EP3600765A1 - Installation et procédé de découpe par jet d'eau chargée d'abrasif en suspension - Google Patents

Installation et procédé de découpe par jet d'eau chargée d'abrasif en suspension

Info

Publication number
EP3600765A1
EP3600765A1 EP17716813.5A EP17716813A EP3600765A1 EP 3600765 A1 EP3600765 A1 EP 3600765A1 EP 17716813 A EP17716813 A EP 17716813A EP 3600765 A1 EP3600765 A1 EP 3600765A1
Authority
EP
European Patent Office
Prior art keywords
pressure
abrasive
valve
pressure vessel
water
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
EP17716813.5A
Other languages
German (de)
English (en)
Other versions
EP3600765B1 (fr
Inventor
Marco Linde
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
ANT Applied New Technologies AG
Original Assignee
ANT Applied New Technologies AG
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by ANT Applied New Technologies AG filed Critical ANT Applied New Technologies AG
Priority to PL17716813.5T priority Critical patent/PL3600765T3/pl
Publication of EP3600765A1 publication Critical patent/EP3600765A1/fr
Application granted granted Critical
Publication of EP3600765B1 publication Critical patent/EP3600765B1/fr
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B24GRINDING; POLISHING
    • B24CABRASIVE OR RELATED BLASTING WITH PARTICULATE MATERIAL
    • B24C7/00Equipment for feeding abrasive material; Controlling the flowability, constitution, or other physical characteristics of abrasive blasts
    • B24C7/0007Equipment for feeding abrasive material; Controlling the flowability, constitution, or other physical characteristics of abrasive blasts the abrasive material being fed in a liquid carrier
    • B24C7/0015Equipment for feeding abrasive material; Controlling the flowability, constitution, or other physical characteristics of abrasive blasts the abrasive material being fed in a liquid carrier with control of feed parameters, e.g. feed rate of abrasive material or carrier
    • B24C7/0023Equipment for feeding abrasive material; Controlling the flowability, constitution, or other physical characteristics of abrasive blasts the abrasive material being fed in a liquid carrier with control of feed parameters, e.g. feed rate of abrasive material or carrier of feed pressure
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B24GRINDING; POLISHING
    • B24CABRASIVE OR RELATED BLASTING WITH PARTICULATE MATERIAL
    • B24C7/00Equipment for feeding abrasive material; Controlling the flowability, constitution, or other physical characteristics of abrasive blasts
    • B24C7/0007Equipment for feeding abrasive material; Controlling the flowability, constitution, or other physical characteristics of abrasive blasts the abrasive material being fed in a liquid carrier
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B24GRINDING; POLISHING
    • B24CABRASIVE OR RELATED BLASTING WITH PARTICULATE MATERIAL
    • B24C1/00Methods for use of abrasive blasting for producing particular effects; Use of auxiliary equipment in connection with such methods
    • B24C1/04Methods for use of abrasive blasting for producing particular effects; Use of auxiliary equipment in connection with such methods for treating only selected parts of a surface, e.g. for carving stone or glass
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B24GRINDING; POLISHING
    • B24CABRASIVE OR RELATED BLASTING WITH PARTICULATE MATERIAL
    • B24C1/00Methods for use of abrasive blasting for producing particular effects; Use of auxiliary equipment in connection with such methods
    • B24C1/04Methods for use of abrasive blasting for producing particular effects; Use of auxiliary equipment in connection with such methods for treating only selected parts of a surface, e.g. for carving stone or glass
    • B24C1/045Methods for use of abrasive blasting for producing particular effects; Use of auxiliary equipment in connection with such methods for treating only selected parts of a surface, e.g. for carving stone or glass for cutting
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B24GRINDING; POLISHING
    • B24CABRASIVE OR RELATED BLASTING WITH PARTICULATE MATERIAL
    • B24C7/00Equipment for feeding abrasive material; Controlling the flowability, constitution, or other physical characteristics of abrasive blasts
    • B24C7/0084Equipment for feeding abrasive material; Controlling the flowability, constitution, or other physical characteristics of abrasive blasts the abrasive material being fed in a mixture of liquid and gas

