Pressure and Temperature Field Measurements of a Lightly Loaded Circumferential Groove Journal Bearing

“…The difference in the pressure and temperature might be due to the high number of holes for the pressure and temperature sensors of the bushing. Yet another reason may be the lack of simulation methods in the groove: physically, the temperature field in the groove is dependent on the oil flow (speed and mass flow rate) in the groove and the pressure field is not constant in the groove [20]. The present TEHD simulation tool is not capable of taking into account these phenomena: the pressure is supposed to be constant in the simulation tool and the oil temperature in the groove depends only on the temperature of the bushing and shaft temperature.…”

“…In 2011, Cristea [20,21] published several experiments of a central groove journal bearing at equilibrium state. His test rig consisted of a rotating shaft of 80 mm diameter, with a 61 µm radial clearance at room temperature (22 • C).…”

“…The temperature measurements were done at every 10 • , at 5 different axial sections (at 1, 7, 13, 19 and 26.5 mm from the end of the land). Unlike in [20], Cristea measured the oil flow rate and the resistant torque during his experiments in [21].…”

“…Cristea's journal bearing had a steel shaft and a bronze bushing with an external diameter of 200 mm. The oil inlet temperature was constant, at 30 • C during the experiments of Cristea [20] and 40 • C for [21] (see Table 3). Table 3.…”

“…Table 3. Journal bearing and oil supply properties of the experiments of Cristea [20,21]. 1 Oil supply temperature for [21].…”

Experimental and Numerical Analysis on the Seizure of a Carbon-Filled PTFE Central Groove Journal Bearing during Start-Up Period

“…The difference in the pressure and temperature might be due to the high number of holes for the pressure and temperature sensors of the bushing. Yet another reason may be the lack of simulation methods in the groove: physically, the temperature field in the groove is dependent on the oil flow (speed and mass flow rate) in the groove and the pressure field is not constant in the groove [20]. The present TEHD simulation tool is not capable of taking into account these phenomena: the pressure is supposed to be constant in the simulation tool and the oil temperature in the groove depends only on the temperature of the bushing and shaft temperature.…”

“…In 2011, Cristea [20,21] published several experiments of a central groove journal bearing at equilibrium state. His test rig consisted of a rotating shaft of 80 mm diameter, with a 61 µm radial clearance at room temperature (22 • C).…”

“…The temperature measurements were done at every 10 • , at 5 different axial sections (at 1, 7, 13, 19 and 26.5 mm from the end of the land). Unlike in [20], Cristea measured the oil flow rate and the resistant torque during his experiments in [21].…”

“…Cristea's journal bearing had a steel shaft and a bronze bushing with an external diameter of 200 mm. The oil inlet temperature was constant, at 30 • C during the experiments of Cristea [20] and 40 • C for [21] (see Table 3). Table 3.…”

“…Table 3. Journal bearing and oil supply properties of the experiments of Cristea [20,21]. 1 Oil supply temperature for [21].…”

Experimental and Numerical Analysis on the Seizure of a Carbon-Filled PTFE Central Groove Journal Bearing during Start-Up Period

Experimental Study of Temperature Distribution and Oil Flow Rate for Plain and Herringbone-Grooved Hydrodynamic Journal Bearing

Experimental rigs for testing components of advanced industrial applications