A field of the invention is machining of metals and metal alloys. The invention provides an atomization-based system and method for creating and applying a thin film of cutting fluid that can be used for cooling and lubrication in machining. An example application of the invention is titanium alloy machining.
Hard to machine materials, such as titanium and its alloys, produce localized extreme temperatures during machining. This limits cutting efficiency and also quickly wears out expensive tools. Short tool life leads to frequent interruptions in manufacturing, high maintenance costs, and sometimes damage to an expensive workpiece being machined. Damage to a workpiece increases manufacturing defect rates and raises expense overall.
Titanium alloys are often used to produce complex and critical parts used, for example, in aircraft and medical implants. Additional example applications include aerospace structures and engines, rockets, spacecraft, turbines, automotive engine components, nuclear and chemical plants, petrochemical industries, offshore engineering, food processing, and biomedical devices. The alloys possess high strength-to-weight ratio, high-temperature strength, strong fracture and corrosion resistance, and biocompatibility.
Titanium alloys are very difficult to machine, however, and tool life is poor in systems that machine titanium. Titanium has poor thermal conductivity and low elongation-to-break ratio. Titanium is also chemically reactive with typical tool materials at a cutting temperature of 500° C. and above. As a result, highly-localized temperatures are developed at the tool-chip interface. Severe edge chipping and plastic deformation via galling and seizure of chips are often produced. This ultimately shortens tool life, can be detrimental to surface finish, and can cause parts to fail quality requirements.
Various efforts have been made to address these problems in machining titanium. One technique is known as flood cooling. See, e.g., Nandy, A. K., et al., “Some studies on high-pressure cooling in turning of Ti-6Al-4V,” International Journal of Machine Tools and Manufacture, 49: 182-198 (2009); Cheng, C., et al., “Treatment of spent metalworking fluids,” Water Research, 39: 4051-4063 (2005). The flood techniques are used in practice, despite relatively ineffectiveness and also unfriendliness to the environment due to large quantities of toxic fluids used for cooling/lubrication.
High pressure cooling technique applies coolant at 70-160 bar or more directly at the tool/workpiece interface. A three to four-folds tool life increase compared to flood cooling has been reported by some. See, e.g., Nandy & Paul, “Effect of coolant pressure, nozzle diameter, impingement angle, and spot distance in high pressure cooling with neat oil in turning Ti-6Al-4V,” Machining Science and Technology, 12: 445-473 (2008); Palanisamy, S., et al., “Effects of coolant pressure on chip formation while turning Ti6Al4V alloy,” International Journal of Machine Tools and Manufacture, 49: 739-743 (2009). In practice however, overall productivity improvements have been reported to be about 50%. The lower productivity improvement is attributable to a higher consumption rate of the cutting fluid, its delivery cost at such high pressure, and the system setup cost. Pusavec, F., et al., “Transition to sustainable production-Part I: application on machining technologies,” Journal of Cleaner Production, 18: 174-184 (2010).
Another difficult to implement process is cryogenic cooling. While offering improved tool life, this is an energy-intensive process that requires liquid nitrogen (LN2) to be delivered at high rates in the range of about 45-250 L/hr. Hong, S. Y., et al., “New cooling approach and tool life improvement in cryogenic machining of titanium alloy Ti-6Al-4V,” International Journal of Machine Tools and Manufacture, 41: 2245-2260 (2001). The liquid nitrogen delivery also poses safety risks to operators and other personnel.
With a goal of environmental friendliness, others have used supercritical CO2 (scCO2) as a solvent to dissolve cutting fluid. Clarens et al., “Evaluation of cooling potential and tool life in turning using metalworking fluids delivered in supercritical carbon dioxide,” Proc. of the ASME International Manufacturing Science and Engineering Conference (MSEC), October 4-7, West Lafayette, Ind., USA (2009). In this method, CO2 gas is provided at levels substantially above its critical pressure, 72.8 bar. Tool wear rates realized during micro-machining were approximately equal to those of conventional flood emulsion systems. In experiments described in this paper, scCO2 spray was provided at 130 bar. These high pressures required a heavy and sophisticated system layout. The costs are prohibitive for such a system, given the lack in improvement over the flood techniques. Also, high pressures pose safety risks to operators and the other personnel. Finally, only low cutting speeds of ˜45 m/min and depth of cut (0.27 mm) was reported, which would not be well-suited for macro-machining applications.
