ATOMIZER UNIT

Abstract

The invention relates to an atomizer unit of a minimal quantity lubricant system (2) for a cooling and/or lubricating function of a cutting-machining process. The atomizer unit (3) has a chamber assembly (8) with an injection chamber (9) and an atomizer chamber (10), wherein the injection chamber (9) is connected to the atomizer chamber (10) by a nozzle (11), and the atomizer unit (3) has at least one first feed channel (12) for feeding a first compressed air flow (13) into the injection chamber (9), at least one second feed channel (14) for feeding a second compressed air flow (15) into the atomizer chamber (10), and an injection valve (16) for injecting a coolant and/or lubricant (4) into the first compressed air flow (13) in the injection region (17) of the injection chamber (9). The atomizer unit (3) is designed such that the first compressed air flow (13) flows from the injection chamber (9) into the atomizer chamber (10) through the nozzle (11), is atomized in the atomizer chamber by the nozzle (11), is combined with the second compressed air flow (15) in the atomizer chamber (10) in order to form a transport flow (18) for transporting the injected coolant and/or lubricant (4), and can be conducted to the machining location (7). The atomizer unit (3) has a heater (20) which heats the coolant and/or lubricant (4), the first compressed air flow (13), the second compressed air flow (15), and/or the transport flow (18).

Description

The invention relates to an atomizer unit of a minimal quantity lubrication system for cooling and/or lubricating a subtractive machining process between a tool and a workpiece at a machining location according to claim 1, to a minimal quantity lubrication system according to claim 10, to a machining system according to claim 12, and to a method for operating an atomizer unit and/or a minimal quantity lubrication system and/or a machining system according to claim 15.

In many subtractive machining processes it is advantageous for cooling and/or lubricating to be provided at the machining location between the tool and the workpiece. The process reliability can in most instances be significantly enhanced as a result of such cooling and/or lubricating. The machining quality and the service life of the tool can be increased, and the thermal input into the workpiece can be reduced. At the same time however, the costs for the respective coolant and/or lubricant are also to be kept low, and any unnecessary release of coolant and/or lubricant into the environment is to be avoided. Post machining, cleaning of the workpiece by removing coolant and/or lubricant is ideally also to be avoided. As the size of the workpiece increases, the complexity associated with cleaning significantly increases in particular when said workpiece is only partially machined at many locations. This applies in particular to structural aircraft components in which a plurality of workpiece parts are connected to one another by drilling and riveting. Therefore, so-called minimal quantity lubrication systems have been developed in order for the quantity of coolant and/or lubricant used in the subtractive machining process to be reduced.

Minimal quantity lubrication systems for machining in which the aerosol is generated in a large container and from the latter is guided to the machining location by way of a line are known in principle. These systems are sluggish. The quality of the aerosol, in particular the concentration of the aerosol and the quantity of aerosol to be fed, here can only be slowly varied and cannot be dynamically controlled.

DE 20 2009 017 656 U1 proposes a minimal quantity lubrication system which already permits somewhat more dynamic controlling, in this minimal quantity lubrication system, the coolant and/or lubricant is sprayed into a chamber by way of a high-pressure nozzle and transported to the machining location by means of a compressed air fiow. This system can be configured as a single-duct minimal quantity lubrication system in which the aerosol is generated outside the spindle of a machining system and by means of single-duct routing is guided through the spindle and the tool to the machining location. Alternatively, the system can be configured as a dual-duct minimal quantity lubrication system in which the aerosol is generated within the spindle and the spindle is fed compressed air and the coolant and/or lubricant by means of a separate line.

Nevertheless, there is demand for further optimization in terms of the homogeneity of the aerosol to be produced, the improvement of the response time, and the adjustability of the aerosol quality. This applies in particular to machining systems in which the generation of aerosol in the spindle of said machining system is not possible due to the lack of installation space.

Therefore, the present invention is based on the object of improving the homogeneity, the response time, and the adaptation to changing conditions and the quantity of the coolant and/or lubricant to be used, in particular in the case of small spindles.

The object mentioned above in an atomizer unit of a minimal quantity lubrication system is achieved by the features of claim 1.

The atomizer unit according to the proposal of a minimal quantity lubrication system for cooling and/or lubricating a subtractive machining process between a tool and a workpiece at a machining location has a chamber assembly having an injection chamber and having an atomizer chamber. The injection chamber is connected to the atomizer chamber by a nozzle. The atomizer unit has at least one first infeed duct for feeding a first compressed air flow into the injection chamber, and at least one second infeed duct for feeding a second compressed air flow into the atomizer chamber. Furthermore, the atomizer unit has an injector valve for injecting a coolant and/or lubricant into the first compressed air flow in the injection region of the injection chamber. Said atomizer unit is designed in such a manner that the first compressed air flow, optionally conjointly with the injected coolant and/or lubricant, from the injection chamber flows through the nozzle into the atomizer chamber and therein is atomized by the nozzle. The first compressed air flow, optionally conjointly with the injected coolant and/or lubricant, is united with the second compressed air flow in the atomizer chamber so as to form a transport flow for transporting the injected coolant and/or lubricant. The transport flow can then be directed to the machining location by way of a transmission duct.

The injection of the coolant and/or lubricant into a first compressed air flow, and the flow of the first compressed air flow conjointly with the optionally injected coolant and/or lubricant through the nozzle, and the unification with the second compressed air flow enables a particularly homogenous distribution and low concentration of the coolant and/or lubricant in the transport flow, and in this way a particularly precise and uniform, flexibly adjustable infeed of coolant and/or lubricant to the machining location. A particularly high quality of the aerosol generated by the atomizer unit is achieved. The aerosol quality is moreover further stabilized as a result of the heating being provided.

