A Coupling Approach Combining Computational Fluid Dynamics and Finite Element Method to Predict Cutting Fluid Effects on the Tool Temperature in Cutting Processes

2019 ◽  
Vol 141 (10) ◽  
Author(s):  
Thorsten Helmig ◽  
Bingxiao Peng ◽  
Claas Ehrenpreis ◽  
Thorsten Augspurger ◽  
Yona Frekers ◽  
...  
Keyword(s):  
Heat Transfer ◽  
Cutting Tool ◽  
Cfd Simulation ◽  
Cutting Conditions ◽  
Cutting Fluid ◽  
Tool Temperature ◽  
Aisi 1045 ◽  
Coupling Approach ◽  
Cutting Processes ◽  
Workpiece Setup

In metal cutting processes, the use of cutting fluids shows significant effects on workpiece surface quality by reducing thermomechanical loads on cutting tool and workpiece. Many efforts are made to model these thermomechanical processes, however without considering detailed heat transfer between cutting fluid, tool, and workpiece. To account for heat transfer effects, a coupling approach is developed, which combines computational fluid dynamics (CFD) and finite element method (FEM) chip formation simulation. Prior to the simulation, experimental investigations in orthogonal cutting in dry and wet cutting conditions with two different workpiece materials (AISI 1045 and DA 718) are conducted. To measure the tool temperature in dry as well as in wet cutting conditions, a two color pyrometer is placed inside an electrical discharge machining (EDM) drilled cutting tool hole. Besides tool temperature, the cutting force is recorded during the experiments and later used to calculate heat source terms for the CFD simulation. After the experiments, FEM chip formation simulations are performed and provide the chip forms for the CFD mesh generation. In general, CFD simulation and experiment are in reasonable agreement, as for each workpiece setup the measured temperature data are located between the simulation results from the two different tool geometries. Furthermore, numerical and experimental results both show a decrease of tool temperature in wet cutting conditions, however revealing a more significant cooling effect in a AISI 1045 workpiece setup. The results suggest that the placement of drilling holes has a major influence on the local tool temperature distribution, as the drilling hole equals a thermal resistance and hence leads to elevated temperatures at the tool front.

A Coupling Approach Combining CFD and FEM Methods to Predict Cutting Fluid Effects on the Tool Temperature in Cutting Processes

2019 ◽  
Author(s):  
Thorsten Helmig ◽  
Bingxiao Peng ◽  
Claas Ehrenpreis ◽  
Thorsten Augspurger ◽  
Yona Frekers ◽  
...  
Keyword(s):  
Heat Transfer ◽  
Cutting Tool ◽  
Cfd Simulation ◽  
Cutting Conditions ◽  
Cutting Fluid ◽  
Tool Temperature ◽  
Aisi 1045 ◽  
Coupling Approach ◽  
Cutting Processes ◽  
Workpiece Setup

Abstract In metal cutting processes the use of cutting fluids shows significant effects on workpiece surface quality by reducing thermomechanical loads on cutting tool and workpiece. Many efforts are made to model these thermomechanical processes, however without considering detailed heat transfer between cutting fluid, tool and workpiece. To account for heat transfer effects, a coupling approach is developed which combines CFD (Computational Fluid Dynamics) and FEM (Finite Element Method) chip formation simulation. Prior to the simulation, experimental investigations in orthogonal cutting in dry and wet cutting conditions with two different workpiece materials (AISI 1045 and DA 718) are conducted. To measure the tool temperature in dry as well as in wet cutting conditions, a two color pyrometer is placed inside a EDM drilled cutting tool hole. Besides tool temperature, the cutting force is recorded during the experiments and later used to calculate heat source terms for the CFD simulation. After the experiments, FEM chip formation simulations are performed and provide the chip forms for the CFD mesh generation. In general, CFD simulation and experiment are in reasonable agreement, as for each workpiece setup the measured temperature data is located between the simulation results from the two different tool geometries. Furthermore, numerical and experimental results both show a decrease of tool temperature in wet cutting conditions, however revealing a more significant cooling effect in a AISI 1045 workpiece setup. The results suggest that the placement of drilling holes has a major influence on the local tool temperature distribution, as the drilling hole equals a thermal resistance and hence leads to elevated temperatures at the tool front.