Efforts by some of the present inventors and colleagues have focused on atomized spray application of cutting fluids, and have proven to be successful in micro-machining applications. Micro-machining of AISI 1018 steel with atomized cutting fluid droplets was demonstrated in Jun, Joshi, DeVor, and Kapoor, “An experimental evaluation of an atomization-based cutting fluid application system for micromachining,” ASME Transactions—Journal of Manufacturing Science and Engineering, 130: 0311181-8 (2008). This system was limited to a flow rate of about 1 mL/min, which is ill-suited toward macro-machining applications in general, and also toward the more difficult materials, such as titanium alloys. Macro-machining applications require machining at or above about 1 mm depth of cut and 0.1 mm/rev or higher feed rate. This larger cutting zone creates faster evaporation rates and, in the disclosed set-up, a small amount of cutting fluid can even evaporate prior to reaching the tool-workpiece interface.
Typical commercial nozzle units used in minimum quantity lubrication (MQL) systems employ a high-velocity gas to produce fluid droplets with shear mechanism. The size of fluid droplets varies in a wide range in such systems. The fluid flow rate in these systems is typically limited at ˜2-3 mL/min, a level that is insufficient for providing cooling and lubrication effect during machining at the macro-scale.
Machining of difficult materials, especially of materials having properties like titanium alloys, and especially at the macro-machining level, remains inefficient and expensive. Tools are replaced often and machine surfaces can exhibit defects. Defects can compromise part integrity and can cause a high part rejection rate, leading to additional expense.
An embodiment of the invention provides an atomizing cutting fluid system. The system includes a common chamber terminating in a shaped droplet nozzle and including a nozzle section immediately behind the shaped droplet nozzle. An atomizer creates spray directly within the common chamber behind the nozzle section. A cutting fluid supply line provides cutting fluid to the atomizer. A high velocity gas nozzle within the nozzle section and behind the droplet nozzle is configured to provide a high velocity gas to entrain the flow of droplets. The nozzle section and droplet nozzle are configured to produce a fully developed droplets-gas co-flow at a predetermined distance from the nozzle section. In a cutting system, the spray system provides a uniform film for a micro or macro cutting operation at sufficient flow rates.
The present inventors have determined that a limiting factor of flow rates in previous ACF spray systems for micro-machining is the delivery of atomized fluid droplets from outside of the chamber, typically by a long pipe into the machine chamber. This limits the flow rate to about 1-2 mL/min from the outside of the machine chamber to the inside. See, e.g., Jun, M. B. G. et al., “An experimental evaluation of an atomization-based cutting fluid application system for micromachining,” ASME Transactions, Journal of Manufacturing Science and Engineering, 130: 0311181-8 (2008). Others have also studied ACF for micro machining. See, e.g., Rukosuyev, M. et al., “Understanding the effects of system parameters of an ultrasonic cutting fluid application system for micromachining,” Journal of Manufacturing Processes 12/2: 92-98 (2010). One problem that the present inventors have recognized is that it is difficult or impossible to deliver droplets from outside at higher fluid rates, e.g., 10-20 mL/min that are required for macro-scale machining due to droplet-droplet and droplet-wall interactions.
Reduced film thickness and faster droplet spreading with increasing jet pressure has been investigated in the context of lubrication of internal combustion engines. See, e.g., Stanton & Rutland, “Multi-dimensional modeling of thin liquid films and spray-wall interactions resulting from impinging sprays,” International Journal of Heat Mass Transfer, 41: 3037-3054 (1998). Others have studied lubrication and confirmed that lubrication will be effective when there is a stationary surface and a moving surface with a film in between. See, Langlois, W. E., “A Wedge-Flow Approach to Lubrication Theory,” Quarterly of Applied Mathematics 23:39-45 (1965).
After a certain level of jet pressure, higher incident velocity is induced and will result in droplets splashing instead of effectively spreading upon impingement. See, Yarin & Weiss, D. A., “Impact of drops on solid surfaces: self-similar capillary waves, and splashing as a new type of kinematic discontinuity,” Journal of Fluid Mechanics, 283: 141-173 (1995). The impingement angle with respect to the base surface (i.e. tool rake) defines the regime for sticking the droplets, otherwise, partial rebound or split deposition will take place. Chen & Wang, “Effects of tangential speed on low-normal-speed liquid impact on a non-wettable solid surface,” Experiments in Fluids 39: 754-760 (1995). The droplet loses its initial kinetic energy or momentum after impingement with increase in impingement angle resulting in a weak film pressure. Jayaratne & Mason, B. J., “The coalescence and bouncing of water drops at an air/water interface,” In Proc. of the Royal Society of London. Series A, Mathematical and Physical Sciences, 280: 545-565 (1964). Others have recognized that the spray distance controls the diffusive nature of the spray over the travel distance. Rukosuyev, et al. “Understanding the effects of system parameters of an ultrasonic cutting fluid application system for micromachining,” Journal of Manufacturing Processes 12/2: 92-98 (2010).
