EP0573957A1 - Apparatus for blast machining of material - Google Patents

Abstract

An apparatus for the abrasive blasting of materials by means of an abrasive medium which is mixed with a liquid and contains, in particular, granulate-type abrasion particles is characterised in that the liquid-inflow opening (22) is designed as a peripheral gap and is delimited by nozzle elements (3, 3', 4, 4') which can move relative to one another and can be fixed in the relevant position, and in that the cross-section, through which flow occurs, of the liquid-inflow opening (22) can be changed by the relative movement of said nozzle elements (3, 3', 4, 4'). In the region of its mouth, the liquid-inflow opening is aligned in parallel with the wall which is located behind the liquid-inflow opening (22), seen in the direction of flow of the abrasive medium, and belongs to the cavity (12), with the result that a liquid shroud protecting said wall of the cavity (12) is formed.

Description

The invention relates to a device for beam processing materials according to the preamble of patent claim 1.

Devices of this type are used, for example, as cleaning devices in the field of facade cleaning or monument conservation. Here, a mixture of air, water and abrasion particles, for example sand, is sprayed against the surfaces to be cleaned with relatively high pressure, as a result of which the dirt particles adhering to the surface or rust and outer patina layers are removed from metal objects. In order to obtain the desired work result, it is possible to enrich the mixture with chemical additives, to vary the type and shape of the abrasion particles and the ratio of the mixture components and to change the pressure.

A problem with sandblasting is that there is often high water consumption, which increases the overall cost of the process. In addition, with high water consumption, there are increased disposal problems, since the water enriched with dirt particles and possible additives must not get into the normal drain, but must be collected at the foot of the facade by means of suitable containers and cleaned or reprocessed in special facilities.

From US Pat. No. 4,253,610 a device of the type mentioned at the outset is known in which the liquid is introduced into the axial cavity of the nozzle via a large number of small openings. The openings are arranged in a circle around the inner peripheral wall of the cavity. The amount of liquid is adjusted via a valve arranged in the common supply line.

A disadvantage of this known device is that a liquid supply that is optimally adapted to the respective conditions is only possible in a small quantity and pressure range.

From CH-PS 596 956 a suction jet gun is known in which water is fed under pressure through a circumferential gap to a mixing chamber. The treatment agent is sucked in there by the negative pressure generated by the water. The problem with this known device, however, is that its service life is relatively short due to the high wear caused by friction.

Furthermore, from DE-GM 19 82 295 a jet gun is known in which compressed air is used to suck in abrasion particles, which is introduced along the inner wall of the hollow part on the outlet side through a circumferential gap. This known device also has the problem that its service life is short due to the wear that occurs.

The invention is therefore based on the object of creating a device according to the preamble of claim 1, which enables the liquid to be optimally adapted to the respective admixture of the liquid over a wide setting range with the lowest possible liquid consumption and long service life of the device.

This object is achieved by the features of claim 1.

In the device according to the invention, the amount of liquid is metered through the liquid inflow opening itself, so that upstream metering elements within the liquid supply line are dispensed with and the latter can be constructed very simply. Another advantage is that the amount of liquid supplied can be adjusted over a wide range and very precisely, since the liquid inflow opening is immediately in front of the cavity in the direction of flow and there are no downstream elements or openings, the shape and size of the inflow conditions into the cavity determine.

It is particularly advantageous that it is possible to work even at very low liquid pressures of, for example, 5 bar and small amounts of liquid, which enables a particularly gentle surface treatment. This also provides a wide range of applications for the device according to the invention, and on the one hand the disposal problems and on the other hand the costs for the provision of the unused liquid and for the disposal and reprocessing of the contaminated liquid after the blasting treatment can be considerably reduced. This aspect is particularly important with regard to environmental compatibility.

The liquid inflow opening is designed as a circumferential gap, which enables a very simple manufacture of the liquid inflow opening and a uniform supply of the liquid into the cavity from all sides of the peripheral wall.

It is particularly advantageous that the liquid inflow opening in the region of its mouth is oriented at least substantially parallel to the wall of the cavity lying behind the liquid inflow opening, as seen in the flow direction of the blasting material. The liquid supplied to the cavity is hereby deliberately guided along the circumferential wall of the cavity, so that a liquid protective layer is formed between the wall of the cavity and the abrasion particles. Because of this layer of liquid, the nozzle is significantly less worn by the abrasion particles, which increases its service life.