Therefore, the atomizer unit according to the proposal has a heating which heats the coolant and/or lubricant and/or the first compressed air flow and/or the second compressed air flow and/or the transport flow.

A heated coolant and/or lubricant can be better atomized and thus ensures a further enhanced aerosol quality. Moreover, the reliance of the aerosol quality on environmental influences such as, for example, the ambient temperature, is also reduced. As a result, a high aerosol quality can be achieved even at variable environmental conditions Moreover, the atomizer unit according to the proposal is also very compact and can therefore be easily integrated in the machining system.

According to claim 2, the coolant and/or lubricant is in particular heated prior to the injection from the injector valve into the first compressed air flow. This is now possible by way of a particularly minor input of energy, because only a very minor quantity of coolant and/or lubricant in comparison to the quantity of compressed air is fed to the atomizer unit per unit of time.

According to the preferred refinement as per claim 3, the injector valve is received in an, in particular multiple-part, block. Additionally, the heating and/or a temperature sensor can be disposed in this block. As a result a particularly positive and uniform transmission of heat to the coolant and/or lubricant can be guaranteed.

A structurally simple and efficient construction is derived when the block forms at least part of the injection chamber, and/or forms at least part of the atomizer chamber, and/or the nozzle is mounted in the block.

In order to enable a very high level of responsiveness, in particular also in terms of adjusting or modifying the cooling/lubricating parameters, the injection chamber and/or the atomizer chamber are/is preferably configured as in claim 5.

A minor spacing of the nozzle from the injector valve also enables a high aerosol quality and a flexible adjustment of the aerosol (claim 6).

The nozzle is preferably configured as described in claim 7. A particularly homogenous aerosol is generated as a result.

According to claim 8, the injector valve is a high-pressure injector valve, in particular a gasoline direct-injector valve. This enables a very precise actuation and, correspondingly, a flexible adjustment of the aerosol quality.

In a configuration according to claim 9, particularly flexible and responsive metering can be achieved with a high level of homogeneity.

Moreover, the object outlined at the outset in a minimal quantity lubrication system is achieved by the features of claim 10.

The minimal quantity lubrication system here may have all features described in the context of the atomizer unit individually or in combination. The same advantages as described in the context of the atomizer unit are derived.

The refinement according to claim 11 relates to preferred operating parameters of the minimal quantity lubrication system. In this range, the minimal quantity lubrication system can be particularly efficiently operated for smaller bores.

Moreover, the object described at the outset in a machining system is achieved by the features of claim 12.

The machining system here preferably has the features described in the context of the atomizer unit and/or the minimal quantity system individually and/or in combination. The same advantages as described in the context of the atomizer unit and the minimal quantity lubrication system are derived.

Preferred design embodiments of the machining system are described in claims 13 and 14.

Finally, the object discussed at the outset in terms of a method is achieved by the features of claim 15.

The same advantages as described above in the context of the atomizer unit, the minimal quantity lubrication system and/or the machining system are derived.

An atomizer unit and/or a minimal quantity lubrication system and/or a machining system as described herein can be used in the method.

The invention will be explained in more detail hereunder by means of a drawing illustrating merely an exemplary embodiment, in the drawing

FIG. 1 shows a schematic illustration of a machining system according to the proposal, having an atomizer unit according to the proposal of a minimal quantity lubrication system according to the proposal;

FIG. 2 in a schematic illustration shows an exemplary embodiment of a minimal quantity lubrication system according to the proposal, having the atomizer unit according to the proposal from FIG. 1 in a three-dimensional external view;

FIG. 3 shows an exploded drawing of the atomizer unit from FIG. 2;

FIG. 4 shows a section through the atomizer unit of the exemplary embodiment according to the view IV-IV from FIG. 2, and an enlarged detailed view of the section; and

FIG. 5 shows a three-dimensional illustration of the atomizer unit, and a section according to the view A-A.

FIG. 1 schematically shows a machining system 1 according to the proposal, having a minimal quantity lubrication system 2 according to the proposal which has an atomizer unit 3 according to the proposal.

Reference is made to the not yet published German patent applications DE 10 2008 111 082.0 and DE 10 2008 111 083.9, reference being made thereto in terms of the further design embodiment and the content of said patent applications being incorporated in this application by reference.

The functional mode of the atomizer unit 3 is to be explained by means of FIG. 4 which shows the atomizer unit in the section according to IV-IV of FIG. 2.

The atomizer unit 3 serves for providing the coolant and/or lubricant 4 for cooling and/or lubricating a subtractive machining process between a tool 5 and a workpiece 6 at a machining location 7.

The tool 5 can in particular be a subtractive tool, presently and preferably a drill bit. The workpiece 6 presently and preferably is a structural component, in particular a structural aircraft component. Structural aircraft components are for example fuselage sections and/or wing sections of an aircraft. The workpiece 6 can be composed of a plurality of workpiece parts 6a, 6b. The latter are conjointly drilled here and subsequently riveted to one another. The workpiece parts 6a, 6b can be configured from a material, and/or as a composite and/or as a hybrid component. A workpiece part can in particular be a metal/fiber composite component which is formed from a plurality of tiers, in particular metal tiers and fibrous tiers. By virtue of the high degree of adjustment flexibility of the invention, the latter can generate an added value specifically in the case of these components.