The present inventors have also recognized other limitating factors of prior micro-machining efforts. Limiting factors include heat created during machining, which results from shearing of the metal by the cutting edge on the primary shear plane, and from friction at the tool-chip interaction. Effective penetration of the cutting fluid in the cutting zone is essential for longer tool life. In micro-machining, the wetting and penetration of the cutting zone by the fluid droplets is easier because the machining parameters, e.g., depth of cut and feed rate are comparable to the droplet size (e.g. 10-50 μm) produced from the atomizer. Macro-machining has a tool-chip contact area that is much larger than droplet size, which renders the atomization-based cutting fluid spray techniques used in micromaching ill-suited for achieving penetration. Achieving effective penetration of a spreaded fluid film throughout the cutting region is important in order to provide both cooling and lubrication effects. These effects are closely related to the resulting film thickness, its pressure (i.e. lift force) between the tool and the chip, and its cooling coefficient and tribological effect.
Embodiments of the invention include systems and methods for producing a thin film of an atomization-based cutting fluid spray that can provide cooling and lubrication between a workpiece and a cutting tool during machining. Systems and methods of the invention create a thin film of micro-scale fluid droplets and direct that film to the cutting zone to improve cutting dynamics and cooling. Methods and systems of the invention are safer than high pressure and cryogenic techniques, as preferred systems of the invention can use a gravity supply for a fluid tank. Spray is created with a small amount of fluid that is delivered efficiently as a thin film.
Preferred embodiment methods and systems of the invention are also environmentally friendly. CO2 is used in preferred systems for its excellent cooling processes, while the systems of the invention avoid the need to provide high pressures. Systems of the invention mix CO2 with air in specific ratios and a mixing flow that is optimized. Pressure demands are reduced compared to prior systems that are disfavored for their use of pure CO2. Other inert gases with similar molecular weights, and particularly molecular weights above that of O2 (molecular weight 32) can be used. Argon (˜40) is another option. An additional benefit of CO2 is that it is inexpensive. Its recycling into preferred processes of the invention also provides an environmental benefit.
A preferred system of the invention includes an ultrasonic-based atomizer and a gravity-fed cutting fluid reservoir with a delivery tube. A nozzle section includes high-pressure gas delivery nozzle/tube at the nozzle-spray unit. The nozzle is configured to produce an axisymmetric co-flow jet produced of a high-velocity gas and micro-scale fluid droplets. A flow evolution downstream position pattern is created to deliver a thin film at a tool-workpiece interface. Mixing tubes mix air and CO2 in a common flow to produce a temperature that avoids formation of ice from water mixed in the concentrated cutting fluid. Delivery tubes are sized to maintain the same pressure for the different feeds.
Preferred systems of the invention can rely upon a gravity feed, which avoids many safety hazards and design difficulties associated with high pressure systems. No pump is required to deliver cutting fluid. Gravity feed of cutting fluid is possible, because preferred systems of the invention utilize a very small amount of cutting fluid, e.g., up to 0.167 L/min, as compared to conventional flood coolant, e.g., 1 L/min or above, during machining at the macro-scale. With cutting fluid usage that can be a tenth or less of the fluid used by flood systems, similar or better tool life and performance is achieved.
As the high-velocity gas, the present system utilizes significant amount of CO2 from pressurized cylinder along with air. CO2 helps to reduce the dispensing temperature as well as suppressing smoke from the cutting zone. Smoke from burning cutting fluid is usually seen during machining with air alone or N2 gas. Any inert gas alone or mixed with air could be applied for reducing the dispensing temperature of the spray. However, the molecular weight or molar mass plays a vital role in diminishing smoke from the cutting zone that is produced due to burning of cutting fluid. For example, N2 (molecular weight 28) was tested and produces undesirable smoke. With its higher molecular weight than that of O2 (32), CO2 (44) helps in diminishing the smoke by forming a blanket around the burning fluid and also by displacing the oxygen surrounding the fluid. For this reason, other high molecular weight inert gases, e.g. Ar (˜40), can also be used.
A preferred system of the invention includes an ultrasonic atomizer controlled by a generator. The exit delivery portion of the atomizer should be with the common chamber, however. The atomizer is within a common chamber immediately proximate and behind a nozzle section of the chamber. Cutting fluid is provided to the atomizer from a gravity feed tank. If required, low velocity air inlets may be used to help flow from behind the point where the cutting fluid is introduced. The atomizer creates droplets in a volume contained by a nozzle chamber. High-velocity gas is introduced from mixing unit that mixes air and CO2 to entrain the droplets in an entrainment zone at the outlet of the nozzle. Surrounding fluid droplets are entrained by a high-velocity center gas jet at the droplet nozzle outlet. The high-velocity center gas jet nozzle is co-axial with the chamber and the droplet nozzle.