Definitions

  • the present disclosure relates to a water abrasive slurry slicer having the features specified in the preamble of claim 1 and a process for water abrasive slurring slicing.
  • Water-abrasive suspension cutters are used to cut materials by means of a high-pressure water jet to which an abrasive is added.
  • Water-abrasive suspension cutting systems are to be differentiated from water-abrasive injection-cutting systems, in which the abrasive is introduced only in or at an outlet nozzle in the already very much accelerated water.
  • the high-pressure water is first mixed with the abrasive and then the water-abrasive slurry is accelerated in the outlet nozzle.
  • the abrasive-water ratio can be higher and a higher cutting force can be selected be achieved because the water is mixed under high pressure upstream of the outlet gland without air inclusions controlled with the abrasive.
  • a portion of the water flow can be performed by an abrasive container, which is designed as a pressure vessel.
  • an abrasive container which is designed as a pressure vessel.
  • Such a system is z. B. from EP 1 199 136 known.
  • a technical challenge with these systems is the refilling of the abrasive, since the plant must be taken out of service, the abrasive container must be brought to a depressurized state and only then can be filled. In industrial applications, however, continuous cutting is often desired in which the equipment for filling the abrasive need not be taken out of service.
  • EP 2 755 802 Bl and WO 2015/149867 Al describe lock solutions to ensure continuous operation of the system. Due to the particularly high pressures, in some cases over 2,000 bar, however, the cyclical loading and unloading of a lock chamber is a technical challenge. In particular, the setting of a desired mixing ratio between water and abrasive in the cutting jet with the known systems designed as difficult.
  • a water abrasive slurry cutter is provided with a high-pressure source for supplying water under high pressure
  • the pressure vessel via a controllable throttle with the high pressure line is fluidly connected, wherein the throttle is arranged on the input side of l o pressure vessel and is adapted to regulate the inflow into the pressure vessel from the high pressure line depending on at least one controlled variable.
  • a desired mixing ratio between water and abrasive in the cutting jet can be set.
  • the input side of the pressure vessel arranged and controllable throttle is traversed by clear water without abrasive and thus wears considerably less than if it were arranged on the output side.
  • the controllable throttle may also be referred to as a control valve, which may optionally completely shut off the inflow.
  • a shut-off valve may be disposed downstream or upstream of the throttle to completely stop the flow of desiccant from the pressure vessel.
  • the shut-off valve can be signaled by means of a sensor signal to shut off the pressure vessel from the high-pressure line. This can possibly be done when a minimum level is reached, which should not be undershot.
  • the at least one controlled variable may include a sensor signal and / or an operating parameter of the high pressure source.
  • the controlled variable can contain several parameters, combinations of parameter In this sense, having "having" means that the at least one controlled variable depends on the sensor signal or the parameter, or that the sensor signal or the parameter is included in the controlled variable.
  • the at least one controlled variable comprises an abrasive medium flow from the pressure vessel or a parameter characteristic of an abrasive flow from the pressure vessel.
  • the system may include a first level sensor for signaling at least a first level of abrasive in the pressure vessel. The at least one controlled variable may then have a temporal change of the first fill level.
  • the system may include a first level sensor for signaling at least a first level of abrasive in the pressure vessel and a second level sensor for signaling at least a second level of abrasive in the pressure vessel, wherein the at least one controlled variable is a time difference between the first level and the second Can have level.
  • the level sensors may be ultrasonic sensors or optical sensors, which are arranged at different vertical positions on the pressure vessel and can signal a certain level. With known geometry of the pressure vessel and known vertical distance between the first and the second level sensor, the time difference for a Abrasivffenent Spotify Let.
  • the system can have an abrasive medium flow sensor arranged on the output side of the pressure vessel for signaling an abrasive removal flow, according to which the inflow to the pressure vessel can be regulated.
  • the abrasive medium flow sensor can, for example, run through an output-side abrasive medium line. of the abrasive particles or otherwise measure the abrasive flow. This can take place, for example, optically, inductively via ferromagnetic markers in the abrasive or via a structure-borne sound measurement.
  • the controlled variable speed and / or tent position. Have current consumption of the high pressure source. About the speed and / or power or current consumption of the high pressure source can be closed to the flow of water through the high pressure line, which can co-determine the mixing ratio in the cutting jet. Therefore, these or other operating parameters of the high-pressure line can preferably be included in the at least one controlled variable. Alternatively or additionally, a flow sensor can measure or signal a water flow through the high-pressure line, so that it can enter into the at least one controlled variable.
  • a water abrasive slurry cutting method comprising the steps of:
  • the regulation is carried out as a function of a sensor signal and / or an operating parameter of the high-pressure source. leads.
  • the regulation can be carried out as a function of an abrasive flow from the pressure vessel.
  • the control can be carried out in dependence on a change over time of a first level of abrasive in the pressure vessel, wherein the first level is signaled by a first level sensor.
  • control can be carried out as a function of a time difference between a first level of abrasive in the pressure vessel and a second level of abrasive in the pressure vessel, wherein the first level of a first level sensor and the second level is signaled by a second level sensor.
  • regulation may be carried out as a function of an abrasive agent flow, the abrasive agent flow being signaled by an abrasive fluid flow sensor arranged on the output side of the pressure vessel.
  • the rules can alternatively or additionally also be carried out as a function of a rotational speed or a power or current consumption of the high-pressure source.
  • Fig. 1 is a schematic circuit diagram of a first embodiment of the disclosed herein water-abrasive suspension cutting machine
  • Fig. 2 is a schematic circuit diagram of a second embodiment of the herein disclosed water-abrasive suspension cutting machine
  • Fig. 3 is a schematic circuit diagram of a third embodiment of the disclosed herein water-abrasive suspension cutting machine;