The atomizer unit 3 according to the proposal has a chamber assembly 8 having an injection chamber 9 and having an atomizer chamber 10, the injection chamber 9 being connected to the atomizer chamber 10 by a nozzle 11. Furthermore, the atomizer unit 3 has at least one first infeed duct 12 for feeding a first compressed air flow 13 into the injection chamber 9, and at least one second infeed duct 14 for feeding a second compressed air flow 15 into the atomizer chamber 10. The atomizer unit 3 according to the proposal also has an injector valve 16 for injecting a coolant and/or lubricant 4 into the first compressed air flow 13 in the injection region 17 of the injection chamber 9. As is shown in FIG. 4, the atomizer unit 3 here is designed in such a manner that the first compressed air flow 13, optionally conjointly with the injected coolant and/or lubricant 4. from the injection chamber 9 flows through the nozzle 11 into the atomizer chamber 10 and therein is atomized by the nozzle 11. An aerosol is formed as a result.

An aerosol is understood to be a colloid system composed of gas, presently the compressed air, having small solid and/or liquid particles (suspended substances, presently the coolant and/or lubricant) distributed therein. Presently and preferably, these are liquid particles. The particles preferably have diameters from 10⁻⁷ to 10⁻³ cm. The coolant and/or lubricant 4 in the exemplary embodiment and preferably has a kinematic viscosity of 9×10⁻⁶ m³ per second.

The first compressed air flow 13, optionally conjointly with the injected coolant and/or lubricant 4, in the atomizer chamber 10 unifies with the second compressed air flow 15 so as to form a transport flow 18 for transporting the injected coolant and/or lubricant 4. The transport flow 18 in the exemplary embodiment is directed from the atomizer chamber 10 to the machining location 7 by way of a transmission duct 19. At said machining location 7, the transmission duct 19 directly adjoins the atomizer chamber. The transmission duct presently and preferably is distinguished in that the latter is releasable from the atomizer chamber. The transmission duct can in particular be a flexible hose.

The injection of the coolant and/or lubricant 4 into the first compressed air flow 13, and the later adding of a second compressed air flow 15, provided downstream, after the atomization by the nozzle 11 enables a homogenous distribution of the coolant and/or lubricant 4 at a low concentration in the transport flow 18. An aerosol composed of compressed air and coolant and/or lubricant 4 is produced. Furthermore, this constructive design of the atomizer unit 1 enables short response times for activating and deactivating the aerosol for the subtractive machining process. This is particularly advantageous in the case of short subtractive machining processes such as. for example, when drilling, in particular thin multi-layer workpieces 6 or workpiece parts 6a, 6b.

The fact that the atomizer unit 3 according to the proposal has a heating 20 which heats the coolant and/or lubricant 4 and/or the first compressed air flow 13 and/or the second compressed air flow 16 and/or the transport flow 18, in particular prior to exiting the atomizer chamber 10 and/or prior to entering the transmission duct 19. leads to the aerosol being further stabilized. Environmental influences on the aerosol quality, such as temperature variations in the proximity of the machining system 1, can in particular be reduced. As a result, an even more stable, flexible and highly responsive supply of the machining location 7 with coolant and/or lubricant 4 is achieved.

The heating 20 particularly preferably heats the coolant and/or lubricant 4 prior to injection from the injector valve 16 into the first compressed air flow 13 and/or prior to, in particular immediately prior to, entering the injector valve 16, as is also implemented in the exemplary embodiment.

As is shown in FIGS. 2 and 3, the injector valve 16 is received in an, in particular multiple-part. block 21, in particular metal block. The block 21 is preferably made of steel, in particular stainless steel, and/or aluminum. The heating 20 heats the block 21 and the latter heats the coolant and/or lubricant 4. The injector valve 16 in the exemplary embodiment is received in the block 21 across the entire length of said injector valve 16. The coolant and/or lubricant 4 is preferably also heated in the injector valve 16.

In addition to the injector valve 16. the heating 20 and/or a temperature sensor 22 are/is presently and preferably disposed in the block 21. Furthermore, as is shown in FIG. 3, a temperature limit switch 23 which switches off the heating 20 when a predetermined temperature, preferably 90° C., furthermore preferably 80° C., is exceeded can be provided. The heating 20 is preferably configured as a heating element.

The block 21 in the exemplary embodiment is configured in three parts. However, said block 21 can also be configured in only two parts, for example. The injector valve 16 is at least partially received in a part 21a, 21b, 21c of the multiple-part block 21 (presently in the first block part 21a). The heating 20 and/or the temperature sensor 22 are/is preferably received in the same part of the multiple-part block 21 (presently in the first block part 21a). This is shown in FIG. 3.

In the exemplary embodiment the numbering of the block parts 21a, 21b, 21c ascends in the flow direction. Even when the heating 20 presently is received only in one block part, said heating preferably heats the entire block 21. The block parts in the assembled state here all are in direct contact. Said block parts are preferably made from the same material.

The temperature sensor 22 presently and preferably serves for open-loop control and/or closed-loop control of the heating 20. The heating 20 is preferably operated in such a manner that said heating 20 controls by closed-loop the block 21 to a substantially constant temperature and/or a temperature curve. The block 21 presently and preferably is adjusted to an, in particular substantially constant, temperature between 20° C. and 80° C. furthermore preferably between 30° C. and 70° C., furthermore preferably between 40° C. and 60° C., in the exemplary embodiment 50° C. A particularly efficient thermal transmission to the coolant and/or lubricant 4 is enabled as a result.

