This invention relates generally to geotechnical rig systems and methods. In one embodiment, a cone penetration testing system includes, but is not limited to, a frame; at least one rotatable reel; at least one movable roller; and at least one sensor, wherein the at least one movable roller is configured to adjust a bend radius of at least one tube coiled about the at least one rotatable reel based at least partly on data received from the at least one sensor.

The hardness of a rail after the rail having a temperature equal to or higher than an austenite region temperature is forcibly cooled in a cooling facility is predicted. A plurality of sets of data for learning composed of a cooling condition data set and output data of hardness are acquired using a model that performs computing by using a cooling condition data set having at least a surface temperature of the rail before the start of cooling and the operating conditions of the cooling facility as input data and the hardness inside the rail after the forced cooling as output data.

The hardness of a rail after the rail having a temperature equal to or higher than an austenite region temperature is forcibly cooled in a cooling facility is predicted. A plurality of sets of data for learning composed of a cooling condition data set and output data of hardness are acquired using a model that performs computing by using a cooling condition data set having at least a surface temperature of the rail before the start of cooling and the operating conditions of the cooling facility as input data and the hardness inside the rail after the forced cooling as output data.

A method for checking at least one subregion of a component, in particular a component of a turbomachine, including at least the steps of a) providing a blank; b) producing at least the subregion from the blank by machining the blank using at least one tool and using at least one force sensor-to record at least one force curve of at least one force acting during machining on the at least one tool; c) checking whether there is at least one deviation-of the at least one force curve from at least one predetermined target curve-of the at least one force curve, the at least one deviation-characterizing at least one material defect-contained in an unmachined segment of the subregion. A checking device for checking at least a subregion of a component is also provided.

A method for checking at least one subregion of a component, in particular a component of a turbomachine, including at least the steps of a) providing a blank; b) producing at least the subregion from the blank by machining the blank using at least one tool and using at least one force sensor-to record at least one force curve of at least one force acting during machining on the at least one tool; c) checking whether there is at least one deviation-of the at least one force curve from at least one predetermined target curve-of the at least one force curve, the at least one deviation-characterizing at least one material defect-contained in an unmachined segment of the subregion. A checking device for checking at least a subregion of a component is also provided.

An apparatus and method for inspection of at least one of grass, artificial turf, infill, or dirt, on a surface, using optical photographic images from a camera and three-dimensional (“3D”) depth scans using the camera and one or more laser, to create a mask to distinguish aspects of the surface, so that the surface can be measured and analyzed.

Example networked material testing systems include: a database system storing a shared database, the shared database storing a material test procedure and material test result data; a first material test system communicatively coupled to the database system and configured to perform a first type of material test; and a second material test system communicatively coupled to the database system and configured to perform the first type of material test; wherein the database system comprises a computing device configured to execute machine readable instructions which cause the computing device to: transmit a first test program to the first material test system for performance of the first type of material test on a first specimen according to the first test program; store, in the shared database, first test result data received from the first material test system based on execution of the first test program; transmit a second test program to the second material test system for performance of the first type of material test on a second specimen according to the second test program; store, in the shared database, second test result data received from the first material test system or the second material test system based on execution of the second test program; and generate one or more test reports based on the first test program, the first material test system that performed the first test program, the second test program, and the second material test system that performed the second test program.

Example networked material testing systems include: a database system storing a shared database, the shared database storing a material test procedure and material test result data; a first material test system communicatively coupled to the database system and configured to perform a first type of material test; and a second material test system communicatively coupled to the database system and configured to perform the first type of material test; wherein the database system comprises a computing device configured to execute machine readable instructions which cause the computing device to: transmit a first test program to the first material test system for performance of the first type of material test on a first specimen according to the first test program; store, in the shared database, first test result data received from the first material test system based on execution of the first test program; transmit a second test program to the second material test system for performance of the first type of material test on a second specimen according to the second test program; store, in the shared database, second test result data received from the first material test system or the second material test system based on execution of the second test program; and generate one or more test reports based on the first test program, the first material test system that performed the first test program, the second test program, and the second material test system that performed the second test program.

The present invention pertains to a device, system, and method for evaluating the condition of a wooden structure by automated profiling of the hardness of the structure. More particularly, the present invention is directed towards a probing device comprising a blade coupled to a resistance mechanism and a mechanical sensor for measuring the hardness of wood in a structure; a system comprising such a device, and a computing device coupled to the device that outputs the hardness measurements of the device; and a method for operating such a device and determining the condition of wood by identifying changes in hardness in a wooden structure.

The present invention pertains to a device, system, and method for evaluating the condition of a wooden structure by automated profiling of the hardness of the structure. More particularly, the present invention is directed towards a probing device comprising a blade coupled to a resistance mechanism and a mechanical sensor for measuring the hardness of wood in a structure; a system comprising such a device, and a computing device coupled to the device that outputs the hardness measurements of the device; and a method for operating such a device and determining the condition of wood by identifying changes in hardness in a wooden structure.