In preferred embodiments, droplet velocity and gas velocity are set to produce a droplet-gas co-flow with a core that focuses and produces a thin film at a predetermined, and preferably optimized, distance from the nozzle when contacting a workpiece-tool interface. A preferred example embodiment suitable for macro-machining of titanium alloys is configured to produce a combination of a 1.2 m/s droplet velocity and 26 m/s gas velocity (at 35 mm distance from the gas nozzle) with a droplet spray behavior in terms of droplet entrainment angle and droplet density across the jet flare that provides a thin film. The fully-developed region (i.e., self-similarity state) of the co-flow is at about 26 mm spray distance from the nozzle or above for the present gas nozzle exit diameter of 1.6 mm. This configuration has been demonstrated to produce a uniform thin fluid film for penetrating at the cutting interface. In preferred embodiments, dimensions and spray parameters are set to achieve a droplet entrainment angle in the range of 20-30°.
A preferred example embodiment nozzle for the system includes a convergence of 4° for the droplet nozzle, which ensures atomized droplets can be entrained with the high-velocity gas. For the preferred example, a convergence angle of 0.75° and exit diameter of 1.6 mm for the gas nozzle were determined to develop the droplet-gas co-flow in self-similarity state before the spray impinges at the cutting zone within a feasible spray distance range (e.g., 25-40 mm) during machining. Operated with a combination of 1.2 m/s droplet velocity and 26 m/s gas velocity (at 35 mm distance from the gas nozzle), this produced a fully-developed region (i.e., self-similarity state) of the co-flow at and after 26 mm spray/downstream distance when the exit diameters of the gas nozzle and the droplet nozzle are set 1.6 and 18.8 mm, respectively. This provides a ratio of the downstream distance to the gas nozzle exit diameter at 16 or above. Preferred embodiments of the invention will now be discussed with respect to the drawings. The drawings may include schematic representations, which will be understood by artisans in view of the general knowledge in the art and the description that follows. Features may be exaggerated in the drawings for emphasis, and features may not be to scale.
Referring now to
In each of the systems of
In preferred embodiments, the high-velocity gas includes a substantial amount of CO2, but in a low enough ratio to avoid formation of ice at the outlet. In preferred embodiments the mixture achieves a spray temperature of about 2° C. This temperature is selected to be slightly above the freezing point (0° C.) of water to avoid freezing. A range of ˜1-4° C. is preferred to avoid freezing while maintaining a desirable cooling effect. High-velocity gas is introduced from mixing unit that mixes air and CO2 to entrain the droplets in an entrainment zone at the outlet of the nozzle and produce the resultant jet spray.
The micro-size fluid droplets in the resultant jet spray are focused at a predetermined distance that permits direction of the spray at a workpiece-tool interface to create a uniform thin film. Rather than relying upon an excess of fluid (i.e., flooding), the thin film is efficiently delivered and penetrates the interface to cool and lubricate the work zone and tool.
Upon impingement, the spray-surface interaction results in one of the four regimes: sticking, rebounding, spreading, and splashing, which can be determined based on the non-dimensional Weber number, We(=ρuo2do/σ), and a non-dimensional group, Ky(=uo(ρ/σ)1/4(ρ/μ)1/8f−3/8, where, do is the droplet diameter, uo is the normal component of the droplet velocity, ρ is the liquid density, σ is the liquid surface tension, μ is the liquid dynamic viscosity, and f is the frequency of the droplets impact. The spreading regime (We≧10 and Ky≦17) is desired for effective wetting of the cutting zone, as has been recognized by others, but others have typically relied upon flooding in an effort to provide effective wetting. The
In experimental device the following were fixed dimensions: droplet nozzle: 4°±0.50 with 18.8±1 mm exit dia. Gas nozzle: 0.75±0.1° with 1.6±0.1 mm exit dia. Droplet nozzle convergence was preferred so that the droplets tend to move toward the entrainment zone. In such case, the center gas can effectively entrain the droplets. Without convergence, the droplets in the boundary diffuse with atmospheric air immediately after exiting from the droplet nozzle as the high-velocity gas cannot effectively entrain the droplets that are comparatively at a larger radial distance. Artisans can adjust the fixed dimensions for particular applications, and particularly, to adjust the distance from the nozzle where a thin film is optimally created. Generally, the exit diameter of droplet nozzle should be small enough to avoid interaction with the rotating workpiece and/or stationary tool when the spray unit is set with certain spray conditions such as impingement angle, spray distance. The droplet nozzle should be large enough to avoid droplet interaction between themselves and with the inner wall surface of the nozzle. The length of the nozzle section (section 16 in
Dimension relationships in
The effect of dimensions is explained qualitatively, to provide guidance to produce particular designs. The following parameters can be used by artisans to produce optimal designs for particular applications.
