EP0515449A1

EP0515449A1 - Device for cutting and cleaning objects using a water/abrasive mixture at high pressure.

Info

Publication number: EP0515449A1
Application number: EP91903878A
Authority: EP
Inventors: Hannes Domann
Original assignee: GKSS Forshungszentrum Geesthacht GmbH
Current assignee: GKSS Forshungszentrum Geesthacht GmbH
Priority date: 1990-02-23
Filing date: 1991-02-20
Publication date: 1992-12-02
Anticipated expiration: 2011-02-20
Also published as: DE59103698D1; EP0515449B1; WO1991012930A1; DE4005691A1

Abstract

Un dispositif (10) sert à couper et à nettoyer des objets, ainsi qu'à enlever de manière appropriée des matériaux, au moyen d'un jet d'eau (15) sous haute pression qui traverse un conduit d'admission (13) agencé dans une buse (17) d'admission d'eau et un conduit (14). Un produit abrasif (160) est introduit dans la chambre de mélange (12) après avoir été ajouté au jet d'eau. La chambre de mélange (12) est formée d'un alésage axial par rapport à l'axe (18) de la buse d'admission, ménagé dans un corps (120) de chambre à mélange et délimité du côté (19) de la buse d'admission d'eau par la buse d'admission d'eau (17).A device (10) is used for cutting and cleaning objects, as well as for the appropriate removal of materials, by means of a jet of water (15) under high pressure which passes through an inlet duct (13) arranged in a water inlet nozzle (17) and a conduit (14). An abrasive product (160) is introduced into the mixing chamber (12) after being added to the water jet. The mixing chamber (12) is formed of a bore axial with respect to the axis (18) of the inlet nozzle, formed in a body (120) of the mixing chamber and delimited on the side (19) of the water inlet nozzle through the water inlet nozzle (17).

Description

Device for cutting and cleaning objects using a water-abrasive mixture at high ambient pressure

description

The invention relates to a device for cutting and cleaning objects and for targeted material removal by means of a high-pressure, a mixing chamber from an inlet formed in a water inlet nozzle to an outlet traversing water jet which an abrasive passes through in the mixing chamber Introducing it into the water jet.

A device of this type is known (EP-A-0 221 236).

Both the known device and other known devices of the same type are fundamentally optimized for an ambient pressure of 1 bar (atmospheric normal pressure). In various applications of the device, what must be done under increased ambient pressure has the considerable disadvantage that the cutting, cleaning and removal performance of the device drops considerably, which is essentially due to the expansion of the water jet after it emerges from the water inlet nozzle, ie in the region of the mixture between water and has abrasives. In addition, at increased ambient pressure, an increase in the air mass conveyed was determined by the suction process of the abrasive, which also adversely affects the performance of the device.

It should be mentioned that this serious problem has not been given any significant attention in the prior art, with the result that no ways of solving this problem have been proposed.

It is an object of the present invention to provide a device which operates at high ambient pressure and which does not experience any significant loss compared to the performance at normal ambient pressure, the device being no more complicated in construction than known devices for normal ambient pressure should and can also be produced at the same cost as known devices that work under normal pressure conditions.

The object is achieved according to the invention in that the mixing chamber is formed by a bore in a mixing chamber body which is axial to the inlet nozzle axis, the water nozzle inlet side. is limited by the water inlet nozzle.

In contrast to known devices operating under normal pressure, in which the mixing chamber is of relatively large volume and essentially by a housing body, the inside of the mixing chamber includes, is formed, in the device according to the invention there is only one axial bore to the water inlet nozzle axis, which can be formed as a mixing chamber of defined diameter and defined axial length. Since the jet widening of the water jet entering the mixing chamber increases in proportion to the ambient pressure, it is possible according to the invention due to the resulting reflection behavior of the water jet jacket with simple means to create an optimal inlet geometry over a defined pressure range of predetermined size, which with simple Means is directly adapted to the prevailing pressure, ie by predetermined axial length and / or predetermined diameter of the bore.

