WO2006058659A1 - Method and device for water-jet machining - Google Patents

Abstract

The invention relates to a method and a device for water-jet machining, in which gas is added to the water that is used, thus producing a more intense abrasive action.

Description

 description

Method and device for water jet machining

The present invention relates to a method and apparatus for water jet machining of workpieces.

In particular, under the established term of "water jet cutting", methods and devices for machining workpieces with high pressure water jets are well known. Of particular importance when cutting flat workpieces, such as plastic or metal sheets. A jet of water generated under high pressure hits at a correspondingly high speed

Surface of the workpiece and there has an abrasive effect, so carries off material. By relatively finely focused water jets can approximate lines are cut through metal sheets and cut through appropriate guidance of the water jet with little effort and complicated shapes. The process is known to be relatively inexpensive _, and universal with respect to the materials to be cut, but has limitations in terms of operating speed and material thicknesses.

It is also known to add solid particles to the jet of water during water jet cutting in order to enhance the abrasive effect. In addition to the resulting additional equipment and material consumption, this procedure can also have disadvantages in the disposal of the resulting residues, so lead to environmental damage and disposal costs. Despite the improved performance in many cases, the fundamental economic advantage of the technique of water jet cutting in particular is partially offset.

The present invention is based on the technical problem of providing a method and a device with which water jet machining is made possible in an economical and effective manner.

The invention is directed to a method for water jet machining a workpiece, wherein the water as a water jet under pressure on the workpiece is directed and the workpiece is thereby abraded, characterized in that the water is added to a gas and the impact of the water jet on the workpiece by gas bubbles increased abrasion occurs, and to an apparatus for performing the method with a water jet nozzle for generating the water jet a high-pressure pump for generating the pressure for the water jet and a water pipe for supplying the high-pressure pump with water, characterized by a gas supply means for supplying the gas to the water upstream of the outlet of the water jet from the device.

Preferred embodiments of the inventions are given in the dependent claims and are explained below. The individual features of the invention relate both to the process category and to the device category, without explicitly distinguishing between them in detail.

The basic idea of the invention is to produce an increase in the abrasive effect by adding gas to the water used. As the water impinges on the surface of the workpiece at high velocity, gas bubbles have a surprisingly strong abrasive effect as a result of violent changes in pressure, which in principle is known from cavitation damage, for example to turbine blades.

In order to produce such gas bubbles, the water used can carry dissolved gas in it, which in the exit of the water jet from the nozzle and / or during

Impact of the water jet on the workpiece surface leads to gas bubbles, which one can speak of a cavitation effect in the narrower sense, especially in the latter case. But even if the gas bubbles are at least partially already present in the water jet before it impinges on the workpiece surface, corresponding effects are to be expected. In addition, the gas can also be added in such a way that the gas is not or not completely dissolved in the water, so entrained in gaseous form with the water jet In particular, situations may occur in which all three options are present, ie a part of the gas unresolved is entrained, a part of the gas at the exit from the nozzle from the solution already passes into the gas phase and another part of the Gas on impact of the water jet on the workpiece surface merges into the gaseous form.

In each case, the addition of a gas offers an inexpensive, procedurally simple and, with regard to the residues, particularly unproblematic form of an improvement in the abrasion effect of a water jet. This is especially true when using a low-cost and environmentally benign gas that does not need to be recovered or collected after use. A preferred example in the context of this invention is CO ₂ , which is easy to dissolve in water and is available at low cost. CO ₂ is anyway a component of the natural atmosphere and therefore harmless to the environment. Of course, it can also be used in the context of the invention in mixtures with other gases to produce certain effects.

Preferably, the gas is added downstream from a high pressure pump which produces the pressure necessary for the jet of water. Preferably, a relatively low pressure location is used. With a gas supply upstream of the high-pressure pump, there could possibly be the risk of cavitation damage to the pump and, because of the lower pressure, smaller quantities of gas would be solvable. Would you add more gas, so leave a portion of the gas in the gas phase, u would. U. impaired the effect of the pump.

Preference is given to a gas supply according to the principle of the water jet pump, that is to say at a point with water flowing past an opening substantially parallel to the opening surface. It can be ensured on the one hand without significant overpressure of the gas effective delivery into the water. On the other hand, the gas can be supplied in this form in a high-pressure region of the system, because the flow prevents a pressure compensation through the opening. Preferably, the gas supply line is arranged obliquely in the region of the opening in such a way that the gas flow forms an acute angle with the water flow.

Although the benefit of the invention may be just to avoid the addition of "solid abrasive", it is not excluded that both possibilities combine, so in addition to the gas additive additionally use solid Abrasionsmittei. However, in the context of this invention, preference is given to avoiding the already described advantages over the known methods with solid abrasives.

In addition to classical water-jet cutting, in particular of metal sheets, for example of a light metal alloy, purification processes are also possible within the scope of the invention. Therefore, the term of water jet machining was used here, which should not just relate to separation processes, but should include processing of various forms. Among other things, superficial layers, such as paint residues, can be removed particularly effectively with a method according to the invention. In addition to cutting and cleaning, of course, other workpiece machining with water jet are possible, such as the profiling or roughening of surfaces and the like.

In the following, an embodiment of the invention will be described in more detail, wherein the individual features of the embodiment may also be essential in other combinations of the invention.