a: Length of enclosure 18, which connects the nozzle unit with the atomizer. Atomized droplets created from the tip should have a room to spread, otherwise the droplets would directly hit/interact the backside of the gas nozzle 32. The spray pattern of the atomizer is also preferably configured to spread the atomized droplets around the high speed gas nozzle to avoid such contact.
b and c: They have a relationship as determined by the convergence of the gas nozzle. Length ‘c’ should be selected so that the high-velocity gas nozzle is assembled within 16. Once ‘c’ is selected, ‘b’ can be found by the convergence angle as suggested.
d: It is droplet nozzle exit dia plus the wall thickness of the nozzle. Wall thickness should be at least 1 mm. A thicker wall, however, will increase the size of the unit footprint, which may interact the rotating workpiece and/or the stationary tool for certain spray conditions used during machining.
e: Its dimension varies due to the assembly of the droplet nozzle and gas nozzle. If ‘c’ is selected very small, ‘e’ should be small for flexibility in assembly.
Experiments and Experimental Systems
Additional features and advantages of the embodiments discussed above will be apparent to artisans with reference to experiments and experimental devices that were constructed and tested, as will additional features and embodiments.
An ultrasonic-based atomizer (Model VC5040AT from Sonic and Materials, Inc., CT) that vibrates at 40 kHz, was used in experiments to produce uniform fluid droplet size of about 50 μm at the maximum flow rate of 10 L/hr (i.e. 166.67 mL/min). The atomizer was tightly placed inside a plastic transparent cover. The generator for the atomizer was located outside the machine chamber for easy turn on/off. The cutting fluid reservoir was placed on top of the machine cover (outside the machine) so that the fluid can flow due to gravity. A fluid reservoir of 4-5 gallon size can be used to machine for 16-32 hours at a flow rate of 10-20 mL/min. A plastic tube was used to deliver the cutting fluid from the reservoir to the atomizer tip. Another four small plastic tubes were integrated with the cover behind the atomizer tip for supplying the low-velocity air that assist in pushing the droplets through the nozzle unit.
The spray unit was placed inside the machine chamber (e.g. attached with the lathe turret). The nozzle spray unit was placed in front of the atomizer tip at a distance about 30 mm and tightened inside the other end of the plastic cover.
Machining Experiments
The inventors have determined that the wetting of the entire tool-chip contact zone directly depends on the fluid flow rate. The inventors have also determined that type of the droplet carrier gas can play a significant role in reducing the temperature of the cutting zone, and preferred embodiments use air and CO2 to reduce the cutting zone temperature.
In the Experiments, a Mori Seiki Frontier L-1 CNC lathe was used for turning experiments. The experimental arrangement is pictured in
A cylindrical Ti-6Al-4V bar of size 0175 mm×350 mm was used for turning. Triangular type uncoated microcrystalline carbide inserts ISO grade K313 from Kennametal (TPGN220408) was used as tool material. The tool geometry was set as follows: 50 rake angle, 110 clearance angle, 60° major cutting edge angle, 0.8 mm nose radius. The tool was placed with a standard Kennametal shank, which was then secured with a Kistler 3-component force dynamometer (type 9121) to capture the cutting force data at a sampling frequency of 1 kHz through a National Instrument data acquisition system (SCB-68) integrated with the LabVIEW software. Water-soluble cutting fluid S-1001 at 10% dilution was used as coolant. The thermo-physical properties of water and 10% S-1001 are presented in Table 1. Cutting fluid with higher viscosity and lower surface tension was found to be preferable for better lubricity.
A 25-1 fractional factorial design was employed in conducting experiments. Table 2 lists the factor levels chosen for investigating the effect of five ACF spray parameters, i.e., fluid flow rate, spray distance, impingement angle, type of mist carrier gas and its pressure. The range of the fluid flow rate 10-20 mL/min and the pressure level 150-300 psi were selected to induce the spreading regime (We≧10 and Ky≦17) on the rake face. The velocity of the mist carrier gas, vg in the gas nozzle was estimated to be about 26 m/s at 150 psi and 36 m/s at 300 psi when measured with an anemometer at 35 mm spray distance. Table 3 shows that spreading regime upon droplets impingement on the rake face will occur under these conditions according to the nondimensional number We and group Ky. The Ky values were calculated considering 50% effective flow rate because the fluid droplets were observed to be condensed about 50% during the experiment due to their interactions with the outside of the gas nozzle. The air velocity in the mist nozzle was kept fixed at 1.2 m/s. The spot distance was set fixed at about 8 mm in all the tests.