A major difficulty with devices of this type is that the high cutting performance of the device obtained in the manner described above, even at high ambient pressure, is not negated by the fact that losses in performance due to production errors-related axis errors occur between the inlet nozzle axis and outlet nozzle axis or outlet axis in the mixing chamber body . Manufacturing errors and / or assembly errors can have a very considerable influence on the performance of the device if they accumulate, with the result that the performance drops significantly. In order to easily compensate alignment errors between the inlet nozzle axis and the outlet axis, it is advantageous to design the water inlet nozzle in such a way that it at least partially protrudes into the mixing chamber.

According to an advantageous. Embodiment of the invention, the mixing chamber body is accommodated in a body holder, which on one side with a connecting piece for connection to a high pressure water source and on the other side is connected to a stop nut. This configuration of the device advantageously enables the mixing chamber body to be quickly replaced in accordance with the pressure conditions in the vicinity of the device, since the mixing chamber body can be exchanged easily and quickly as an insert with an externally identical geometry and different bore sizes.

For this purpose, it is advantageous to form the connections by means of threaded connections which, on the one hand, enable an automatic axis adjustment between the connector and thus the inlet nozzle on the one hand and on the other hand between the mixing chamber body and thus the outlet nozzle axis or the mixing chamber body axis. Added to this is the fact that threaded connections of this type can be loosened or fixed relatively quickly and thus without tools.

In principle, the actual outlet nozzle can be formed separately from mixing chamber bodies because of its special requirements regarding its hardness. However, for reasons of simplified storage, on the one hand, and simplified production and thus cost savings, on the other hand, it is advantageous to form the extension of the mixing chamber body in one piece with the outlet nozzle.

Due to the fact that the water inlet nozzle sits as a separate part, as a rule, in the lower part of the connecting piece and is only clamped there between the connecting piece and the mixing chamber body, it may be advantageous for the essentially cylindrical mixing chamber body to be included lateral play in the substantially cylindrical bore of the body holder is added, so tolerances in To compensate for the seat of the water inlet nozzle in the connection piece without restricting the performance of the device, since it is essential to achieve an axial alignment between the inlet nozzle axis and the outlet nozzle axis.

Another advantage of a one-piece mixing chamber body with the outlet nozzle is the usually good correspondence between the axes of the mixing chamber bore and the outlet nozzle bore, which results from the manufacturing process. If the water nozzle is precisely fitted in the mixing chamber bore, this automatically results in an exact alignment of the water nozzle axis with the outlet nozzle axis.

The manufacturing tolerances of the body holder have no influence on the alignment of the axes.

In another advantageous embodiment of the device, a separate bushing device is accommodated in the stop nut, which has a bore for receiving an outlet nozzle separate from the mixing chamber body. In this embodiment, for example, the mixing chamber body can be made of a material that is not as high-quality as the outlet nozzle as a simple cylindrical body, while the outlet nozzle is pressed against the mixing chamber body in axial alignment, end face to end face, by the stop nut, seated in the socket device .

In order to be able to compensate for axis errors between the axis of the mixing chamber body and the axis of the outlet nozzle when the design is separate, it is advantageous for the bore axis of the bore to be eccentric to the axis of the bushing device. In order to achieve a secure fit of the outlet nozzle relative to the mixing chamber body, in particular in the embodiment of the device described above, the stop nut is closed with a union nut provided with a through hole, the free end of the outlet nozzle projecting through the through hole and between Union nut and bushing device, a connection agring, which is firmly connected to the outlet nozzle, is included.

The axial length of the mixing chamber is advantageously in the range between 2-4 mm.

The abrasive one! ate is advantageously introduced through the mixing chamber body into the mixing chamber, so that the geometry of the mixing chamber designed as a bore in the mixing chamber body described above is essentially not disturbed.

It is advantageous here to design the abrasive inlet by an abrasive tube which is interchangeably inserted into the abrasive inlet. The abrasive inlet is preferably tapered towards the actual mixing chamber, so that an abrasive inlet opening into the mixing chamber body can be defined with a defined size.