The heating 20 is preferably also adjusted as a function of the viscosity of the coolant and/or lubricant 4 used. For example, in the case of a coolant and/or lubricant 4 having a higher viscosity, the block 21 can be controlled by open-loop or closed-loop to a higher temperature than in the case of a coolant and/or lubricant 4 having a lower viscosity.

Furthermore, the temperature limit switch 23 presently and preferably is disposed on the same part of the block 21. As is shown in FIG. 5, said temperature limit switch 23 in the exemplary embodiment is disposed on the rear side of the atomizer unit 3.

The atomizer unit 3 furthermore has a cover 24 as a heat shield, the latter preferably being disposed so as to be spaced apart from the block 21. As a result, the block 21 more readily maintains its temperature, on the one hand, and any inadvertent contact with the warm block 21 which could lead to burns is prevented, on the other hand.

As can furthermore be derived from FIG. 3, a second part of the block 21 (second block part 21b) in the exemplary embodiment also partially receives the injector valve 16. The nozzle 11 is preferably also received in the block 21 and/or configured by the latter. The nozzle 11 in the exemplary embodiment is mounted in the block 21, presently in the second part of the block 21.

It is thus presently and preferably the case that the block 21 forms at least part of the injection chamber 9 and/or at least part of the atomizer chamber 10, as is shown in FIG. 4. In the exemplary embodiment the injection chamber 9 is formed by the injector valve 16 and the second block part 21b. Said injection chamber 9 is formed by receiving the outlet end 16a of the injector valve 16 in the second block part 21b. The injection chamber 9 preferably has a volume of at most 10,000 mm³, furthermore preferably of at most 1,000 mm³, furthermore preferably of at most 500 mm³, in the exemplary embodiment of 250 mm³.

The atomizer chamber 10 is formed by the second and the third block part 21b, 21c, and optionally by the nozzle 11. This is shown in FIG. 4. The atomizer chamber 10 is preferably larger than the injection chamber 9 by a factor of 2 to 5. The atomizer chamber 10 preferably has a volume of at most 20,000 mm³, furthermore preferably of at most 5,000 mm³, furthermore preferably of at most 1,000 mm³, and in the exemplary embodiment of 750 mm³.

The nozzle 11 is preferably spaced apart from the injector valve 16, in particular the outlet end 16a of the injector valve 16, by at most 10 cm, preferably at most 5 cm, furthermore preferably at most 3 cm. furthermore preferably at most 1.5 cm. This is shown in FIG. 4.

It can likewise be derived from FIG. 4 that the first compressed air flow 13 in the exemplary embodiment flows into the atomizer unit 3 by way of a plurality of, presently two, first infeed sub-ducts 12a. The latter, presently and preferably opposite one another, lead onward into the block 21, presently the second block part 21b. The first infeed sub-ducts 12a presently and preferably in the atomizer unit 3, presently in the block 21 (second block part 2c), are unified so as to form a first overall infeed duct 12b. The infeed of the first compressed air flow 13 to the injection chamber 9 presently takes place in a radially encircling manner about the injector valve 16 or the outlet end 16a of the injector valve 16. At least one directional component of the first compressed air flow 13 when entering the injection chamber 9 preferably runs in the primary injection direction of the coolant and/or lubricant 4. The first compressed air flow 13, immediately prior to entering the injection chamber 9, presently and preferably runs substantially parallel to the primary injection direction of the coolant and/or lubricant 4. The primary injection direction in the exemplary embodiment is directed along the central axis Me of the injector valve 16.

The first compressed air flow 13, optionally conjointly with the injected coolant and/or lubricant 4, from the injection chamber 9 flows through the nozzle 11 into the atomizer chamber 10. In the atomizer chamber 10 the coolant and/or lubricant 4 by the nozzle 11 is atomized into the second compressed air flow 14, as is shown in FIG. 4. Said nozzle 11 is disposed downstream of the injection chamber 9. In principle, the coolant and/or lubricant 4 can already be atomized when being injected into the injection chamber 9. Said coolant and/or lubricant 4 presently and preferably is, however, at least further atomized in the atomizer chamber 10. In this way, a homogenous aerosol for cooling and/or lubricating the machining process can be generated.

The injected coolant and/or lubricant 4 by the first compressed air flow 13 is forced through the passage opening 11a of the nozzle 11. The first compressed air flow 13 thus conveys the injected coolant and/or lubricant 4 through the nozzle 11 and in this way atomizes said coolant and/or lubricant 4 in the atomizer chamber 10.

The passage opening 11a presently and preferably is configured so as to be substantially round. In principle however, said passage opening 11a may have another geometry. The maximum passage opening width of said passage opening 11a presently and preferably is at most 0.6 mm, preferably at most 0.3 mm, furthermore preferably at most 0.2 mm.

As is shown in FIG. 4, the second compressed air flow 16 in the exemplary embodiment flows into the atomizer unit 3 by way of a plurality of, presently two, second infeed sub-ducts 14a. The latter, presently and preferably opposite one another, lead onward into the block 21. presently the third block part 21c. The first infeed sub-ducts 12a presently and preferably in the atomizer unit 3, in particular in the block 21 (third block part 2c), are unified so as to form a second overall infeed duct 14b. The infeed to the atomizer chamber 10 presently takes place in a radially encircling manner about the nozzle 22. At least one directional component of the first compressed air flow 13 when entering the atomizer chamber 10 preferably runs in the longitudinal direction of the passage opening 11a. The second compressed air flow 15, immediately prior to entering the atomizer chamber 10, presently runs substantially parallel to the longitudinal direction of the passage opening 11a. In the case of an established transport flow, the volumetric flow of the second compressed air flow 15 presently and preferably is larger than the volumetric flow of the first compressed air flow 13. Furthermore preferably, the volumetric flow of the second compressed air flow 15 is larger than the volumetric flow of the first compressed air flow 13 at least by a factor of 2, furthermore preferably at least by a factor of 5 larger than the volumetric flow of the first compressed air flow 13, furthermore preferably at least by a factor of 10 larger than foe volumetric flow of the first compressed air flow 13.