During machining with conventional flood condition, coolant was directed on the rake using a standard delivery system at the flow rate and the pressure of about 1000 mL/min and 60 psi, respectively. The cutting conditions were selected to be 80 m/min cutting speed, 0.2 mm/rev feed rate, and 1 mm depth of cut.
For all the cutting conditions, the tools were removed from the setup first at 4 min and then at 6 min to observe the progress of wear. The tool thereafter was checked every one minute until the maximum flank wear land reached 0.6 mm according to the ISO standard. The maximum tool flank wear was measured using a Quadra-Check 300 optical microscope. The produced bulk chips were photographed by a digital camera and images were analyzed.
Tests were conducted using the ACF spray system for the conditions listed in Table 2. Table 4 lists the results of cutting forces, tool life, and friction co-efficient at the tool-chip interface. The friction coefficient is calculated from the relationship between the tangential and the feed force components for orthogonal cutting. Out of 16 tests in the factorial design, 4 sets of the ACF spray conditions offer tool life of up to 10-11 min. For the same cutting conditions under flood cooling (test No. 17), the average tool life for two tests was found to be about 7 min indicating that, with the ACF spray system, the tool life can be improved up to 40-50% over flood cooling.
An analysis of the tool life data in Table 4 was done to determine the significant effects of the five ACF spray system parameters. It revealed that the machining performances of Ti-6Al-4V are mainly influenced by two-factor interaction effects involving all five variables as shown in Table 5. Therefore, the main effects of the five variables must be interpreted in together.
These results are interpreted to show that a combination of low gas pressure (or velocity), long spray distance, and high droplet flow rate for both the gases applied in an ACF spray system results in longer tool life during titanium machining. The only exception is that, to obtain a longer tool life, the air-mixed CO2 gas has to be impinged at a 25° angle whereas the N2 gas is at a 35° angle.
Though both the gas types offer tool life similar (about 10 min), the air-CO2 mixture is preferable during machining for a number of reasons. Overall chip breakability throughout machining is higher with the use of air —CO2 (90%) mixture as droplet carrier gas than with N2 (40-50%). A high rate of chip breakage is preferable as broken chips are less likely to entangle and accumulate in the machining zone, and rub the machined surface. Unbroken accumulated chips also become obstacles to impinging liquid droplets leading to jet momentum reduction and reduction in the amount of fluid droplets in the cutting zone. N2 gas can also cause a fire hazard during Ti-6Al-4V machining. CO2 gas is inexpensive, also because it is a byproduct from industrial process, and its use in methods of the invention provides environmental benefits as the CO2 gas is recycled into the process.
The tools used in two tests under flood coolant condition (test No. 17) machined for about 6 and 8 min, respectively, before failure indicating that the average tool life is about 7 min. As the nose of the tool No. 1 got chipped off after 6 min, and the wear exceeds 0.6 mm, the machining was stopped. The tools in these tests also produced heavy fire hazards and smokes due to poor penetration of the cutting fluid at the interface. Furthermore, the chips were rarely broken.
The results in Table 5 and
The air-mixed CO2 gas provides an initial temperature that is low (about 2° C.), which encourages formation of broken chips. The hot chips coming from the cutting zone immediately come into contact with this gas and quench at that temperature, which leads to increasing the brittleness of the chip material. At the pressure level of 150 or 300 psi, these chips are easily broken. In contrast, the initial temperature of impinging N2 gas is about 18-20° C., which does not promote breaking of the chips due to the lack of brittleness.
Nitrogen gas also produced significant fire hazards in the machine zone and produces smoke. As discussed above, the higher molecular inert gases behave differently and reduce the fire hazard. The air —CO2 mixture helps in diminishing the fire hazard and thus no fire hazard has been observed.
All the ACF spray system parameters such as pressure level and type of the mist carrier gas, mist flow rate, spray distance, impingement angle play significant role in the machining performances such as tool life and chip formation. For some combinations of these parameters, the ACF spray system improves tool life up to 40-50% over flood cooling as shown by the results. Though both N2 and air —CO2 mixture offer about the same tool life, air —CO2 effectively diminishes fire hazard in the cutting zone while N2 gas produces smoke by burning the mists at the elevated cutting temperature. The use of air —CO2 mixture in titanium turning often produces broken chips, which do not interact with the finished surface, and are beneficial in terms of chip management. The ACF spray system of the invention is cost effective due to a significantly lower amount of cutting fluid consumption (10-20 mL/min) as compared to flood cooling (1000 mL/min or above).