In order to be able to vary this size depending on the type of use of the device, the abrasive tube has an external thread which engages in a corresponding internal thread formed in the mixing chamber body and / or in the body holder, so that abrasive tubes of different geometries can be used very quickly can. In order to be able to better adapt the entry geometry of the water-abrasive mixture into the outlet of the outlet nozzle or the mixing chamber body again to the changed conditions at higher ambient pressure, the mixing chamber is advantageously located at its outlet for the water-abrasive agent Seeing end tapered funnel-shaped.

As already mentioned, the outlet nozzle is under very high mechanical stress due to the high mechanical influences on it by the water-abrasive mixture. For this reason, as is common practice, the outlet nozzle is made of a suitable hard material. However, it can also be sensible and therefore advantageous to likewise form the mixing chamber body from the same hard material if, for example, the mixing chamber body and the outlet nozzle are manufactured in one piece, the increased material expenditure for the mixing chamber body then taking a back seat compared to the manufacturer ¬ costs of separate mixing chamber body made of a special material.

To influence the jet geometry at the outlet nozzle and the abrasion behavior of the outlet nozzle bore, an additional fluid supply device is advantageously provided in the outlet nozzle region. This addition can take place vertically or at an acute angle in the jet direction to the outlet nozzle bore via one or more fluid channels or via an annular addition geometry. If an abrasive nozzle that is not formed in one piece with the mixing chamber body is used, this can preferably be done at the point of division. Different jet behavior can be achieved by the type of fluid and the fluid pressure. In addition to the preferably dry abrasive agent consisting of abrasive material and air or gas, the wet addition consisting of water and abrasive material can also be used in the device described here. The pressure range in which the abrasive additives advantageously works can be between 1 and approx. 300 bar.

The invention will now be described with reference to the following schematic drawings using two exemplary embodiments. In it show:

Fig. 1 in section of a first embodiment of the device and

Fig. 2 in section a second embodiment of the device.

The device 10 essentially consists of a mixing chamber body 120 and a so-called connection piece 121, which is connected on a free side to a pressure line, not shown here, in a known manner. The connecting piece 121 has a through hole which runs essentially centrally, through which the water brought in via the pressure line (not shown) passes according to the arrow 15. At the lower end of the connection piece 121 facing the mixing chamber 12, a nozzle insert 19 is provided which, for example, comprises the water inlet nozzle 17 made of a hard material such as sapphire or the like. In the embodiments of the device 10 described here, the nozzle insert is seated in a conical seat in the connecting piece 121 formed at the lower end, based on the figures Nozzle insert 19 has a through hole which passes through it essentially centrally, the one end of the through hole which points towards the mixing chamber 12 forming an inlet 13 of the water or water jet 15 into the mixing chamber 12.

The mixing chamber body 120 is essentially rotationally symmetrical in the form of a cylinder. The actual mixing chamber 12 is formed by a bore which is axial to the inlet nozzle axis 18 and which is delimited on the water inlet nozzle side 19 by the water inlet nozzle 17. The water inlet nozzle 17 protrudes into the mixing chamber, the water inlet nozzle 17 being supported with a flange-like collar 170 on the upper boundary surface 123 of the mixing chamber body 120.

The axial length 122 of the mixing chamber 12 is in the range of 2-8 mm, preferably in the range of 2-4 mm, with chamber diameters of 2-8 mm being advantageous, for example.

In the mixing chamber 12 designed as a bore, the abrasive agent 160 is introduced in a known manner into the water jet 15 passing through the mixing chamber 12 from the inlet 13 to an outlet 14, which is formed here in the mixing chamber body 120.

The water inlet nozzle axis 18 and thus that of the water jet 15 must be aligned with high precision axially to the outlet nozzle axis 24 or to the mixing chamber body axis 124 in order to ensure optimum energy transmission of the water jet 15 to the abrasive medium 160. The mixing chamber body 120 is received in a body holder 25. This is connected on one side 250 to the connecting piece 121 and on the other side 151 to a stop nut 132 via threaded connections 152, 153 formed there in each case. The mixing chamber body 120 itself is essentially cylindrical. The bore 254 passing through the body holder 25 is also essentially cylindrical and is dimensioned such that the mixing chamber body 120 is received in it with radial play.