The liquid jacket protecting the peripheral wall of the cavity has a particularly advantageous effect on the service life of the device when working at very high pressures. This is the case, for example, if the device is used for jet cutting materials, where, depending on the material to be cut, for example stone, steel, wood, fabrics or any other materials of all degrees of hardness, pressures of 1000 bar or more may be required. Here too, the liquid jacket at least largely keeps the abrasion particles away from the peripheral wall of the cavity and considerably reduces the wear on the nozzle.

Advantageously, one nozzle element consists of a hollow cylindrical insert part which is arranged to be axially movable within a nozzle shell, and the other nozzle element consists of a further hollow cylindrical insert part which is immovably connected to the nozzle shell and which is arranged within the nozzle shell in alignment with the first insert part, the cavity being inside the insert parts are designed.

With such an arrangement, it is possible to manufacture only the insert parts from a very wear-resistant material, for example hardened steel, while the nozzle casing can be made of a relatively light material, for example aluminum or plastic. As a result, the device according to the invention has, in addition to a high abrasion resistance to the blasting material, also a low weight, which improves the handling of the device. In addition, if necessary, only the insert parts can be replaced, while the nozzle jacket and the connection devices provided thereon can continue to be used.

According to a further advantageous embodiment, flow guide elements are provided on at least one of the two walls of the nozzle elements delimiting the liquid inflow opening in order to give the liquid flowing into the cavity a spiral flow direction around the central axis of the nozzle. The jet emerging from the nozzle thereby receives a swirl with which the shape of the jet can be influenced in a favorable manner.

Further advantageous embodiments of the invention can be seen from the subclaims.

• Fig. 1 einen teilweise geschnittenen Längsschnitt durch die erfindungsgemäße Düse und
• Fig. 2 eine Ausbildungsvariante der Düse von Fig. 1.

The invention is explained in more detail below with reference to the drawing, for example; in this shows:

• Fig. 1 is a partially sectioned longitudinal section through the nozzle according to the invention and
• FIG. 2 shows an embodiment variant of the nozzle from FIG. 1.

1 shows a nozzle 1 with an elongated, hollow cylindrical nozzle jacket 2, in which two nozzle elements in the form of hollow cylindrical insert parts 3, 4 are provided. The nozzle jacket is connected to a liquid inlet connection 5.

The nozzle jacket 2 has a continuous longitudinal bore 7, which is arranged centrally to its central axis 6, for receiving the insert parts 3, 4 and which consists of a section 9 with an internal thread 8 with an enlarged diameter and a section 10 with a smaller diameter adjoining it in the flow direction. The two sections 9, 10 are connected to one another via a radial shoulder 11.

The insert parts 3, 4 are arranged one behind the other in the flow direction and in alignment with the central axis 6. They delimit with their inner circumferential walls a continuous cavity 12 which has an inlet opening 13 for abrasion particles, for example sand, at the inflow end and an outlet opening 14 for the blasting material at the outlet end. The direction of flow of the abrasion particles entering via the inlet opening 13 is indicated by the arrow 15.

The insert part 3 which has the inlet opening 13 is inserted approximately up to the center of the nozzle shell 2 in its longitudinal bore 7 and is arranged to be axially movable therein. For this purpose, the insert part 3 has a section 16 with an enlarged outer diameter, which carries an external thread 17 which can be screwed into the internal thread 8 of the nozzle casing 2. Furthermore, the insert part 3 is provided with a downstream section 18 with a smaller diameter as viewed in the direction of flow, which section is guided axially displaceably within the section 10 of the longitudinal bore 7.

In order to be able to determine the desired relative position of the insert part 3 with respect to the nozzle casing 2, a lock nut 19 is screwed onto the section of the insert part external thread 17 projecting beyond the end face of the nozzle casing 2, whereby the external thread 17 and the internal thread 8 of the nozzle casing 2 are braced against one another can be.

The insert 3 can be connected to a supply line (not shown) for the abrasion particles via an end region projecting axially via the lock nut 19.

The insert 4 lying behind the insert 3 in the direction of flow consists of a tubular sleeve and is fixed within the section 10 of the longitudinal bore 7 by means of a screw, not shown, which is screwed into a radial threaded bore 20 of the nozzle casing 2 and against the outer peripheral wall of the insert 4 presses.