Spray Experiments
Experiments were conducted using the experimental ACF spray unit to characterize droplet spray behavior. The inner gas nozzle was 5 mm inside the droplet nozzle exit position to avoid divergence of droplets. Experiments using a 22 factorial design considering two gas velocities of 26 and 36 m/s, and two droplet velocities of 0.2 and 1.2 m/s were performed to study the effect of droplet velocity and gas velocity on droplet spray characteristics including droplet entrainment zone (e.g. angle and distance) and flow development regions described by droplet density and droplet distribution that is shown in
Experiments revealed a droplet-free zone at the center of the spray after its exit from the gas nozzle. After a certain distance that depends on the spray condition, the droplet and the gas merge and droplets distribute uniformly across the jet flare. The flow development behavior is characterized in
A liquid dispensing into still ambient air or parallel moving air/gas, defines an FF region is approximately x/dg≧25. See, Rukosuyev, M., et al., “Design and development of cutting fluid system based on ultrasonic atomization for micro-machining,” Transaction of the NAMRI/SME 38: 97-104 (2010); Fellouah, H., et al., “Reynolds number effects within the development region of a turbulent round free jet,” International Journal of Heat and Mass Transfer 52: 3943-3954 (2009).
The experimental device used 1.6 mm, and hence, the self-similar state (i.e. distance between the gas nozzle exit and the FF region) is expected to fall at 40 mm or beyond. However, the fully-developed or FF region was 24-35 mm, which is smaller than predicted by past studies. The early flow development of the self-similar state in the experiments testing embodiments of the invention could be attributable to the density of the center gas (air —CO2) being lower than the outer co-flow gas (droplet). Also, when gas velocity decreases, the distance between the gas nozzle exit and the FF region becomes shorter. The experiments suggest that the downstream distance for the self-similar state, where the flow becomes asymptotic, gets smaller with the reduction in gas velocity.
The experiments show that droplet and gas velocities in an ACF spray system influence the droplet entrainment mechanism and the droplet-gas mixing behavior at the center jet. A combination of a higher droplet velocity (1.2 m/s) and a lower gas velocity (26 m/s), among four spray conditions observed, provides the best spray condition in terms of droplet entrainment angle.
The behavior can be modeled to provide a theoretical relationship of droplet and gas velocities with droplet entrainment angle and entrainment zone, and their influence on droplet density and distribution across the jet flare at three different regions (i.e. NF, IF, and FF). When a high-velocity fluid is dispensed into a still atmospheric air or to a low-velocity parallel moving fluid, entrainment of the outer fluid into the inner fluid takes place. As the high-velocity fluid jet flows at a dynamic pressure, its static pressure reduces according to Bernoulli's principle. This causes a pressure difference between the jet domain and the surrounding fluid/air. Moreover, if a compressible fluid like gas is dispensed (exit from a nozzle), it immediately expands in the radial direction. The pressure difference and the gaseous nature of the dispensing fluid cause entraining of the outer surrounding gas or air to flow in and mix with the center gas. Due to differences in fluid properties and flow dynamics between the center jet and the outer droplets, one fluid diffuses into the other and vice versa. The slow-moving droplets cause aerodynamic drag to the high-velocity gas that results in deceleration of the gas, and the momentum lost by the high-velocity gas is received by the droplets. Their momentum gradually evolves to an equilibrium state (i.e. fully-developed) as the jet moves forward. A fully-developed flow is desirable. In
In the experiments, it was also shown that an increase of the droplet velocity (e.g., up to 1m/s) with a decrease of the gas velocity (e.g., 36 m/s to 26 m/s when measure at about 35 mm downstream distance from the gas nozzle 32) produce a better spray. The droplets-gas co-flow develop in short distance. This provides a potential core that does not contains droplets disappear early. The droplet entrainment angle becomes smaller with this combination (compare
To estimate the droplet entrainment angle, the following assumptions are made about the nature of the droplets:
Fluid droplets inside the droplet nozzle uniformly mix with the ambient air and create a homogenous droplet vapor. It appears to be a single gaseous phase, but different from the centerline gas jet in nature;
Fluid droplets do not interact each other during flow (non-condensing).
The fluid droplets are uniform in size.
Gravitational force acting on the droplets is ignored.