1, the mixing chamber body 120 is formed in one piece with the outlet nozzle 21, namely in the extension of the outward extension of the mixing chamber body 120. The stop nut 32, which has a recess 34 in its inner bore 33, encloses the mixing chamber body 120, which is correspondingly tapered in diameter at this point. The inner bore 33 has a larger diameter than the diameter of the outlet nozzle 21 formed as an extension in the mixing chamber body 120, the diameter being dimensioned such that the outlet nozzle 21 passes through the inner bore 33 with play.

In the lower part of the outlet nozzle 21 there can be a fluid channel 212 or a plurality of fluid channels which run at right angles or at an acute angle (here at 45 ') to the outlet nozzle axis 24. The fluid channels are connected via an annular gap 321 to a fluid addition connection 36. A pair of sealing rings 320 realizes the pressure closure from the environment. In the embodiment of the device 10 shown in FIG. 2, the mixing chamber body 120 is formed separately from the outlet nozzle 21. A separate bushing device 28 is received in the stop nut 32 there. The bushing device 28 has a bore 29 for the passage or for receiving the outlet nozzle 21. The bore axis 30 of the bore 29 can be formed eccentrically to the bushing device axis 31, so that error tolerances of all components of the device can be compensated in such a way that an axial alignment of the inlet nozzle axis 18, the mixing chamber axis 124 and the outlet nozzle axis 24 is achieved and an axial error goes to zero.

In the embodiment according to FIG. 2, the stop nut 32 has an external thread 35 at its outward-pointing end, on which a union nut 40 provided with a through hole 38 is seated. The diameter of the through hole 38 is dimensioned such that the outlet nozzle 21 projects through the through hole 38 with play. By means of the stop ring 39, the outlet nozzle 21 is held in the bushing device 28 or in the stop ring 39 and pressed with its one flat boundary surface 210 against the lower boundary surface 125 of the mixing chamber body 120 and fixed in this position. As mentioned at the beginning, the abrasive is conveyed into the mixing chamber 12 via an abrasive medium. The Abrasi medium one! Ate 19 is formed by an abrasive tube 161 that can be used therein and has an external thread 162. The external thread 162 engages in a corresponding internal thread 225, which can be formed either in the mixing chamber body 120 and / or in the body holder 25. The abrasive inlet 16 is conically tapered towards the mixing chamber 12, thus including it on the one hand a sealing ring creates a sealing seal between the mixing chamber 12 and the environment and, on the other hand, defined opening diameters can be provided in the abrasive medium pipe in accordance with the desired abrasive medium delivery rate. In this way, the abrasive agent pipe 161 can be replaced very quickly and selected according to the required conditions.

A defined distance between the lower edge 210 of the mixing chamber body and the upper edge of the outlet nozzle 21 can be set by an appropriately selected stop ring 39. A targeted addition of fluid can take place via the resulting annular gap. The fluid is supplied through a suitable hole in the stop nut.

Reference sign list

253 thread

10 device 254 bore

11 Water-abrasive mixture 255 female thread

12 mixing chamber 26 mixing chamber

120 mixing chamber body

121 connector 28 socket insert

122 axial length direction 23 upper boundary surface 29 bore 24 axis of the chamber body 30 axis of bore 25 lower boundary surface 31 bushing insert 26 recessed body bore direction axis 3 inlet (water inlet nozzle) 32 stop nut 4 outlet (outlet nozzle or 320 sealing rings

Mi sehkämmerkörper) 321 ring channel 5 water jet 33 inner bore 6 abrasive fluid inlet 34 recess 60 abrasive agent 35 external thread 61 abrasive fluid eye 36 fluid addition 62 external thread connection 63 abrasive inlet axis 37 7 water inlet nozzle 38 through hole 70 flange-like collar 39 stop ring 8 inlet nozzle hole 0 outlet nozzle 10 boundary surface 12 fluid channel 2 funnel-shaped design 3 nozzle opening 4 outlet nozzle axis 5 body holder 50 page 51 page 52 thread