The insert parts 3, 4 are dimensioned such that the inside diameter of the insert part 4 is larger than the inside diameter of the insert part 3, but smaller than its outside diameter in an end section 21 which is adjacent to the insert part 4 and to the section 18 of the insert part 3 in the flow direction connects.

The insert part 3 is only screwed so far into the nozzle casing 2 that its end facing the insert part 4 still has a certain distance from the adjacent end region of the insert part 4, so that a circumferential, annular gap is present between the two insert parts 3, 4 represents a liquid inflow opening 22 for the liquid supplied via the liquid inflow nozzle 5.

The liquid inflow opening 22 is arcuate in longitudinal section and is delimited on the side of the insert 4 by a convex wall 23 which extends from the end of the insert 4 to the inner peripheral wall. On the side of the insert part 3, the liquid inflow opening 22 is delimited by a concave wall 24, which has approximately the same curvature as the convex wall 23 of the insert part 4 and is provided on the end of the end region 21 facing the insert part 4.

In the region of its mouth, the liquid inflow opening 22 runs along and parallel to the inner peripheral wall of the insert part 4, so that the liquid flowing into the cavity 12 receives a flow direction which runs parallel to the inner peripheral wall of the insert part 4. As a result, a liquid jacket is generated on this inner peripheral wall, which significantly reduces the wear of the insert 4 due to the blasting material.

The alignment of the liquid inflow opening 22 parallel to the circumferential wall can be effected in a simple manner by an axial projection 25 which adjoins the concave wall 24 towards the end face of the insert part 3 and can be inserted into the insert part 4 at a radial distance. The outer peripheral surface of the projection 25 runs parallel to the inner peripheral surface of the insert part 4.

The convex wall 23 and / or the concave wall 24 can have inclined webs, not shown, which give the inflowing liquid a spiral flow direction around the central axis 6.

At its inflow end, the liquid inflow opening 22 is connected to a circumferential annular chamber 26 which is delimited radially inwards by the end section 21 of the insert part 3 and radially outwards by the nozzle jacket 2. The annular chamber 26 is in turn connected to a radial bore 27 of the nozzle casing 2, into which a fastening section of the liquid inflow nozzle 5 can be inserted. The attachment of the liquid inflow connector 5 to the nozzle jacket 2 can be done, for example, in that the bore 27 is designed as a threaded bore and the fastening section of the liquid inflow connector 5 is screwed into the bore 27 until a flange 28 of the liquid inflow connector 5 abuts the outer surface of the nozzle jacket 2 .

In order to prevent liquid from the annular chamber 26 from entering the joint between the nozzle casing 2 and the insert part 3 or 4, elastic sealing means in the form of O-rings 29 are provided on both sides of the annular chamber, which in radial grooves of the nozzle casing 2nd lie and are in sealing contact with the outer peripheral surfaces of the insert parts 3, 4.

An embodiment variant of the invention is described in FIG. 2, in which the inflow direction of the wear particles is indicated by the arrow 30.

In contrast to FIG. 1, in the embodiment of FIG. 2 the insert part having the inlet opening 13 is not arranged to be axially movable within the nozzle casing 2, but the insert part following in the flow direction. The corresponding insert parts are designated 3 ', 4' in FIG. 2.

The axial fixation of the insert part 4 within the nozzle casing 2 'takes place here by means of a union nut 31, which with its axial section 31a can be screwed onto a corresponding external thread 17' of the nozzle casing 2 'and with a radially inwardly projecting section 31b on a radial one Shoulder 33 abuts, which is provided in the downstream end region of the insert 4 'and on its outer circumference.

It may be sufficient to fix the insert 4 'only in the outflow direction, since the insert 4' is only forced in this direction by the excess pressure in the annular chamber 26.

A sealing ring 34 between the union nut 31 and the nozzle casing 2 'prevents dirt from entering the gap between the nozzle casing 2' and the union nut 31 from outside and reaching the thread 32.

The rest of the structure essentially corresponds to the exemplary embodiment in FIG. 1.

The insert parts 3, 3 ', 4, 4' are advantageously made of a wear-resistant material, for example hardened steel, while the casing 2, 2 'can be made of aluminum or plastic.