The atomizer unit 3 has a connector 25 for the supply line of the coolant and/or lubricant 4. Said connector 25 presently and preferably is provided on the block 21. The coolant and/or lubricant 4 is guided from this connector 25 to the injector valve 16. The coolant and/or lubricant 4 on the way from the connector 25 to the injector valve 16 in the exemplary embodiment and preferably is in direct contact with the block 21. As a result, a particularly positive thermal input from the heating 20 into the coolant and/or lubricant 4 is guaranteed. The coolant and/or lubricant 4 can also be further heated in the injector valve 16. The block 21 which absorbs the heat of the heating 20 disposed in said block 21 passes this heat onward to the injector valve 16, and the latter passes said heat onward to trie coolant and/or lubricant 4.

The injector valve 16 presently and preferably is a high-pressure injector valve, in particular a gasoline direct-injector valve. The latter is known from the automotive sector and has proven to be reliable. The injector valve 16 Is electrically actuatable. Said injector valve 16 presently and preferably is supplied with a voltage of 48 V. In order to be actuated and/or supplied with voltage, said injector valve 16 has an electrical connector 25. The latter is able to be connected to a control assembly 34. In order for the injector valve 16 to be opened and/or dosed, the latter presently and preferably has a solenoid and/or a piezo actuator. A dosing pin 16d for opening and/or closing the injector valve 16 is moved by means of said solenoid and/or piezo actuator.

The outlet end of the injector valve 16 is configured on the end of an elongate portion 16b. The latter is presently and preferably cylindrical. For the purpose of transmitting heat, in particular from the block 21, to the coolant and/or lubricant 4, the elongate portion 16b presently and preferably is at least partially, in particular completely, configured from metal.

The electrical connector 16c of the injector valve 16 presently and preferably protrudes from the block 21, as is shown in FIG. 2 and/or FIG. 5. Said electrical connector 16c presently protrudes from an opening 21d of the first block part 21a.

It is thus furthermore presently ard preferably the case that the injector valve 16 is actuated in a pulsed manner. The opening duration of the injector valve 16 here is preferably provided so as to be shorter than the duration between two opening actions of the injector valve 16.

It can in particular be provided that different pulse frequencies can be set for different coolant and/or lubricants 4. The duration between two opening actions of the injector valve 16 is preferably adjusted, in particular as a function of the viscosity of the coolant and/or lubricant 4. The opening duration of the injector valve 16 during one pulse preferably remains constant here.

In order for the coolant and/or lubricant to be injected, the injector valve 16 is preferably actuated by way of an actuation frequency of 5 to 100 Hz, preferably 10 to 60 Hz. presently 35 Hz. The opening duration of the injector valve is preferably less than 10 ms. furthermore preferably less than 2 ms, furthermore preferably less than 1 ms. furthermore preferably less than 0.5 ms. furthermore preferably less than 0.4 ms, and in the exemplary embodiment 0.37 ms.

In the exemplary embodiment and preferably, this results in an injection quantity of 29 g of coolant and/or lubricant in the transport air flow per hour.

For switching and/or controlling in a closed loop the first and/or second compressed air flow 13, 15, the minimal quantity lubrication system 2, in particular the atomizer unit 3, has a compressed air valve assembly 35. The compressed air valve assembly presently has a switch valve 35a for switching the first compressed air flow 13 and/or a switch valve 35b for switching the second compressed air flow 15. The two compressed air flows 13, 15 can be switched in a mutually separate manner. The compressed air valve assembly 35 is preferably fastened to the cover 24.

FIG. 2 shows the minimal quantity lubrication system 2 according to the proposal. The latter in the exemplary embodiment has the previously described atomizer unit 3. The minimal quantity lubrication system 2 presently and preferably is suitable and/or specified to consume in total equal to or less than 50 ml of coolant and/or lubricant per hour during the subtractive machining process. Presently and preferably, at most 50 ml. furthermore preferably at most 40 ml, furthermore preferably at most 30 ml, of coolant and/or lubricant are consumed per hour during the subtractive machining process.

Provided is a coolant and/or lubricant source 26 for supplying the injector valve with coolant and/or lubricant 4. The coolant and/or lubricant 4 presently and preferably is liquid. Said coolant and/or lubricant 4 presently and preferably is provided by the coolant and/or lubricant source 26 at a pressure of 50 to 250 bar, preferably of 80 to 220 bar, furthermore preferably of 100 to 200 bar, furthermore preferably of 130 to 170 bar, presently of 150 bar. Pressures this high enable a positive distribution of the coolant and/or lubricant 4 already when being injected into the injection chamber 8.

The minimal quantity lubrication system 2 furthermore has a compressed air source assembly 27 for supplying the first and/or the second infeed duct 13,15 with compressed air. A single compressed air source for supplying both infeed ducts 13, 15 with compressed air is preferably provided. Alternatively however, the compressed air source assembly 27 can also be configured by two separate compressed air sources and a first compressed air source supplies the first infeed duct 12 with compressed air and a second compressed air source supplies the second infeed duct 14 with compressed air. The compressed air is preferably generated from ambient air.