  • Fig. 4 is a schematic circuit diagram of a fourth embodiment of the disclosed herein water-abrasive suspension cutting machine;
  • Fig. 5 is a schematic circuit diagram of a fifth embodiment of the disclosed herein water-abrasive suspension cutting machine
  • 6a-c are schematic partial circuit diagrams of three different embodiments of a conveying aid of the disclosed herein water-abrasive suspension cutting machine;
  • Figures 7a-c are schematic partial circuit diagrams of three different embodiments of an abrasive agent flow control of the herein disclosed water abrasive slurry cutting machine;
  • 8-12 are schematic diagrams of five different embodiments of an abrasive delivery means of the herein disclosed Water Abrasive Suspension Cutting Machine;
  • FIG. 13 is a schematic flow diagram of one embodiment of the water-abrasive-suspension cutting method disclosed herein.
  • FIG. 14 shows pressure-time diagrams in a lock chamber, in an accumulator and in a high-pressure line according to an embodiment of the water-abrasive suspension cutting device disclosed herein;
  • FIG. 15a-b show cross-sections in an xz-plane through a refill valve in two different open positions according to an embodiment of the disclosed herein water-abrasive suspension Schneidanla- ge;
  • FIG. 16a-b show cross-sections in an xz plane through a refill valve in two different closed positions according to an embodiment of the water-abrasive suspension cutting system disclosed herein;
  • FIG. 16a-b show cross-sections in an xz plane through a refill valve in two different closed positions according to an embodiment of the water-abrasive suspension cutting system disclosed herein;
  • 17a-b are cross-sections in a yz plane through a refill valve in the closed position according to two different embodiments of the disclosed herein water-abrasive suspension cutting machine;
  • 18a-b are perspective views of a refill valve according to an embodiment of the disclosed herein water-abrasive suspension cutting machine.
  • 19a-b are cross-sections through a shut-off valve in the form of a needle valve according to two different embodiments of the disclosed herein water-abrasive suspension cutting machine in an open position.
  • I has a high pressure source 3, the water in a high pressure line 5 under a high pressure po of about 1 .500 to 4,000 bar available.
  • the high-pressure line 5 is connected to an outlet nozzle 7 from which the high-pressure water emerges at a very high speed in a jet 9. So that the jet 9 can be used effectively as a cutting jet for cutting material, the high-pressure line 5 is branched such that at least part of the flow through the high-pressure line 5 through a pressure vessel
  • a water-abrasive suspension 13 is located.
  • a shut-off valve 15 the feeding of the water abrasive suspension 13 to the outlet nozzle can be switched on and off.
  • the proportion of the water-abrasive suspension 13 in the jet 9 can be adjusted via a throttle 17 by the flow rate amount is throttled in the guided through the pressure vessel 1 1 side of the high-pressure line 5.
  • the throttle 17 may be configured statically, for example in the form of a pinhole or adjustable or adjustable.
  • the throttle 17 is adjustable, so that the throttle 17 may possibly also completely shut off the inflow into the pressure vessel 1 1, so that it is possible to dispense with the shut-off valve 15.
  • the throttle 17 is preferably controllable, a signal which is characteristic for the abrasive average flow and which can be obtained from a sensor or an available operating parameter being used as a control variable for regulating the opening of the throttle 17 (see FIGS. 7a-c). ,
  • a refill valve 19 is arranged in the form of a ball valve above the pressure vessel 1 1.
  • the refill valve 19 connects a lock chamber 21 arranged above the refill valve 19 with the pressure vessel 11.
  • a filling valve 23 is arranged, which connects a arranged above the lock chamber 21 Vietnamese Stahlstofftrichter 25 with the lock chamber 21.
  • the filling valve 23 may be configured substantially identical to the refill valve 19 in the form of a ball valve.
  • the refilling funnel 25 is not under pressure, so that dry, moist or wet abrasive or a water-abrasive agent suspension can be introduced from above (see FIGS. 8-12).
  • This may be, at least in part, an abrasive agent that has been reprocessed from the cutting jet 9 and that is conveyed via a conveying device (see FIGS. 8-12) in dry, wet, frozen, pelleted or suspended state.
  • dierter form can be filled from above into the refilling funnel 25.
  • the lock chamber 21 may be temporarily depressurized.
  • a pressure in the lock chamber 21 can be discharged via a pressure relief valve 27 in the form of a needle valve into a drain 29.
  • the filling valve 23 may be open, so that abrasive falls from the refilling funnel 25 into the lock chamber 21.
  • This gravitational filling of the lock chamber 21 with abrasive can be supported and accelerated by a pump 31st
  • the pump 31 may be connected on the suction side with the lock chamber 21 and the pressure side with the refilling funnel 25.
  • the pump 31 sucking abrasive into the lock chamber 21. This is particularly useful especially when abrasive in the tapered lower portion of the refilling funnel 25 and the filling valve 23 clogged.
  • the pump 31 does not need to be designed for high pressure, it is advantageous if the pump 31 by means of a Pumpenabsperrventils 33 in the form of a needle valve from the lock chamber 21 can be shut off.
  • the Pumpenabsperrventil 33 can be designed flushable to flush the valve seat and the valve body, for example in the form of a valve needle, of abrasive (see Figures 19a-b). This ensures on the one hand a tight closing of the Pumpenabsperrventils 33 and reduces the wear of material in the valve.
  • the pump 31 can be largely protected from abrasives by means of an upstream filter and / or separator (both not shown).
  • a first embodiment of the needle valve of Fig. 19a may be used, in which a side scavenging inlet and an opposite lateral Spülauslass is provided.
  • the second embodiment of the needle valve according to FIG. 19b is more advantageous, in which a check valve is provided at the scavenging inlet. Since the pressure release valve 27 is opened at high pressure, the check valve prevents a pressure release in the direction of the scavenging inlet.
  • the Spülauslass can open into the drain 29, so that both the pressure relief and the Spülstoffablass takes place only to the drain 29 out and not to Rinse inlet.
  • the lock chamber 21 has a printing input 35 in a lower region, via which the lock chamber 21 can be printed.
  • the printing input 35 is in the embodiment of FIG. 1 via a pressure relief valve 37 in the form of a needle valve shut off with a pressure accumulator 39 and via throttles 41, 42 connected to the high pressure line 5.
  • the pressure accumulator 39 has two accumulator units in the form of spring accumulators, which are connected in parallel with the inlet of the Betigungsventils 37.
  • the pressure accumulator 39 is connected via the throttle 41 to the high-pressure line 5.
