A device measures a frictional force and a film thickness of a lubricating oil film in different surface velocity directions. The device includes an experiment bench. A translation stage is mounted to the experiment bench, and is linearly movable. A main shaft system is mounted to the experiment bench. A glass disc is mounted to the main shaft system and is rotatable. An arcuate guide rail is disposed on the translation stage. A rotary base is mounted to the arcuate guide rail and is movable along the arcuate guide rail. A loading system is mounted to the rotary base. A steel ball of the loading system and the glass disc are movable relative to each other. A rotary bearing in the rotary base is configured to convert a frictional force generated from the relative movement to a pressure allowed to be collected by a pressure sensor on the rotary base.

A method for determining a suitability of a lubricant to avoid false brinelling damage in a bearing includes providing a rheometer and the lubricant, performing a first conditioning of the rheometer, filling the rheometer with a first lubricant sample, and deforming the first lubricant sample to determine a first shear stress from a first shear deformation of the first lubricant sample at the first temperature, with reference to the first zero point. The method also includes performing a second conditioning of the rheometer, refilling the rheometer with a second lubricant sample, and deforming the second lubricant sample to determine a second shear stress from a second shear deformation of the second lubricant sample at the second temperature, with reference to the second zero point. The lubricant is classified as suitable or unsuitable for avoiding false brinelling damage as a function of the first shear stress and the second shear stress.

A method for determining a suitability of a lubricant to avoid false brinelling damage in a bearing includes providing a rheometer and the lubricant, performing a first conditioning of the rheometer, filling the rheometer with a first lubricant sample, and deforming the first lubricant sample to determine a first shear stress from a first shear deformation of the first lubricant sample at the first temperature, with reference to the first zero point. The method also includes performing a second conditioning of the rheometer, refilling the rheometer with a second lubricant sample, and deforming the second lubricant sample to determine a second shear stress from a second shear deformation of the second lubricant sample at the second temperature, with reference to the second zero point. The lubricant is classified as suitable or unsuitable for avoiding false brinelling damage as a function of the first shear stress and the second shear stress.

A device for measuring fluid parameters may be modular or integrally formed. The device is positioned on a machine that includes one or more fluids to be monitored, and the device includes a (1) controller, (2) spacer that connects to a power source and that may include one or more connectors to connect to remote sensors, and (3) an optional manifold through which the fluid may pass. The manifold could include fluid sensors and/or be connectable to a sample bottle for the purpose of taking fluid samples.

A device for measuring fluid parameters may be modular or integrally formed. The device is positioned on a machine that includes one or more fluids to be monitored, and the device includes a (1) controller, (2) spacer that connects to a power source and that may include one or more connectors to connect to remote sensors, and (3) an optional manifold through which the fluid may pass. The manifold could include fluid sensors and/or be connectable to a sample bottle for the purpose of taking fluid samples.

A method for determining a suitability of a lubricant to avoid false brinelling damage in a bearing includes providing a rheometer and the lubricant, performing a first conditioning of the rheometer, filling the rheometer with a first lubricant sample, and deforming the first lubricant sample to determine a first shear stress from a first shear deformation of the first lubricant sample at the first temperature, with reference to the first zero point. The method also includes performing a second conditioning of the rheometer, refilling the rheometer with a second lubricant sample, and deforming the second lubricant sample to determine a second shear stress from a second shear deformation of the second lubricant sample at the second temperature, with reference to the second zero point. The lubricant is classified as suitable or unsuitable for avoiding false brinelling damage as a function of the first shear stress and the second shear stress.

A method for determining a suitability of a lubricant to avoid false brinelling damage in a bearing includes providing a rheometer and the lubricant, performing a first conditioning of the rheometer, filling the rheometer with a first lubricant sample, and deforming the first lubricant sample to determine a first shear stress from a first shear deformation of the first lubricant sample at the first temperature, with reference to the first zero point. The method also includes performing a second conditioning of the rheometer, refilling the rheometer with a second lubricant sample, and deforming the second lubricant sample to determine a second shear stress from a second shear deformation of the second lubricant sample at the second temperature, with reference to the second zero point. The lubricant is classified as suitable or unsuitable for avoiding false brinelling damage as a function of the first shear stress and the second shear stress.

A method for inspecting a lubricant oil composition containing a base oil and a fullerene, the method including: measuring at least one of a lamellar length of the lubricating oil composition and a most abundant diameter in a particle size distribution obtained by a dynamic light scattering method, and selecting the lubricating oil composition whose measured value is within a set range.

A system for simulating the effects of use and aging on immersive coolants. Two conductive coils are immersed in a tank containing a sample of the coolant. The coils are spaced such that electrical activation of the first coil induces current in the second coil. A DC power source is provided to an inverter, which provides AC current for activating the first coil. The induced AC current in the second coil is delivered to a rectifier which converts the induced AC current to DC current. The DC current is then returned to the power source. The electromagnetic field between the coils simulates motor operation, so that the coolant's physical and chemical characteristics can be tested for the effects of use and aging.

A method for determining the degree of sludge generation in oil includes: a deteriorated oil generating step ST1; a RPVOT testing step ST2; a sludge amount measuring step ST2B; and a determining step ST3. The step ST1 generates deteriorated oil oxidized by immersing and rotating a pressurized container in a thermostatic bath having a predetermined temperature. The pressurized container is pressurized until the oxygen partial pressure reaches a predetermined pressure higher than the value under atmospheric pressure by adding oil and a copper catalyst, substituting with oxygen, or injecting oxygen or air. The step ST2A measures an RPVOT residual ratio of a portion of generated deteriorated oil by the RPVOT test. The step ST2B measures the amount of sludge for a portion of generated deteriorated oil. The step ST3 determines the ease of sludge generation from the relationship between the measured RPVOT residual ratio and the amount of sludge.