In the exemplary embodiment the minimal quantity lubrication system 2 has one compressed air source which provides the compressed air for the first compressed air flow 13 and the second compressed air flow 14. For example, a booster 28 can be provided here in the supply line to the first compressed air flow 13. said booster 28 increasing the pressure of the first compressed air flow 13 by way of post-compression. It is thus particularly preferably the case that the first infeed duct 12 is provided with compressed air at a higher pressure than the second infeed duct 14. The pressure differential in the provision of pressure presently and preferably is 2 to 8 bar. Furthermore preferably, said pressure differential is 4 to 6 bar, furthermore preferably essentially 5 bar. In the case of an established transport flow 18, the first infeed duct 12 is preferably provided with compressed air at a pressure of 3 to 8 bar, furthermore preferably 4 to 7 bar, in the exemplary embodiment of 6 bar, and/or in the case of an established transport flow 18 the second infeed duct 14 is provided with compressed air at a pressure of 8 to 15 bar, furthermore preferably 9 to 13 bar. presently 11 bar. The pressure of the first compressed air flow 13 and of the second compressed air flow 15 can preferably be adjusted separately from one another.

The machining system 1 according to the proposal, as is shown in FIG. 1, has a tool 5 and a minimal quantity lubrication system 2 having an atomizer unit 3. The machining system 1 has a spindle 29 having a tool receptacle 30 for receiving the tool 5. The machining system 1 here has an end effector 31 in which the spindle 29 is disposed. The compressed air source assembly 27 and/or the coolant and/or lubricant source 26 here is presently and preferably disposed so as to be spaced apart from the end effector 31. The atomizer unit 3 in turn is preferably disposed on the end effector 31.

The machining system 1 preferably is a drill, presently a drilling/riveting machine. The tool 5 in the exemplary embodiment is a drill bit. The spindle 29 presently and preferably is a component part of a drilling unit 32 of the end effector 31. The end effector 31 can additionally have a riveting unit 33 for placing rivet elements in a bore drilled by the drilling unit 32.

Moreover, the machining system 1 has a control assembly 34 for controlling the machining system 1 and the minimal quantity lubrication system 2, and thus the subtractive machining process. The control assembly 34 presently and preferably has a machining system controller 34a and optionally a minimal quantity lubrication system controller 34b. The machining system controller 34a is preferably a PLC controller. The latter controls the subtractive machining process. The minimal quantity lubrication system controller 34b presently and preferably receives from the machining system controller 34a parameters for controlling the minimal quantity lubrication system 2. The minimal quantity lubrication system 2, in particular the atomizer unit 3 of the minimal quantity lubrication system 2. is controlled as a function of these parameters. This takes place in particular by adding the coolant and/or lubricant 4 by means of the injector valve 16, as well as by way of switching the transport flow 18 and/or the temperature adjustment of the heating 20.

As is shown in FIG. 1, the atomizer unit 3 presently and preferably is disposed outside the spindle 29. This is necessary in particular in the case of small and compact spindles 29. A disposal of the atomizer unit 3 in the spindle 29 here is specifically not possible in most instances due to the lack of installation space. The transmission duct 19 presently runs from the atomizer unit 3 through the spindle 29 and through the tool 5 to the machining location 7.

The atomizer unit 3 in the flow direction of the transport flow 18 is disposed ahead of the spindle 29. The flow path from the atomizer unit 3 to the spindle 29 is preferably less than 50 cm, furthermore preferably less than 20 cm, furthermore preferably less than 10 cm. The closer the atomizer unit 3 is to the spindle 29, the shorter the latency periods for activating and/or deactivating the aerosol can be achieved.

It is thus preferably the case that the spindle axis S intersects the injector valve 16 and/or the nozzle 11. Furthermore preferably, the spindle axis S is disposed so as to be coaxial with the central axis M_E of the injector valve 16 and/or with the central axis M_D of the nozzle 11. This enables the aerosol to be particularly positively guided in the transmission duct 19 Alternatively, the spindle axis S and the central axis M_E and/or the central axis M_D can also be disposed so as not to be coaxial. In this instance, said axes are preferably configured so as to be mutually parallel, or the intersection point thereof is preferably disposed so as to be spaced apart from the atomizer unit 3 by at most 20 cm. furthermore preferably at most 10 cm.

Additionally or alternatively, an atomizer unit 3a from which a transmission duct 19a is routed to the machining location 7 so as to bypass the tool can be provided, as is shown in FIG. 1. This additional or alternative atomizer unit 3a is preferably configured as described. In the case of two atomizer units 3, 3a, both are preferably supplied by means of the same compressed air source assembly 27 and/or coolant and/or lubricant source 26. Presently, both are controlled by the same control assembly 34, the two atomizer units 3, 3a being able to be controlled in an open loop and/or closed loop by separate minimal quantity lubrication system controllers or by the same minimal quantity lubrication system controller 34b.

The subtractive machining process is to be described in more detail hereunder. It is particularly preferable for the transport flow 18 to be established before or during a subtractive machining process, and for the coolant and/or lubricant 4 to be added in the established transport flow so as to, conjointly with the transport flow 18, form an aerosol.