  • the throttles 41, 42 may be configured statically, for example in the form of pinhole diaphragms, or adjustable or controllable. If the throttles 41, 42 can be adjusted to a degree at which the connection between the high-pressure line 5 and the pressure input 35 can be completely shut off, it is possible to dispense with the pressurizing valve 37.
  • the accumulator 39 is fully pressurized before the lock chamber 21 is printed. As soon as the pressurizing valve 37 is opened, the pressure accumulator 39 discharges into the sluice chamber 21 and thus quickly prints it to approximately 40% of the high pressure po, which is provided in the high-pressure line 5 as the nominal high-pressure source 3.
  • the accumulator 39 is immediately loaded again from the moment in which he has discharged pressure.
  • the high-pressure line 5 prints both the lock chamber 21 with the residual pressure and the pressure accumulator 39. This is particularly advantageous if the pressure loading of the accumulator 39 is so time-consuming that the Nach Scholl begangrate of the pressure charging time of the accumulator 39 depends.
  • the pressure accumulator 39 can be shut off with a pressure accumulator valve 43 in the form of a needle valve.
  • the accumulator valve 43 can be shut off in order not to burden the high pressure line 5 during the printing of the lock chamber 21 in addition to the pressure loading of the accumulator 39.
  • Such a load could cause a pressure drop in the high-pressure line 5, which could have a negative influence on the cutting performance at the outlet nozzle 7. It is therefore advantageous to open the pressure accumulator valve 43 only when the lock chamber 21 is completely printed and the pressure valve 37 is closed, so that the pressure accumulator 39 can be pressure-loaded via the throttle 41 from the high-pressure line 5.
  • the filling of the lock chamber 21 and the refilling of the pressure vessel 1 1 can usually take longer than the pressure loading of the accumulator 39.
  • the throttle 41 may be set so that the printing of the accumulator 39 runs as slowly as possible, but still fast enough so that before the next Passage for printing the lock chamber 21 of the pressure accumulator 39 is completely loaded with pressure.
  • the pressure accumulator 39 is entirely dispensed with and the lock chamber 21 is printed exclusively via the throttle 41 from the high-pressure line 5.
  • the high-pressure source 3 can react so quickly to an initial pressure drop, for example via a servo pump control, and can adapt the pump power correspondingly quickly so that it does not even come to a large amplitude of pressure drop.
  • the high-pressure source 3 can be informed of an initial pressure drop, so that the high-pressure source 3 can quickly counteract a further pressure drop with an increase in output or speed increase.
  • the initial pressure drop can already be mitigated, so there is no time to a pressure drop, which significantly affects the cutting performance.
  • the refill valve 19 can be opened, so that gravity-based or -supported abrasive can flow from the lock chamber 21 through the refill valve 19 into the pressure vessel 1 1 to this refill.
  • a conveying aid 45 for example in the form of a pump, is provided, which is connected to the pressure vessel 1 1 in a suction-absorbing manner and to the lock chamber 21 in a pressure-sensitive manner.
  • the conveying aid 45 supports or generates the Abrasivmiftelsfrom from the lock chamber 21 down into the pressure vessel 1 1. It can prevent or dissolve clogging of abrasive particles and accelerate the heavy refilling or assisted refilling process.
  • the conveying aid 45 operates on the pressure vessel 1 1 mif water under the nominal high pressure po. It must therefore be designed for high-pressure operations. For example, as shown in Fig. 6b, it may only have an inductively driven paddle wheel in the high pressure, so that the number of moving parts under high pressure is minimized.
  • a plausible Büab- barrier bensfil 47 is disposed between the conveying aid 45 and the lock chamber 21, wherein the randomly dodgeabsperrvenfilfil 47 in the form of a Nadelvenfils the pump 47 can shut off against the lock chamber 21 when the lock chamber 21 is not or not completely printed.
  • the randomly provedbbsperrvenfil 47 is a flushable needle valve according to FIG. 19b mif a check valve on Spülle- lass, since it is operated under high pressure.
  • FIGS. 6a-c show various alternative embodiments for the conveying aid 45.
  • the conveying aid 45 may, for example, have an impeller driven by a shaft from the outside (see FIG. 6a) or an inductively driven impeller (see FIG. 6b).
  • the conveying aid 45 can also support the refilling of Abrasivmiftel in the pressure vessel 1 1 via a piston stroke (see Fig. 6c).
  • the conveying aid 45 can continuously pump or convey or temporally limited or pulsed. It may possibly be sufficient if the Abrasivmiftelhne is only initially supported in the pressure vessel 1 1 and then continues to run fast enough alone suitskraff- unferstüfzt. Alternatively or in addition the Abrasivstoff Kunststoff Kunststoff Kunststoff Kunststoffe, Alternatively or in addition the Abrasivstoff Kunststoff Kunststoff Kunststoff Kunststoffe, Alternatively or in addition the Abrasivstoff Kunststoff Kunststoff Kunststoff Kunststoffe, Alternatively or in addition the Abrasivstoff Kunststoff Kunststoff Kunststoff Kunststoffe, Alternatively or in addition the Abrasivstoff Kunststoff Kunststoff Kunststoff Kunststoffe, Alternatively
  • the refill valve 19 In addition to an upper valve inlet 49 and a lower valve outlet 51, the refill valve 19 also has a lateral pressure inlet 53. Via the pressure inlet 53, a valve chamber, in which there is a movable valve body, can be printed. Namely, without printing on the valve space, it may be that when the system is started up, the very high pressures on the valve inlet 49 and the valve outlet 51 press the valve body so strongly into the valve seat that the valve body can no longer be moved. Via the lateral pressure inlet 53, a pressure compensation in the refill valve 19 can be made, so that the valve body is movable after commissioning.
  • a purge for the refill valve 19 is provided.
  • a flushing source 55 can be shut-off connected to the pressure inlet 53 (see FIG. 4).
  • three flushing valves 57, 59, 61 are provided to be able to turn on and off the flushing and to separate from the high pressure.
  • a first purge valve 57 in the form of a needle valve is arranged between the conveying aid 45 and the pressure inlet 53.
  • a second flushing valve 59, also referred to herein as Spülauslassventil 59 is arranged in the form of a needle valve between a side Spülauslass 63 and a drain 65.
  • a third purge valve 61 in the form of a needle valve is disposed between the purge source 55 and the pressure inlet 53.
  • the refill valve 19 In order to flush the refill valve 19 with water or a mixture of water and detergent so that a valve space of the refill valve 19 can be freed of abrasive residues, the refill valve 19 is preferably closed.
  • the first flush valve 57 is also if closed, so that pressure can be released from the pressure inlet 53 without relieving the pressure on the conveying aid 45.