scholarly journals MODELING THE COOLING EFFECT OF THE CUTTING FLUID IN MACHINING USING A COUPLED FE-CFD SIMULATION

2021 ◽  
Vol 2021 (3) ◽  
pp. 4576-4583
Author(s):  
H. Liu ◽  
◽  
T. Helmig ◽  
T. Augspurger ◽  
N. Nhat ◽  
...  
Keyword(s):  
Heat Transfer ◽  
Convective Heat Transfer ◽  
Convective Heat ◽  
Cfd Simulation ◽  
Cutting Fluid ◽  
Model Parameters ◽  
Fe Model ◽  
Tool Temperature ◽  
Tool Surface ◽  
Cutting Zone

The cooling with cutting fluids is a complex process in manufacturing, since chemical, mechanical and thermal phenomena occur simultaneously. The experimental methods developed so far do not allow for a direct observation of the coolant flow during machining, which limits the understanding of the cooling mechanism. The main aim of this paper is the investigation of convective heat transfer between cutting fluid and the cutting zone as well as the heat flow distribution on the tool surface during the cutting process by means of a coupled FE-CFD simulation. The FE model calculates the heat generation under consideration of the experimentally validated punctual, transient tool temperature during the machining processes. Based on the result of the FE, the subsequent CFD simulation performs the calculation of the flow behavior and convective heat transfer. This method allows a detailed investigation of the temperature field in the cutting zone under consideration of the cutting fluid. The simulation returns spatially resolved heat transfer coefficients along the tool surface and provides first findings for an improvement of heat removal efficiency by changing the coolant supply parameters and the physical properties of the cutting fluid. The model parameters were validated by comparing the simulation results and the measured punctual tool temperature.

A Thermal Model to Predict Tool Temperature in Machining of Ti-6Al-4V Alloy With an Atomization-Based Cutting Fluid Spray System

2016 ◽  
Author(s):  
Asif Tanveer ◽  
Deepak Marla ◽  
Shiv G. Kapoor
Keyword(s):  
Heat Transfer ◽  
Interaction Model ◽  
Spray Cooling ◽  
Droplet Surface ◽  
Cutting Fluid ◽  
Design Parameters ◽  
Transfer Model ◽  
Tool Temperature ◽  
Spray System ◽  
Heat Transfer Phenomenon

In this study a heat transfer model of machining of Ti-6Al-4V under the application of atomization-based cutting fluid spray coolant is developed to predict the temperature of the cutting tool. Owing to high tool temperature involved in machining of Ti-6Al-4V, the model considers film boiling as the major heat transfer phenomenon. In addition, the design parameters of the spray for effective cooling during machining are derived based on droplet-surface interaction model. Machining experiments are conducted and the temperatures are recorded using the inserted thermocouple technique. The experimental data are compared with the model predictions. The temperature field obtained is comparable to the experimental results, confirming that the model predicts tool temperature during machining with ACF spray cooling satisfactorily.

Experimental validation of a quasi-transient coupling approach for the modeling of heat transfer in autoclave processing

2022 ◽  
pp. 002199832110635
Author(s):  
Junhong Zhu ◽  
Tim Frerich ◽  
Adli Dimassi ◽  
Michael Koerdt ◽  
Axel S. Herrmann
Keyword(s):  
Heat Transfer ◽  
Cfd Simulation ◽  
Transfer Problem ◽  
Numerical Study ◽  
Computing Time ◽  
Computational Cost ◽  
Transfer Coefficients ◽  
Lumped Mass ◽  
Coupling Approach ◽  
Transient Coupling

Structural aerospace composite parts are commonly cured through autoclave processing. To optimize the autoclave process, manufacturing process simulations have been increasingly used to investigate the thermal behavior of the cure assembly. Performing such a simulation, computational fluid dynamics (CFD) coupled with finite element method (FEM) model can be used to deal with the conjugate heat transfer problem between the airflow and solid regions inside the autoclave. A transient CFD simulation requires intensive computing resources. To avoid a long computing time, a quasi-transient coupling approach is adopted to allow a significant acceleration of the simulation process. This approach has been validated for a simple geometry in a previous study. This paper provides an experimental and numerical study on heat transfer in a medium-sized autoclave for a more complicated loading condition and a composite structure, a curved shell with three stringers, that mocks the fuselage structure of an aircraft. Two lumped mass calorimeters are used for the measurement of the heat transfer coefficients (HTCs) during the predefined curing cycle. Owing to some uncertainty in the inlet flow velocity, a correction parameter and calibration method are proposed to reduce the numerical error. The simulation results are compared to the experimental results, which consist of thermal measurements and temperature distributions of the composite shell, to validate the simulation model. This study shows the capability and potential of the quasi-transient coupling approach for the modeling of heat transfer in autoclave processing with reduced computational cost and high correlation between the experimental and numerical results.