The aerosol in this instance can be transported in a particularly simple manner by the transport flow 18 to the machining location 7. Establishing the transport flow 18 prior to injecting the coolant and/or lubricant 4 enables the addition of the coolant and/or lubricant 4 and the transport of the latter to the machining location 7 to be very precisely controlled and thus the cooling and/or lubricating at the machining location 7 to be very precisely controlled. As a result, minor quantities of coolant and/or lubricant 4 can be used exactly at the points in time at which the coolant and/or lubricant 4 are/is actually required or advantageous. In the exemplary embodiment, the coolant and/or lubricant 4 is added only once a constant transport flow 18 has been established, thus when the transport flow 18 has been configured so as to be quasi-stationary. This enables the period of time after which the aerosol upon actuation of the injector valve 16 for injecting the coolant and/or lubricant 4 exits the at least one exit opening of the toot 5 to be very precisely determined. It is particularly preferable for the coolant and/or lubricant 4 to be added to the transport flow 18 in such a manner that the aerosol exits the at least one exit opening only once at least one exit opening of the tool 5 is submerged, in particular completely submerged, in the workpiece 6.

The minimal quantity lubrication system 2 can preferably be adjusted and/or provided with parameters, in particular by an operator, for a workpiece 6 and/or a workpiece part 6a, 6b. in particular for each position of the workpiece 6 and/or of a workpiece part 6a/6b, in the subtractive machining process. As a result, the cooling and/or lubrication can be adapted for different positions, in particular each position, of the workpiece 6 or the workpiece part 6a, 6b. Adjusting and/or providing parameters presently and preferably takes place prior to the start of the subtractive machining process.

The pressure of the transport flow 18, in particular the pressure of the first compressed air flow 13 and/or of the second compressed air flow 15, and the quantity of coolant and/or lubricant used, is preferably adjustable and/or able to be provided with parameters, in particular by the operator. Adjusting and/or providing parameters presently and preferably takes place prior to the start of the subtractive machining process. The pressure of the second compressed air flow 15 is presently and preferably provided with parameters by the operator, on the one hand, and the control assembly 34, in particular the minimal quantity lubrication system controller 34b, adjusts the first and the second compressed air flow 13, 15 based on the parameters provided for the second compressed air flow 15. Additionally or alternatively, the operator can provide parameters for the quantity of coolant and/or lubricant. The control assembly 34, in particular the minimal quantity lubrication system controller 34b, presently and preferably adjusts the pressure of the coolant and/or lubricant 4 and/or the actuation of the injector valve 16 based on the parameters provided for the quantity of coolant and/or lubricant. The adjustment of the actuation of the injector valve 16 presently and preferably takes place by determining the actuation frequency and/or the opening duration and/or a transient which describes a flutter status of the injector valve 16. This can preferably be adjusted by the operator. The control assembly 34 preferably provides different opening durations of the injector valve 16 as a function of the viscosity of the currently used coolant and/or lubricant 4.

In the subtractive machining process for a first tier of the workpiece the cooling and/or lubrication can in particular be adjusted differently from a second tier of the workpiece 6. Additionally or alternatively, the adding of coolant and/or lubricant 4 can be deactivated for individual tiers of the workpiece 6, in particular when said tiers are made of a fiber-composite material, in particular of a carbon-fiber-reinforced plastic (CFRP).

At the end of the subtractive machining process, in particular once a hole has been drilled, the first compressed air flow 13 and the second compressed air flow 15 are preferably activated when the tool 5 is being retracted from the workpiece 6, without coolant and/or lubricant 4 being injected. This preferably takes place for at least 150 ms, furthermore preferably at least 200 ms, furthermore preferably at least 250 ms. As a result, the surface of the workpiece 6 can be cleaned when the tool 5 is being extracted, and/or remnants of coolant and/or lubricant 4 can be blown cut of the transmission duct 19 and/or of the atomizer unit 3.

The machining system 1, in particular the minimal quantity lubrication system 2, here can monitor the flow of aerosol and/or the concentration of aerosol. Furthermore, said machining system 1, or said minimal quantity lubrication system 2, based on this monitoring can intervene so as to control the subtractive machining process in a closed loop and/or open loop, in particular in that said machining system 1, or said minimal quantity lubrication system 2, adapts parameter settings of the minimal quantity lubrication system 3.

The monitoring can take place directly and/or indirectly. For example, the monitoring can take place indirectly by monitoring the consumption of coolant and/or lubricant and/or the first compressed air flow 13 and/or the second compressed air flow 15.

The monitoring can take place diractly, for example, by means of a sensor, in particular a laser sensor, in the transmission duct 19.

Claims

1. An atomizer unit of a minimal quantity lubrication system (2) for cooling and/or lubricating a subtractive machining process between a tool (5) and a workpiece (6) at a machining location (7), the atomizer unit (3) having a chamber assembly (8) having an injection chamber (9) and having an atomizer chamber (10), the injection chamber (9) being connected to the atomizer chamber (10) by a nozzle (11),the atomizer unit (3) having at least one first infeed duct (12) for feeding a first compressed air flow (13) into the injection chamber (9), and at least one second infeed duct (14) for feeding a second compressed air flow (15) into the atomizer chamber (10),the atomizer unit (3) having an injector valve (16) for injecting a coolant and/or lubricant (4) into the first compressed air flow (13) in the injection region (17) of the injection chamber (9),the atomizer unit (3) being designed in such a manner that the first compressed air flow (13), optionally conjointly with the injected coolant and/or lubricant (4), from the injection chamber (9) flows through the nozzle (11) into the atomizer chamber (10) and therein is atomized by the nozzle (11),the first compressed air flow (13), optionally conjointly with the injected coolant and/or lubricant (4), being unified with the second compressed air flow (15) in the atomizer chamber (10) so as to form a transport flow (18) for transporting the injected coolant and/or lubricant (4) and being directable to the machining location (7),the atomizer unit (3) having a heating (20) which heats the coolant and/or lubricant (4) and/or the first compressed air flow (13) and/or the second compressed air flow (15) and/or the transport flow (18).