  • the second flush valve 59 is opened to the drain 65, so that the possibly existing high pressure can be discharged from the valve chamber.
  • the third flush valve 61 is opened, then water or a water-detergent mixture flows through the valve chamber to the drain 65 and thus rinses it free of Abrasivstoffresten.
  • the rinsing of the refill valve 19 is carried out at completely pressureless system 1 as a service procedure in order to completely rinse the valve chamber and possibly to be able to move the valve body thereby.
  • a flushing inlet 66 can be provided separately from the pressure inlet 53 (see also FIGS. 15a-b and 17a-b).
  • the pressure inlet 53 may be coaxial with and juxtaposed with a servomotor shaft 86, wherein the scavenging inlet 66 and scavenging outlet 63 may be disposed transversely of the servomotor shaft 86 coaxially with one another and on opposite sides, respectively.
  • the flushing is terminated by closing the three flushing valves 57, 59, 61 in the reverse order, that is, the third flushing valve 61 is first closed so that the flushing flow is stopped. Then, the second purge valve 59 is closed to complete the valve space opposite to the drain 65. Finally, the first purge valve 57 can be opened so that the valve space is printed at high pressure.
  • the printing of the valve chamber is advantageous because a valve body in the refill valve 19 can be pressed so strongly into a valve seat by the high pressure difference between the valve outlet 51 or valve inlet 49 and the valve chamber that this can no longer be moved. The printing of the valve space, however, creates a pressure equalization, so that the valve body 19 remains movable in the refill valve.
  • the maximum level cone Fmax is defined by the fact that with further refilling with abrasive in the pressure vessel 1 1, a backflow into the refill valve 19 would result.
  • the minimum level cone Fmin is defined by the fact that the abrasive agent content of the abrasive agent suspension in the output-side abrasive medium line 70 would decrease on further removal of the abrasive agent.
  • level sensors 72, 74, 76 can be arranged on the pressure vessel 11 in order to signal the reaching of a filling cone.
  • the fill level sensors 72, 74, 76 may be, for example, ultrasonic sensors, optical sensors or barriers, electromagnetic sensors or sensors of another type.
  • the level sensors 72, 74, 76 ultrasonic sensors that can signal a reaching a level cone on a change in structure-borne noise.
  • an upper level sensor 72 may signal the reaching of the level cone Fi and start a timer or define a time ti.
  • a lower level sensor 74 may signal the arrival of the level cone F2 and stop a timer at At or define a time T2.
  • a mean Abr- sivstoffentddling raw be determined as AV / At or AV / ( ⁇ 2- ⁇ i).
  • the third lowest level sensor 76 may be the minimum level cone Signal Fmin and immediately cause a shut-off of Absperrvenfils 15 to prevent empty suction of the pressure vessel 1 1.
  • other parameters of the friction such as the pump speed of the high-pressure source 3 for determining the abrasive intake flow and its regulation, can also be used as the control variable for the control film 17. As shown in FIG.
  • the abrasive flow rate or the mixing ratio can also be determined by means of a corresponding sensor 79 on the abrasive mast rifling 70 or in front of the outfeed nozzle 7 and used as a control variable for the control valve 17.
  • the level sensors 72, 74 can also be used to control or clock the refill cycles.
  • a fill of the lock chamber 21 may fit over the upper level sensor 72 between the Corsfandskegel Fi and the maximum Grefandskegel Fmax. If the level cone falls below Fi, the upper level sensor 72 can trigger filling of the lock chamber 21 so that it is completely filled when the lower level sensor 74 signals the Grefandskegel F2 and thus can trigger refilling from the filled lock chamber 21 in the pressure vessel 1 1. This prevents the Corsfandskegel drops to the minimum Artsfandskegel Fmin. Between the minimum level cone Fmin and the Grefandskegel F2 can also fit at least one filling of the lock chamber 21 as a buffer.
  • the lock chamber 21 can automatically be filled again immediately as soon as the refilling of the pressure vessel 1 1 is completed. Then only with the level cone F2 refilling from the lock chamber 21 needs to be triggered.
  • the vertical distance between the upper Drsfandsssensor 72 and the lower Grefandsssensor 74 can be chosen relatively short, for example so short that a decrease between Fi and F2 takes less than a filling process of the lock chamber 21.
  • the average abrasive take-off flow AV / ⁇ ⁇ and AV / ( ⁇ 2- ⁇ i), respectively, can be more frequently determined and thus more accurately reflect the current abrasive take-off flow dV / dt.
  • FIGS. 8 to 12 show various possibilities of adding abrasive agents in dry, wet, moist, suspended, frozen, pelletized or other form into the refilling funnel 25 or directly into the filling valve 23.
  • a precharge container 78 is provided, from which by means of a pump 80 abrasive suspension is conveyed into the refilling funnel 25.
  • a pump 80 Via an overflow 82 at the refilling funnel, water can drain during loading of the refilling funnel 25, which is displaced by the sinking abrasive.
  • a precharge container 78 is provided from which dry pulverulent or moist lumpy abrasive agent is conveyed into the refilling funnel 25 by means of a conveyor screw 84 and / or a conveyor belt 85.
  • water can also run off here during the loading of the refilling funnel, which is displaced by the sinking abrasive.
  • the abrasive can be recovered and processed, for example, after a cutting process from the waste water of the cutting jet 9, so that it can be used for a further cutting process.
  • the advantage of this plant compared to known water abrasive injection cutting machines is that such a recycled abrasive does not have to be dried and can be filled into the plant in wet-lumpy or any form.
  • a feed screw 84 can also be arranged on the input side to the refilling funnel 25 in order to convey abrasive medium into the refilling funnel 25. This is particularly advantageous if no Abrasivstoffsuspension in Vorlade authorer 78, but abrasive as a dry powder or in moist-lumpy form.
  • the refilling of the abrasive in the pressure vessel 1 1 is carried out portioned and cyclically while a workpiece to be machined can be continuously cut with the cutting jet 9 according to an embodiment of the disclosed herein water-abrasive suspension cutting.
  • 13 illustrates the method steps in terms of time.
  • a first step 301 water is provided under high pressure in the high-pressure line 5 by means of the high-pressure source 3.
  • a pressurized abrasive suspension is then provided 303 in the pressure vessel 11.
  • a workpiece by means of the high-pressure jet 9, which at least partially contains the Abrasivstoffsuspension, 305 are cut while removing the Abrasivstoffsuspension from the pressure vessel 1.
  • the steps 307 to 31 1 serve the portioned and cyclic refilling of the pressure vessel 1 1 with abrasive during of the continuous separation 305.
  • the unprinted lock chamber 21 is filled 307 with abrasive or an abrasive suspension.