When a high-velocity gas is dispensed from a nozzle, the pressure difference between the jet and the surrounding rest or co-flow jet increases with the increase in its velocity. The Gaussian mean velocity profile shown in
where, Pd, Pgs, pd refer to the static pressure of the droplets in the droplet nozzle, the static pressure of the gas at the jet center, and the droplet equivalent density of the droplet vapor, respectively. The pressure difference, (Pd−Pgs) can be directly measured from a piezometer. The static pressure at the jet center, Pgs decreases with an increase in gas velocity. For a given control volume consisting of a circular ACF nozzle unit, an equivalent density of the droplet vapor can be calculated using mass conservation law:
where, ρf and ρa are the fluid and air densities, {dot over (V)}f is the volumetric fluid flow rate, t is time, VN is the control volume in round nozzle.
When a single droplet that is entrained in the droplet entrainment zone (formed around the potential core immediately after the gas nozzle exit) approaches to flow in the center at an angle, θgs due to the static pressure drop, the dynamic pressure of the jet that flows at a high velocity, Ug pulls off the droplet in its flow direction at a velocity, Ugr, at the outer contour of the jet. The flow of the droplet due to velocities, Ud, Ugs, and Ugr, can be represented by the velocity diagram of
where Ugr is the velocity at the outer contour of the jet, and its value is obtained as:
U
gr
=k
x
U
gx, (4)
where, kx is a proportionality constant, and Ugx, is the local jet velocity in the x-axis. At the nozzle exit, x=0, the value of Ugx, is approximately equal to Ug; however, it decreases with the increase in downstream distance as the velocity of the jet decays. Also, for a compressible non-viscous fluid flow, kx≈1 at x=0, because the velocity at the jet center is approximately equal to the velocity at the outer contour.
Equation 3 states that the droplet entrainment angle can be influenced by both gas velocity and droplet velocity. A higher droplet velocity, Ud governs a droplet to follow at a smaller angle, θr with respect to the jet axis. However, the dependence of gas velocity, Ug on the value of θr is a bit complex. With the increase in gas velocity, Ug, both Ugr and Ugs increase. Note that, if the value of Ug (or dynamic pressure) of the jet increases, the value of Ugs also increases due to a comparatively larger static pressure drop, (Pd−Pgs). Predicting the influence of Ug requires knowledge of the value of the static pressure of the jet, Pgs.
The expression for the droplet entrainment angle, θr in Eqn. (3) is obtained considering a single droplet in the droplet entrainment zone. However, when considering a number of droplets around the center jet, the droplet that is close to the gas jet contour will move faster than the one that is farther away. Therefore, the value of θr estimated from the above relationship for a co-flow jet may not be accurate.
The density and distribution of droplets across the jet flares at locations A, B, and C for three different regions: NF, IF and FF, vary as shown in
where, N is the number of fluid droplets depending on the flow rate and atomizer frequency, rjA, rjB, rjC are radii of the jet boundary layer at the locations A, B, C, respectively, and rpA, riB are radii of the potential core and the intermediate core at the locations, A, B, respectively. The jet boundary layer suffers from an eddy (turbulence) effect due to entrainment of atmospheric air. As such, average values of rjB and rjC should be taken for the intermediate and far-field regions. Eqns. 5(a)-(c) suggest that the average droplet density is significantly higher at location A followed by medium at location B, and the least at location C.
The droplet vapor is assumed to behave like one medium as a non-condensing gas. However, the fluid droplets may interact, especially when they come close or touch each other. This situation can occur in two ways: during entrainment in the droplet entrainment zone and during mixing within the NF (i.e. near-field) region. For a set of droplet and gas velocities, if the droplet entrainment angle increases, then the size of the droplet entrainment zone decreases due to a smaller downstream distance. In such a case, the droplet density becomes higher and the distance between the droplets may reduce. If two or more droplets touch each other, they will result in condensation and will form, comparatively, a larger droplet. Also, during mixing within the NF region, the entire amount of droplets usually passes through a smaller jet flare (for example, at cross section A-A in
To avoid condensation of the fluid droplets in the entrainment zone and next in the mixing region (i.e. near-filed and intermediate-field), it is preferable to allow the droplets to be entrained slowly and gradually until the intermediate region. In such a case, the radius of the jet at the NF and the IF regions will increase and the droplet density will decrease that will protect the fluid droplets from condensation.
While specific embodiments of the present invention have been shown and described, it should be understood that other modifications, substitutions and alternatives are apparent to one of ordinary skill in the art. Such modifications, substitutions and alternatives can be made without departing from the spirit and scope of the invention, which should be determined from the appended claims.
Various features of the invention are set forth in the appended claims.
This application claims priority under 35 U.S.C. §119 from prior provisional application Ser. No. 61/830,262, which was filed Jun. 3, 2013.
Number | Date | Country | |
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61830262 | Jun 2013 | US |