Claims

1. Device for cutting and cleaning objects and for targeted material removal by means of a high-pressure water jet that crosses a mixing chamber from an inlet formed in a water inlet nozzle to an outlet, to which an abrasive is fed into the mixing chamber by being introduced into the water jet. characterized in that the mixing chamber (12) is formed by a bore in a mixing chamber body (120) which is axial to the inlet nozzle axis (18) and which is delimited on the water inlet nozzle side (19) by the water inlet nozzle (17).

2. Device according to claim 1, characterized in that the water inlet nozzle (17) protrudes into the mixing chamber (12).

3. Device according to one or both of claims 1 or 2, characterized in that the mixing chamber body (120) is received in a body holder (25) which on one side (250) with a connecting piece (121) for connection to a high pressure water source e and on the other side (251) with a stop nut (32) in connection.

4. The device according to claim 3, that the connections are threaded connections (252, 253).

5. The device according to one or more of claims 1 to 4, characterized in that the mixing chamber body (120) is integrally formed in its extension with the outlet nozzle (21).

6. The device according to one or more of claims 3 to 5, characterized in that the substantially cylindrical mixing chamber body (120) with lateral play in the substantially cylindrical bore (254) of the body holder (25) is received.

7. The device according to one or more of claims 3 to 6, characterized in that in the stop nut (32) a bushing device (28) is received, which has a bore (29) for receiving the outlet nozzle (21).

8. The device according to claim 7, characterized in that the bore axis (30) of the bore (29) to the Buchsen¬ device axis (31) is eccentric.

9. The device according to one or more of claims 3 to 8, characterized in that the stop nut (32) is closed with a union nut (40) provided with a through hole.

10. The device according to one or more of claims 1 to 9, characterized in that the axial length (122) of the mixing chamber (12) is in the range of 2-4 mm.

11. The device according to one or more of claims 1 to 10, characterized in that an abrasive inlet (16) through the mixing chamber body (120) into the mixing chamber (12).

12. The apparatus according to claim 11, characterized gekennzeich¬ net that the abrasive inlet (16) through an insertable in this abrasive tube (161) is formed.

13. The device according to one or both of claims 11 or 12, characterized in that the Abrasivmit¬ teleinlaß (16) to the mixing chamber (12) is conically tapered.

14. The device according to one or both of claims 12 or 13, characterized in that the abrasive tube (161) has an external thread (162) which is formed in a corresponding one in the mixing chamber body (120) and / or in the body holder (25) Internal thread (255)

15. The device according to one or more of claims 1 to 14, characterized in that the mixing chamber (12) at its outlet (14) for the water-abrasive mixture (12) facing end is funnel-shaped.

16. The device according to one or more of claims 1 to 5, characterized in that the mixing chamber body (120) consists of hard material.

17. The device according to one or more of claims 1 to 16, characterized in that in the mixing chamber body (120) or in the outlet nozzle (21) in the direction of the water jet (15) below the Abrasi vmitteleinl asses (16) at least one fluid channel (212) is provided, which opens into the outlet nozzle bore (20).

18. The apparatus according to claim 17, characterized gekennzeich¬ net that an annular channel (321) is formed around the mixing chamber body (120) or the outlet nozzle (21), in which on the one hand the fluid channel (212) and on the other hand a fluid addition connection (36 ) opens, the annular channel (321) being sealed on both sides by sealing rings (320) against the mixing chamber body (120) or the outlet nozzle (21).

19. The device according to one or more of claims 5 to 17, characterized in that between the lower boundary surface (125) of the mixing chamber body (120) and the opposite boundary surface (210) of the outlet nozzle (21), a gap of predetermined width for the supply of fluid is provided in which on the one hand a fluid addition connection (36) opens and on the other hand it opens into the mixing chamber bore (126) and / or the outlet nozzle bore (20).