  • the delivery aid 45 is shut off by the auxiliary conveying stop valve 47 from the unprinted lock chamber 21.
  • the pump 31 is shut off from the lock chamber 21 308.
  • the lock chamber is at least partially printed by pressure discharge of the accumulator 39 309, and finally the pressure vessel 1 1 with abrasive or an abrasive suspension via the refill valve 19 from the printed lock chamber 21 refilled 31 1.
  • the accumulator can be pressure loaded via the throttle 41 from the high pressure line 5 313.
  • the Sluice chamber 21 can be printed 315 from the high pressure line 5 at least partially via the throttle 41. This slow throttled printing 315 from the high pressure line 5 can last longer than the fast printing 309 by the pressure discharge of the pressure accumulator 39.
  • the printing 309 of the lock chamber 21 by pressure discharge of the pressure accumulator can be done so fast that in the lock chamber 21 befindliches abrasive is loosened by a pressure surge.
  • the printing 309 of the lock chamber is effected by pressure discharge of the pressure accumulator 39, preferably in a lower region of the lock chamber 21, since any blockages of abrasive in a lower region are more probable than in an upper region.
  • the printing input 35 of the lock chamber 21 from the pressure accumulator 39 and / or the high-pressure line 5 during filling 307 and refilling 31 1 is shut off.
  • the pressure loading 313 of the pressure accumulator 39 can thus take place during the filling 307 and / or the refilling 31 1.
  • energy can be stored in the pressure accumulator 39 via a spring or fluid compression, which can be designed, for example, as a spring or bladder accumulator.
  • the filling 307, the printing 309 and the refilling 31 1 can run cyclically while the cutting 305 can be carried out continuously.
  • the pressure accumulator 39 after printing 309 of the lock chamber 21 can be shut off by the discharge of the pressure accumulator 39 from the high-pressure line 5 by means of the pressure accumulator valve 43.
  • the pressure accumulator valve 43 may preferably only then be opened again for pressure loading of the pressure accumulator 39 be when the lock chamber 21 has been printed on the throttle 41 from the high pressure line 5.
  • FIG. 14 illustrates an exemplary course of the pressure p over the time t in the lock chamber 21 (top), in the pressure accumulator 39 (in the middle) and in the high-pressure line 5 (below).
  • the pressure in the unprinted lock chamber 21 is initially the ambient pressure, which here lies on the zero line.
  • the lock chamber 21 can be filled 307 in this unprinted phase before the start of printing 309 at time to.
  • the refilling 31 1 can begin and the pressure vessel 39 can be simultaneously reloaded with pressure 313.
  • the lock chamber 21 is completely printed via the throttle 41 over the time window B away from the high-pressure line 5.
  • the refill valve 19 is opened so that abrasive can flow into the pressure vessel 11.
  • the abrasive has completely flowed out of the lock chamber 21 in the pressure vessel 1 1 and the refilling step 31 1 completed.
  • the pressure from the lock chamber 21 can be discharged relatively quickly via the pressure relief valve 27 into the drain 29 until at again low pressure in the lock chamber 21 prevails. Then, a new refill cycle starting with the filling 307 of the lock chamber 21 can start.
  • the accumulator 39 is preferably as slow as possible and throttled from h to pressure from the high pressure line 5 again to be fully loaded at to printing again 309 for to.
  • the lower graph shows the pressure drop in the high-pressure line 5 when opening the Bescherungsventils 37 at to or the accumulator valve 43 at h.
  • the amplitude of the pressure drop is reduced in each case via the throttle 41 to a level at which the cutting performance of the cutting jet 9 is not significantly impaired.
  • FIG. 15a and 15b the refill valve 19 is shown in more detail in cross-section in each case in different open positions. Since the refill valve 19 must be actuated at high pressure on the valve inlet 49 and the valve outlet 51, the trouble-free operation of the refill valve 19 is a technical challenge. The reliable opening and closing of the refill valve 19 is now ensured by four sub-aspects, each of which, either alone or in any combination of two, three, or all four sub-aspects, help to prevent the refill valve 9 from becoming clogged or blocked by the abrasive.
  • the refill valve 19 which is preferably designed as a ball valve, has a vertical flow direction D from top to bottom and has a centrally arranged and about a perpendicular to the flow direction D axis of rotation R rotatable valve body 67 with spherical outer surfaces.
  • the valve body 67 has a central opening 69, which runs parallel to the flow direction D and perpendicular to the axis of rotation R in the open positions shown in FIGS. 15 a and 15b.
  • the first open position according to FIG. 15a differs from the second open position shown in FIG. 15b, characterized in that the valve body 67 is rotated by 180 ° with respect to the axis of rotation R.
  • the valve body 67 is seated in a valve space 71 between an upper valve seat 73 and a lower valve seat 75.
  • the upper valve seat 73 forms the valve inlet 49 and the lower valve seat 75 the valve outlet 51.
  • the upper valve seat 73 and the lower valve seat 75 are arranged coaxially with each other and to the vertical flow direction D.
  • the valve chamber 71 can be purged via the lateral flushing inlet 66 and via the flushing outlet 63 located diametrically opposite the flushing inlet 66, preferably in the case of a completely depressurized refill valve 19.
  • the refill valve 19 is capable of assuming a first closed position (FIG. 16a), a first open position (FIG. 15a), and a second open position (FIG. 15b), in the first closed position (Fig. 16a) the lock chamber 21 from the pressure vessel 1 1 is fluid-separated and in the first and the second open position (Fig. 15a-b), the lock chamber 21 is fluidly connected to the pressure vessel 1 1.
  • the first open position and the second open position are substantially indistinguishable because of the symmetry of the valve body 67.
  • the valve body 67 can be rotated arbitrarily far in one direction about the axis of rotation R, so that a reversal of the direction of rotation is in principle not necessary and the valve body 67 can be actuated exclusively in one direction of rotation, provided that the torque required for this does not exceed a certain threshold.
  • the first closed position of Fig. 1 6a is here at 90 ° between the first open position and the second open position. In this case, there is also a second closed position (see FIG. 16b), which is rotated 180 ° relative to the first closed position about the axis of rotation R.
  • the opening 69 extends in the closed positions shown in FIGS.
  • valve 16a and 16b both perpendicular to the flow direction D and perpendicular to the axis of rotation R, so that the Valve body 67 seals the valve inlet 49 at the upper valve seat 73 and the valve outlet 51 at the lower valve seat 75.
  • the optional rinse inlet 66 and Spülauslass 63 are not shown, but may be provided.