Computational Methods for the Assessment of Nanofluids in Abrasive Processes

2017 ◽  
Vol 261 ◽  
pp. 201-206
Author(s):  
Nikolaos E. Karkalos ◽  
Angelos P. Markopoulos
Keyword(s):  
Temperature Profile ◽  
Metal Cutting ◽  
Cutting Tool ◽  
Cutting Fluid ◽  
Environmental Concerns ◽  
Cutting Fluids ◽  
Fluid Type ◽  
Cooling Fluid ◽  
Cutting Processes ◽  
The Cost

Metal cutting processes such as machining or abrasive processes are related to the production of relatively large amounts of heat, as a result of the intense contact of workpiece and cutting tool. For that reason, it is often necessary to employ a cooling fluid in order to alleviate the intense and usually undesired heat-induced effects on the workpiece. Due to the cost and environmental concerns regarding cutting fluids, the heat absorbing efficiency and quantity of cutting fluids employed is always a concern. In the present work, the effect of cutting fluid type in the temperature profile of the workpiece during grinding is investigated and useful conclusions are drawn, concerning the efficiency of nanofluids as cutting fluids.

scholarly journals A Thermal Model to Predict Tool Temperature in Machining of Ti–6Al–4V Alloy With an Atomization-Based Cutting Fluid Spray System

2017 ◽  
Vol 139 (7) ◽  
Author(s):  
Asif Tanveer ◽  
Deepak Marla ◽  
Shiv G. Kapoor
Keyword(s):  
Heat Transfer ◽  
Interaction Model ◽  
Spray Cooling ◽  
Droplet Surface ◽  
Cutting Fluid ◽  
Design Parameters ◽  
Transfer Model ◽  
Tool Temperature ◽  
Spray System ◽  
Heat Transfer Phenomenon

In this study, a heat transfer model of machining of Ti–6Al–4V under the application of atomization-based cutting fluid (ACF) spray coolant is developed to predict the temperature of the cutting tool. Owing to high tool temperature involved in machining of Ti–6Al–4V, the model considers film boiling as the major heat transfer phenomenon. In addition, the design parameters of the spray for effective cooling during machining are derived based on droplet–surface interaction model. Machining experiments are conducted and the temperatures are recorded using the inserted thermocouple technique. The experimental data are compared with the model predictions. The temperature field obtained is comparable to the experimental results, confirming that the model predicts tool temperature during machining with ACF spray cooling satisfactorily.

The Effect of Regulating Elements on Convective Heat Transfer along Shaped Heat Exchange Surfaces

2013 ◽  
Vol 34 (1) ◽  
pp. 5-16 ◽  
Author(s):  
Jozef Cernecky ◽  
Jan Koniar ◽  
Zuzana Brodnianska
Keyword(s):  
Heat Transfer ◽  
Heat Exchange ◽  
Cfd Simulation ◽  
Local Heat Transfer ◽  
Local Heat ◽  
Temperature Fields ◽  
Transfer Coefficients ◽  
Heat Transfer Intensification ◽  
Heat Transfer Coefficients ◽  
Forced Air

Abstract The paper deals with a study of the effect of regulating elements on local values of heat transfer coefficients along shaped heat exchange surfaces with forced air convection. The use of combined methods of heat transfer intensification, i.e. a combination of regulating elements with appropriately shaped heat exchange areas seems to be highly effective. The study focused on the analysis of local values of heat transfer coefficients in indicated cuts, in distances expressed as a ratio x/s for 0; 0.33; 0.66 and 1. As can be seen from our findings, in given conditions the regulating elements can increase the values of local heat transfer coefficients along shaped heat exchange surfaces. An optical method of holographic interferometry was used for the experimental research into temperature fields in the vicinity of heat exchange surfaces. The obtained values correspond very well with those of local heat transfer coefficients αx, recorded in a CFD simulation.

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