Claims (13)

1. Device for jet processing, in particular for jet cleaning or jet cutting, of materials by means of a blasting material mixed with a liquid, in particular containing granular abrasion particles, consisting of a nozzle (1, 1 ') with a continuous cavity (12) which has an end at one end Has inlet opening (13) which is connected to a supply unit which supplies the abrasive particles under increased pressure to the nozzle (1, 1 '), and at the other end an outlet opening (14) for the blasting material and one between the inlet and outlet openings (13, 14) arranged liquid inflow opening (22) connected to a supply line for the liquid, characterized in that
that the liquid inflow opening (22) is designed as a circumferential gap and is delimited by nozzle elements (3, 3 ', 4, 4') which are axially movable relative to one another and lockable in different axial positions, and the cross section through which the liquid inflow opening (22) flows through the relative movement of these nozzle elements ( 3, 3 ', 4, 4') is changeable, and that the liquid inflow opening (22) is aligned in the region of its mouth parallel to the wall of the cavity (12), which is seen behind the liquid inflow opening (22) in the flow direction of the jet material, so that a this wall of the cavity (12) protective liquid jacket is formed. 2. Device according to claim 1, characterized in that a nozzle element (3, 3 ') preferably at its front end section (21) seen in the flow direction has a linear or arcuate outer peripheral or end face (24) in longitudinal section, which together with a the circumferential or end face (23) of the other nozzle element (4, 4 '), which is spaced apart therefrom, delimits the liquid inflow opening (22). 3. Apparatus according to claim 1 or 2, characterized in that a nozzle element (3, 3 ') at least in the region of its front end section (21) seen in the flow direction has an outer diameter which is smaller
is insertable as the inner diameter of the adjacent region of the cavity (12) within the other nozzle element (4, 4 ') and at least partially with this front end section (21) into the cavity (12) of the other nozzle element (4, 4'). 4. Device according to one of the preceding claims, characterized in that a nozzle element consists of a hollow cylindrical insert (3, 4 ') which is arranged axially movable within a nozzle shell (2, 2'), and the other nozzle element either from another , hollow cylindrical insert part (4, 3 ') immovably connected to the nozzle casing (2, 2'), which is arranged within the nozzle casing (2, 2 ') in alignment with the first insert part (3, 4'), or from the nozzle casing (2, 2 ') itself, the cavity (12) being formed within the insert parts (3, 3', 4, 4 ') or within the movable insert part (3, 4') and the nozzle casing (2, 2 ') is. 5. Device according to one of the preceding claims, characterized in that the movable nozzle element (3) has an external thread (17) and in a provided in the nozzle jacket (2) provided longitudinal bore (7) with an internal thread (8). 6. The device according to claim 5, characterized in that the movable nozzle element (3) by means of a screwed onto its external thread (17) and on the nozzle jacket (2) can be brought into contact with the lock nut (19). 7. Device according to one of the preceding claims, characterized in that the movable nozzle element (4 ') arranged in the flow direction behind the fixed nozzle element (3') and at least in the flow direction by a screwed onto the nozzle jacket (2 ') nut (31) is. 8. Device according to one of the preceding claims, characterized in that the liquid inflow opening (22) is connected to an upstream, circumferential annular chamber (26), which is preferably around a front end region (21) of the front insert part (3, 3 'seen in the flow direction) ) is trained around. 9. Device according to one of the preceding claims, characterized in that on at least one of the two the liquid inflow opening (22) delimiting walls (23, 24) of the nozzle elements (3, 3 ', 4, 4') flow guide elements are provided to the in to give the liquid (12) flowing in a spiral flow direction around the central axis (6) of the nozzle (1) hen. 10. The device according to claim 9, characterized in that the flow guide elements consist obliquely to the central axis (6) of the nozzle (1, 1 '), preferably over the entire circumference of the liquid inflow opening (22) around evenly distributed webs. 11. Device according to one of the preceding claims, characterized in that the nozzle element (3, 3 ') seen in the direction of flow extends to approximately the center of the nozzle (1) and has a first cavity section with a constant circular cross section which is smaller than a second cavity section with a constant, circular cross section, which is provided within the subsequent nozzle element (4, 4 '). 12. The device according to one of claims 4 to 11, characterized in that the fixed insert (4, 3 ') is fixed by means of a screw within the nozzle casing (2, 2') which in a in the nozzle casing (2, 2 ') The provided radial threaded bore (20) can be screwed in and brought into contact engagement with the outer peripheral surface of the insert part (4, 3 '). 13. Device according to one of claims 4 to 12, characterized in that the insert parts (3, 3 ', 4, 4') made of a hard material, for example hardened steel, and the nozzle jacket (2, 2 ') made of a relatively light Material, such as aluminum or plastic.

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