlet portion 1, followed in the flow direction successively a narrowest cross-section 2, a diverging in the flow direction following section 3, a cylindrical section 4 and a section 5 with increasing in the flow direction cross-sectional area 6. The convergent inlet section 1 and the diverging secondary section 3 each have a conical inner contour. The length of the cylindrical portion 4 is 80 mm, while the length of the portion 5 is 200 mm. These dimensions have proven particularly advantageous for the preferred embodiment shown in the drawing.

The nozzle is constructed in several parts and comprises a first assembly 7, which has the cylindrical section 4 and the section 5 with increasing cross-sectional area in the flow direction, and a second assembly 16, the converging inlet section 1, the narrowest cross-section 2 and the downstream divergent section 3 has. The first assembly 7 consists of two half shells 8 and 9, which are designed identically. The identical construction allows a particularly inexpensive production of the nozzle.

The identical half-shells 8, 9 have with particular advantage on one side elevations or projections 23 and on symmetrically opposite side to complementary depressions or recesses 24, so that in a simple manner a precisely fitting Assembly of identical parts is possible, as shown in Figure 4 can be seen.

As can be seen in FIGS. 3 and 5, in the first assembly 7, the width of the section 5 increases in the flow direction with increasing cross-sectional area, while the height of this section 5 decreases in the flow direction.

In order to allow the resulting stream of dry ice particles, which has been uniformly accelerated even in the preceding cylindrical section 4 continue to flow as evenly and without turbulence, grooves 11 are milled on the two flat inner surfaces of the section 5 in the longitudinal direction, the radial from the center of the boundary line between cylindrical section 4 and subsequent section 5 to the nozzle exit edge 22 symmetrical to the longitudinal axis of the nozzle in the flow direction apart.

The Strahlmittelaustragsdüse also has means 12 to connect them with their converging inlet portion of the gun 13 or the outlet hose 14 of a dry ice blasting machine 15.

A union nut 17 is used to attach the first assembly 7 to the second assembly 16. It has on its outside roughened gripping surfaces 18, so that the union nut 17 can also be attached or detached by hand. The first assembly 7 is rotatably mounted on the second assembly 16 and can be changed by simply loosening and then re-tightening the nut 17 in the short term by the operator in their orientation. When using a gun 13, it is thus possible to achieve the orientation of the flat jet at any angle to the handle, thus achieving a particularly simple and fatigue-free for the operator guiding the Strahlmittelaustragsdüse.

As can be seen from Figure 6, the dry ice blasting device according to the invention comprises a metering device 19 which is connectable via a feed line 20 for compressed air with a compressed air source not shown here. In a reservoir 21 dry ice particles are stored, which are mixed via the metering device 19 of the compressed air. The mixture of compressed air and dry ice is passed via the supply line 14 to the gun 13. The gun 13 has a coupling nozzle 22 for connecting the Strahlmittelaustragsdüse.

Claims (15)

Strahlmittelaustragsdüse, in particular for dry ice blasting, with a converging in the flow direction inlet portion (1) to which in the flow direction a narrowest cross-section (2), a cylindrical portion (4) and a portion (5) with increasing in the flow direction cross-sectional area (6), wherein the length of the cylindrical portion (4) is at least 20 mm. Blast media discharge nozzle according to claim 1, wherein adjoining the narrowest cross-section (2) in front of the cylindrical portion (4) is a diverging portion in the flow direction. A jet discharge nozzle according to claim 1 or 2, wherein the ratio of the lengths between the section (5) having the cross-sectional area increasing in the flow direction and the cylindrical section (4) is at most 4: 1. A blasting agent discharge nozzle according to any one of the preceding claims, wherein the ratio of the lengths between the section (5) of increasing cross-sectional area (6) and the cylindrical section (4) is at most 2.5: 1. Strahlmittelaustragsdüse according to any one of the preceding claims, wherein the nozzle is constructed in several parts, wherein at least a portion of the cylindrical portion (4) and the portion (5) with increasing in the flow direction cross-sectional area (6) are combined to form an assembly (7). Blasting agent discharge nozzle according to one of claims 2-5, wherein at least a part of the cylindrical portion (4) and the portion (5) are increased in flow direction increasing cross-sectional area (6) to a first assembly (7) and the converging in the flow direction inlet portion (1 ) are joined together with the narrowest cross section (2) following in the direction of flow and a following section (3) diverging in the flow direction to form a second module (16). Blasting agent discharge nozzle according to claim 5 or 6, wherein the first assembly (7) has two identical half-shells (8, 9). A blasting agent discharge nozzle according to any one of the preceding claims, wherein the section (5) adjoining in the flow direction to the cylindrical portion (4) increases in the flow direction in width and decreases in height with increasing in the flow direction cross-sectional area (6). A blasting agent discharge nozzle according to one of the preceding claims, wherein the section (5) adjoining the cylindrical section (4) has, on its flat inner surfaces in the longitudinal direction, grooves (11) which are radial and symmetrical to the longitudinal axis of the nozzle in the flow direction up to the nozzle exit edge (22). diverge. A blasting agent discharge nozzle according to claim 9, wherein the grooves (11) have their common starting point at the midpoint of the boundary between the cylindrical portion (4) and the portion (5) following thereon. Blast media discharge nozzle according to one of claims 6 to 10, wherein the first assembly (7) with a cylindrical portion (4) and with the section (5) with increasing in the flow direction cross-sectional area (6) in the region of the cylindrical portion (4) has a cylindrical outer shape and with the aid of a union nut (17) to the second module (16) can be connected. Blasting agent discharge nozzle according to one of claims 6 to 11, wherein the first assembly (7) on the second assembly (16) is rotatably fastened. Blast media discharge nozzle according to one of the preceding claims, wherein the nozzle has means (12) for connecting it with its converging inlet section (1) to the gun (13) or the outlet hose (14) of a particle beam device, in particular a dry ice blasting device (15). Particle jet device for dispensing a mixture of compressed air and dry ice, wherein the particle beam device is connectable to a source of compressed air and has a supply of particles and a metering device (19), with which the particles of the compressed air can be admixed, and a discharge device to which a supply line for compressed air and particles can be connected, wherein the discharge device comprises a Strahlmittelaustragsdüse according to any one of the preceding claims. A particle beam device according to claim 14, wherein the particles are dry ice particles.

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