Figure 1 shows schematically a device for water jet cutting according to this invention.

FIG. 2 shows for comparison a conventional apparatus for water-jet cutting with fixed addition of abrasive agent. FIG. 3 shows a comparison of cutting experiments with the invention

Device and a conventional water jet cutting device based on photographs of the tracks on workpieces.

FIG. 1 shows a highly schematic and partially sectional view of a water jet cutting device according to the invention. This one has

Druckwasserieitung 1 with a water outlet nozzle 2, through which a focused water jet 3 emerges at high speed and hits a workpiece 4.

The pressurized water line 1 is supplied via a high-pressure pump 5 with water, which is connected via a water supply line 6 to a water network. With a Gas supply device 7 is added to CO ₂ in an amount just below the solubility limit at the water pressure used for the water jet cutting device. The water pressure can be, for example, in the range of 1000 bar. This is done in a manner not shown here in accordance with the principle of a water jet pump through a running at an acute angle to the water flow gas line 10, which meets a parallel to the water flow opening. The gas flow should therefore be largely parallel to the flow of water and be employed only at a relatively low angle.

The CO2 dissolves well in the water, so that in this embodiment, a clean liquid jet reaches the nozzle 2.

As a result of the pressure drop in the exit of the jet of water from the nozzle 2, there may already be a certain part of the CO2 in the gas phase. This also depends on the speed of the water. For a substantial part of the rest, this only applies when the water jet 3 impinges on the surface of the workpiece 4, so that there is a markedly increased abrasive effect there due to the gas bubbles already contained in the water jet 3 and the gas bubbles produced by cavitation. A certain amount of gas in the water jet after it leaves the nozzle 2 does not necessarily disturb the invention.

In comparison to FIG. 1, FIG. 2 shows a conventional device of comparable design. Here, the gas supply device 7 is missing. The high-pressure pump 5 and the water supply line 6 are omitted, in contrast to FIG. 1, a mixing chamber 8 with a lateral closes to the nozzle 2 in the high-pressure pipe 1

Abrasivmittelzuführleitung 9 on. Through this supply line 9, a particulate abrasive, for example, a carbide added, which is mixed in the mixing chamber with the water jet. After hitting the water jet on the workpiece 4, not shown here fall 4 in addition to the removal of the workpiece 4 significant amounts of Abrasivmittels. In many cases, it is necessary to dispose of these mixed residues as hazardous waste relatively expensive. Figure 3 shows the results of experiments. The right column shows from top to bottom a kerf 1 1, ie a cross-sectional view, a plan view of the top and a bottom view of the underside of a machined with the inventive device of Figure 1 sheet. The sheet was made of AJMgSi with 3 mm thickness. The pressure in the high-pressure pipe 1 in this case was 360 mPa. The workpiece was moved at a feed rate of 30 mm / min.

In comparison, the left column shows corresponding images from top to bottom, but without the addition of CO2. It can be seen that only a half of the light metal sheet penetrating kerf was achieved in the conventional approach at the top left, whereas right above a completely severed sheet is seen. Accordingly, the upper side, middle line, left shows only a slightly widened erosion trace, while the right side with the dark line shows the passage of the water jet on the lower side. In the experiment with conventional water jet cutting the water jet has penetrated only selectively through the sheet. This is also shown in the bottom line, the left below a limited to a relatively short piece of track passage through the sheet shows, whereas right below a relatively clean led dividing line can be seen.

Thus, the invention provides an increase in performance of the conventional water jet cutting process without simultaneous disposal problems and at relatively low additional costs.

Claims

claims 1. A method for water jet machining a workpiece (4), wherein the water is directed as a water jet (3) under pressure on the workpiece (4) and the workpiece (4) is thereby abraded, characterized in that the water is added to a gas and upon impact of the water jet (3) on the workpiece (4) by gas bubbles increased abrasion occurs. 2. The method of claim 1, wherein the gas is completely dissolved in the water and the gas bubbles occur by cavitation. 3. The method of claim 1, wherein the gas is at least partially undissolved and added as gas bubbles to the water jet (3). 4. The method according to any one of the preceding claims, wherein the gas is added to the water downstream of a high-pressure pump (5) for generating the pressure of the water jet (3). 5. The method according to any one of the preceding claims, wherein the gas is added to the water according to the principle of a water jet pump. 6. The method according to any one of the preceding claims, wherein the gas contains CO ₂ , preferably CO ₂ . 7. The method according to any one of the preceding claims, wherein the water jet (3) contains no solid abrasion additives. 8, Method according to one of the preceding claims for water jet cutting flat workpieces (4), in particular metal sheets. 9. The method according to any one of the preceding claims for cleaning, in particular stripping, of workpieces (4). 10. Apparatus for carrying out a method according to one of the preceding claims with a water jet nozzle (2) for generating the water jet (3), a high pressure pump (5) for generating the pressure for the water jet (3) and a water pipe (6) for the supply of High-pressure pump (5) with water, characterized by a gas supply means for supplying the gas to the water upstream of the outlet of the water jet (3) from the device. 11. The device according to claim 10, wherein the gas supply means (7) between the nozzle and the high-pressure pump (5) is arranged. 12. The apparatus of claim 10 or 11, wherein the gas supply means comprises a water jet pump.