  • valve body 67 can be moved in the other direction of movement and the valve 19 can be brought into the other open position / closed position.
  • the obstruction or blockage can be resolved by the reversal as a positive side effect, so that at the next operation, the previously blocked movement direction is free again.
  • the refill valve 19 can be freed even by repeated back and forth turning, for example, if the valve body 67 is difficult to operate in both directions of movement.
  • the valve space 71 can be printed in a closed position of the valve body 67.
  • the valve chamber 71 has the pressure inlet 53, via which the valve chamber 71 can be printed in a closed position of the valve body 67.
  • the pressure inlet 53 is here in the yz plane coaxially with a servomotor shaft 86 arranged opposite to this.
  • the pressure inlet 53 can also lie in the xz plane perpendicular to it and if necessary be used as flushing inlet 66 as required.
  • the valve body 67 is rotated about the rotation axis R.
  • the valve chamber 71 When commissioning or recommissioning the initially pressureless system 1, the valve chamber 71 is initially depressurized. If the pressure vessel 1 1 and the lock chamber 21 then printed at about 2,000 bar, the valve body 67 can be clamped by the valve seats 73, 75 because of the input-side and output-side high pressure with simultaneous low pressure in the valve chamber 71 and only difficult or impossible to move. By means of the pressure inlet 53, the pressure difference between the valve chamber 71 and the valve inlet 49 and the valve outlet 51 during commissioning can be largely reduced, so that the valve body 67 is not clamped by the high pressure.
  • the upper valve seat 73 is shown adjustable according to the fourth sub-aspect via an adjusting device.
  • the upper valve seat 73 can be positioned via an external thread by means of a rotation about the flow direction D in the z-direction. The rotation can be performed manually or motor driven by attacking from the outside in attack surfaces 77 lever 88.
  • the valve space can be purged as shown, for example, in FIGS. 15a-b.
  • the pressure inlet 53 can optionally serve as flushing inlet 66. This is particularly advantageous in combination with the second sub-aspect of a pressure inlet 53, since a flushing passage can be performed at unpressurized valve chamber 71 or completely pressureless system 1 and then at restart of the system 1, the valve chamber 71 can be re-printed via the pressure inlet 53 so the valve body 67 is not pinched by the high pressure.
  • the refill valve has the input-side upper valve seat 73 and the output-side lower valve seat 75, wherein at least one of the valve seats 73, 75 is adjustable, so that the distance of the valve seats 73, 75 is adjustable to each other.
  • the refill valve 19 can be optimally adjusted to be both tight and on the other hand not to block.
  • a tool opening 90 may be provided through which a tool in the form of a lever 88 can engage to adjust the at least one adjustable valve seat 73.
  • the adjustment of the valve seat 73 is performed in a service procedure at unpressurized system 1.
  • the upper input-side valve seat 73 via an external thread axially along the flow direction D is adjustable.
  • Levers 88 can be attached from the outside to circumferentially arranged engagement surfaces 77 (see Fig. 18b) to rotate the valve seat 73.
  • the refill valve 19 does not need to be disconnected from the system 1 or dismantled. The operator can thus manually intervene immediately to ensure continuous operation, or turn off the system 1 and de-pressure to perform the adjustment of the valve seat 73 as a service procedure.
  • the readjustment can also be controlled automatically and / or controlled by a motor.
  • the valve body 67 is preferably controlled by a servo motor, not shown, rotated about the rotation axis R.
  • a servo motor not shown
  • the possibly measured torque or the power consumption of the engine can be monitored so that when a threshold value is exceeded, the direction of rotation can be changed over to the other open position or closed position.
  • torque or power spikes may be recorded over a period of time and an error or maintenance case signaled based on this record. For example, the need for readjusting the valve seat 73 may be indicated.
  • FIG. 19 a-b show two embodiments of flushable needle valves used, for example, as one or more of the shut-off valves 15, 27, 33, 37, 47 or elsewhere in the plant 1 can be.
  • the needle valve according to FIG. 19 a is preferably used where the needle valve does not have to open or close under high pressure, for example as a pump shut-off valve 33 in the circuit to support the filling of the lock chamber 21.
  • the Pumpenabsperrventil 33 in this case has a high-pressure inlet 92 which is shut off with respect to a high-pressure inlet 92 coaxially disposed and axially positionable needle 94 with respect to a low-pressure outlet 95.
  • the needle 94 has at a high pressure input 92 end facing a conical closing surface 96 which can be pressed against a valve seat 98 to shut off. As soon as the high pressure input 92 is shut off, high pressure can be applied to the high pressure input 92 without it escaping via the low pressure outlet 95. When there is no high pressure at high pressure inlet 92, pump shutoff valve 33 may be opened to allow low pressure flow from high pressure input 92 to low pressure output 95.
  • the needle valve according to FIG. 19a-b also has a rinsing inlet 100, through which the opened needle valve can be flushed through, wherein rinsing liquid, ie water or water with cleaning additives, can flow out via the low-pressure outlet 95.
  • rinsing liquid ie water or water with cleaning additives
  • the valve seat 98 and the closing surface 96 can be freed of abrasive agent residues in order to ensure a clean closing with as little material wear as possible.
  • the needle valve can be flushed just before a closing operation of the refill valve 19.
  • Fig. 19b shows a needle valve with a check valve 102 on the rinse inlet 100.
  • the check valve 102 prevents backflow into the rinse inlet 100 and allows only a flow of rinsing liquid in the direction of the needle valve. This is useful if the needle valve, for example, as one or more of the shut-off valves 15, 27, 37, 47 is used, since there the valve is opened when the high pressure input 92 high pressure prevails. Without the check valve 102, this high pressure would at least partially discharge into the rinsing inlet 100 and lead to a return flow into the rinsing inlet 100. This prevents the check valve 102 and thus enables a clean pressure relief via the low-pressure outlet 95.
  • the low-pressure outlet 95 can also be a high-pressure outlet 95 in this case.
  • the low-pressure outlet 95 is connected to a drain 29.
  • the high-pressure outlet 95 is connected to the pressure input 35 of the lock chamber 21 in order to pressurize it with high pressure.
  • the needle valves are pneumatically operated via a Anpressteller (not shown).
  • Anpressteller (not shown).
  • an air pressure can be applied to the much larger pressure plate so that the needle valve can be closed with a few bar air pressure and kept tight against a high pressure of 1, 500 bar and more ,