2. The atomizer unit as claimed in claim 1, characterized in that the heating (20) heats the coolant and/or lubricant (4) prior to being injected from the injector valve (16) into the first compressed airflow (13).

3. The atomizer unit as claimed in claim 1 or 2, characterized in that the injector valve (16) is received in an, in particular multiple-part, block (21), in particular metal block, preferably in that additionally the heating (20) and/or a temperature sensor (22) are/is disposed in the block (21), furthermore preferably in that the heating (20) heats the block (21) and the latter heats the coolant and/or lubricant (4).

4. The atomizer unit as claimed in one of the preceding claims, characterized in that the block (21) forms at least part of the injection chamber (9), and/or forms at least part of the atomizer chamber (10), and/or the nozzle (11) is mounted in the block (21).

5. The atomizer unit as claimed in one of the preceding claims, characterized in that the injection chamber (9) has a volume of at most 10,000 mm3, furthermore preferably of at most 100 mm3, furthermore preferably of at most 500 mm3, furthermore preferably of 250 mm3, and/orin that the atomizer chamber (13) has a volume of at most 20,000 mm3, furthermore preferably of at most 5000 mm3, furthermore preferably of at most 1000 mm3, furthermore preferably of 750 mm3.

6. The atomizer unit as claimed in one of the preceding claims, characterized in that the nozzle (11) is disposed so as to be spaced apart from the injector valve (16), in particular the outlet end (16a) of the injector valve (16), by at most 10 cm, preferably at most 5 cm, furthermore preferably at most 3 cm, furthermore preferably at most 1.5 cm.

7. The atomizer unit as claimed in one of the preceding claims, characterized in that the passage opening width of the passage opening (11a) of the nozzle (11) is at most 0.5 mm, preferably at most 0.3 mm, furthermore preferably at most 0.2 mm.

8. The atomizer unit as claimed in one of the preceding claims, characterized in that the injector valve (16) is a high-pressure injector valve, in particular a gasoline direct-injector valve.

9. The atomizer unit as claimed in one of the preceding claims, characterized in that the injector valve (16) is actuated in a pulsed manner, preferably in that the opening duration of the injector valve (16) is shorter than the duration between two opening actions of the injector valve (16).

10. A minimal quantity lubrication system having an atomizer unit as claimed in one of the preceding claims, having a coolant and/or lubricant source (26) for supplying the injector valve (16) with coolant and/or lubricant (4), and having a compressed air source assembly (27) for supplying the first and/or second infeed duct (13, 15) with compressed air.

11. The minimal quantity lubrication system as claimed in claim 10, characterized in that the coolant aid/or lubricant (4) is provided by the coolant and/or lubricant source (26) at a pressure of 50 to 250 bar, preferably of 80 to 220 bar, furthermore preferably of 100 to 200 bar, furthermore preferably of 130 to 170 bar, furthermore preferably of 150 bar, and/orin that compressed air in the case of an established transport flow (18) is provided to the first infeed duct (12) at a pressure of 3 to 8 bar, preferably of 4 to 7 bar, furthermore preferably of 5 bar,and/orin that compressed air in the case of an established transport flow (18) is provided to the second infeed duct (14) at a pressure of 8 to 15 bar, preferably of 9 to 13 bar, furthermore preferably of 11 bar.

12. A machining system for the subtractive machining of a workpiece (6), the machining system (1) having a tool (5) and an atomizer unit (3) as claimed in one of claims 1 to 9, and/or a minimal quantity lubrication system (2) as claimed in claim 10 or 11.

13. The machining system as claimed in claim 12, characterized in that the machining system (1) has a spindle (29) having a tool receptacle (30), and in that the transmission duct (19) from the atomizer unit (3) to the machining location (7) runs, in particular in a rectilinear manner, through the spindle (29) and the tool (6).

14. The machining system as claimed in claim 12 or 13, characterized in that the machining system (1) is a drill, in particular a drilling/riveting machine, and in that the tool (6) is a drill bit.

15. A method for operating an atomizer unit (3), in particular as claimed in one of claims 1 to 9, and/or a minimal quantity lubrication system (2), in particular as claimed in claim 10 or 11, and/or a machining system (1), in particular as claimed in one of claims 12 to 14, the atomizer unit (3) having a chamber assembly (8) having an injection chamber (9) and having an atomizer chamber (10), the injection chamber (9) being connected to the atomizer chamber (10) by a nozzle (11).the atomizer unit (3) having at least one first infeed duct (12) for feeding a first compressed air flow (13) into the injection chamber (9), and at least one second infeed duct (14) for feeding a second compressed air flow (15) into the atomizer chamber (10),the atomizer unit (3) having an injector valve (9) for injecting a coolant and/or lubricant (4) into the first compressed air flow (13) in the injection region (17) of the injection chamber (9),the first compressed air flow (13), optionally conjointly with the injected coolant and/or lubricant (4), from the injection chamber (9) flowing through the nozzle (11) into the atomizer chamber (10) and therein being atomized by the nozzle (11),the first compressed air flow (13), optionally conjointly with the injected coolant and/or lubricant (4), being unified with the second compressed air flow (15) in the atomizer chamber so as to form a transport flow (18) for transporting the injected coolant and/or lubricant (4), and the transport flow (18) being guided through a transmission duct (19) to a machining location (7),the atomizer unit (3) having a heating (20) which heats the coolant and/or lubricant (4) and/or the first compressed air flow (13) and/or the second compressed air flow (15) and/or the transport flow (18) prior to entering the transmission duct (19).