Landscapes

  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Perforating, Stamping-Out Or Severing By Means Other Than Cutting (AREA)
  • Finish Polishing, Edge Sharpening, And Grinding By Specific Grinding Devices (AREA)
  • Mechanical Treatment Of Semiconductor (AREA)
  • Processing Of Stones Or Stones Resemblance Materials (AREA)

Abstract

L'invention concerne une installation de découpe par jet d'eau chargée d'abrasif en suspension (1) qui présente une source haute pression (3) destinée à fournir (301) de l'eau sous haute pression, une conduite haute pression (5) reliée à la source haute pression (3), ainsi qu'un réservoir sous pression (11) destiné à fournir (303) une suspension d'agent abrasif (13) sous haute pression. Le réservoir sous pression (11) est en communication fluidique avec la conduite haute pression (5) par l'intermédiaire d'un étranglement (17) réglable, cet étranglement (17) étant situé côté entrée du réservoir sous pression (11) et étant conçu pour réguler l'afflux dans le réservoir sous pression (11) depuis la conduite haute pression (5) en fonction d'au moins une grandeur de régulation.
EP17716813.5A 2017-03-31 2017-03-31 Installation et procédé de découpe par jet d'eau chargée d'abrasif en suspension Active EP3600765B1 (fr)

Priority Applications (1)

Application Number Priority Date Filing Date Title
PL17716813.5T PL3600765T3 (pl) 2017-03-31 2017-03-31 Instalacja do cięcia strugą zawiesiny wodno-ściernej i sposób cięcia strugą zawiesiny wodno-ściernej

Applications Claiming Priority (1)

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PCT/EP2017/057786 WO2018177559A1 (fr) 2017-03-31 2017-03-31 Installation et procédé de découpe par jet d'eau chargée d'abrasif en suspension

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EP3600765A1 true EP3600765A1 (fr) 2020-02-05
EP3600765B1 EP3600765B1 (fr) 2022-06-08

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US (1) US11511392B2 (fr)
EP (1) EP3600765B1 (fr)
JP (1) JP7050806B2 (fr)
KR (1) KR102450780B1 (fr)
CN (1) CN110709209B (fr)
AU (1) AU2017407669A1 (fr)
BR (1) BR112019019435A2 (fr)
CA (1) CA3058494C (fr)
MX (1) MX2019011565A (fr)
PL (1) PL3600765T3 (fr)
WO (1) WO2018177559A1 (fr)

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Publication number Publication date
US20210107113A1 (en) 2021-04-15
WO2018177559A1 (fr) 2018-10-04
KR102450780B1 (ko) 2022-10-04
BR112019019435A2 (pt) 2020-04-14
CN110709209B (zh) 2022-07-19
CA3058494A1 (fr) 2018-10-04
CN110709209A (zh) 2020-01-17
AU2017407669A1 (en) 2019-10-17
CA3058494C (fr) 2024-02-13
JP2020515421A (ja) 2020-05-28
PL3600765T3 (pl) 2022-11-14
KR20190135513A (ko) 2019-12-06
JP7050806B2 (ja) 2022-04-08
MX2019011565A (es) 2019-11-18
EP3600765B1 (fr) 2022-06-08
US11511392B2 (en) 2022-11-29

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