Abstract: The invention features methods and apparatuses for altering a cutting operation during operation of the pressurized liquid jet cutting system. A pressurized liquid jet cutting system includes a pressurized fluid jet cutting head having a plurality of components. The cutting head further includes a sensor configured to sense an operating condition. The sensor transmits a value of the operating condition to a computing device, which alters a subsequent cutting operation. Further, the fluid jet cutting head is configured to work with a data storage mechanism and a reader, such that the data storage mechanism in contact with a body of the fluid jet cutting head is configured to communicate information to a reader of the pressurized liquid jet cutting system. The information is usable to determine a condition of replacement (e.g.

Abstract: A transportable fold-out at least partial enclosure includes in one aspect of the invention a stationary platform having a major surface defining a stationary plane, a plurality of side edges, a front edge and a back edge. A primary platform has a major surface defining a primary plane, an inside edge, an outside edge, a front edge, a back edge, the inside edge being joined to the stationary platform, the primary platform having a folded position in which the primary plane and stationary plane are oblique or orthogonal, and the primary platform having an extended position where the primary platform is unfolded from the stationary platform. An end wall assembly has at least two segments, each segment having a major surface defining a segment plane, side edges, a top edge and a bottom edge, the side edges of the segments being joined to each other, the bottom edges of each segment being joined to one of the stationary platform and the primary platform.

Abstract: An aspect includes a transportable fold-out at least partial enclosure including: a center stationary section; a pair of primary platform assemblies, each primary platform including a first panel pivotally joined on opposite sides of the center stationary section and a second panel pivotally joined to the first panel on a side opposite the first panel; and at least one wall assembly pivotally joined to center stationary section and one of the primary platforms.

Abstract: A transportable fold-out at least partial enclosure includes in one aspect of the invention a stationary platform having a major surface defining a stationary plane, a plurality of side edges, a front edge and a back edge. A primary platform has a major surface defining a primary plane, an inside edge, an outside edge, a front edge, a back edge, the inside edge being joined to the stationary platform, the primary platform having a folded position in which the primary plane and stationary plane are oblique or orthogonal, and the primary platform having an extended position where the primary platform is unfolded from the stationary platform. An end wall assembly has at least two segments, each segment having a major surface defining a segment plane, side edges, a top edge and a bottom edge, the side edges of the segments being joined to each other, the bottom edges of each segment being joined to one of the stationary platform and the primary platform.

Abstract: A method and system utilizing multi-sensor analysis and data point correlation is provided for predictive monitoring and maintenance of a pressurized fluid cutting system. In a disclosed aspect, multiple sensed characteristics of system operation are correlated to determine a particular failure mode. Identification of the failure mode through active sensor data analysis and correlation facilitates predictive maintenance, minimizes system downtime, and optimizes system output.

Abstract: A disposable seal carriage for use with a liquid jet cutting system can include a body having a first end portion, a longitudinal axis, and a second end portion opposite the first end portion along the longitudinal axis. The first end portion can have a first outer width as measured perpendicular to the longitudinal axis, the second end portion can have a second outer width as measured perpendicular to the longitudinal axis, and the first outer width can be greater than the second outer width. The seal carriage can further include a flexible region extending through at least a portion of the body along a portion of the longitudinal axis. In some embodiments, the body includes a plurality of exterior projections positioned between the first and second end portions.

Abstract: A method and system utilizing multi-sensor analysis and data point correlation is provided for predictive monitoring and maintenance of a pressurized fluid cutting system. In a disclosed aspect, multiple sensed characteristics of system operation are correlated to determine a particular failure mode. Identification of the failure mode through active sensor data analysis and correlation facilitates predictive maintenance, minimizes system downtime, and optimizes system output.

Abstract: A transportable fold-out at least partial enclosure includes in one aspect of the invention a stationary platform having a major surface defining a stationary plane, a plurality of side edges, a front edge and a back edge. A primary platform has a major surface defining a primary plane, an inside edge, an outside edge, a front edge, a back edge, the inside edge being joined to the stationary platform, the primary platform having a folded position in which the primary plane and stationary plane are oblique or orthogonal, and the primary platform having an extended position where the primary platform is unfolded from the stationary platform. An end wall assembly has at least two segments, each segment having a major surface defining a segment plane, side edges, a top edge and a bottom edge, the side edges of the segments being joined to each other, the bottom edges of each segment being joined to one of the stationary platform and the primary platform.

Abstract: An operational monitoring system for use with a liquid jet cutting system can include an accelerometer coupled to a cutting head of the liquid jet cutting system. The accelerometer can be configured to generate motion data associated with movement of the cutting head. The system can include a computing device operably connected to the accelerometer and having a memory and a processor. The memory can store a planned data set including expected parameters associated with movement of the cutting head along a planned cut path. In some embodiments, the computing device is configured to receive the motion data from the accelerometer and correlate the motion data to the planned data set.

Abstract: A pressurized fluid jet cutting head is provided. The cutting head includes a body having one or more component parts coupled together, wherein a junction in the cutting head is defined between a first component part having a first engagement surface and a second component part having a second engagement surface, wherein the first and second engagement surfaces abut at the junction. A temperature sensor is positioned in thermal communication with the body and is configured to measure a temperature value of at least one of the first component part, the second component part, and the junction. The temperature value is communicated to a controller for analysis, wherein the controller receives the measured temperature value and communicates operating instructions for the cutting head based on a comparison of the measured temperature value to a predetermined value.

Abstract: An ultra high-pressure liquid jet soil processing system of an agricultural implement is provided. The ultra high-pressure liquid jet soil processing system includes a frame, an ultra high-pressure liquid pump disposed on the frame, a set of ultra high-pressure lines fluidly connected to the ultra high-pressure liquid pump, and at least a first liquid jet soil implementation head and a second liquid jet soil implementation head fluidly connected to the ultra high-pressure liquid pump via the set of ultra high-pressure lines. The first and second implementation heads are configured to condition soil for seed deposition by generating a plurality of trenches.

Abstract: An aspect includes a transportable fold-out at least partial enclosure including: a center stationary section; a pair of primary platform assemblies, each primary platform including a first panel pivotally joined on opposite sides of the center stationary section and a second panel pivotally joined to the first panel on a side opposite the first panel; and at least one wall assembly pivotally joined to center stationary section and one of the primary platforms.

Abstract: A method and system utilizing multi-sensor analysis and data point correlation is provided for predictive monitoring and maintenance of a pressurized fluid cutting system. In a disclosed aspect, multiple sensed characteristics of system operation are correlated to determine a particular failure mode. Identification of the failure mode through active sensor data analysis and correlation facilitates predictive maintenance, minimizes system downtime, and optimizes system output.

Abstract: Provided is an adaptive maintenance system of a pressurized fluid cutting system including methodological aspects of generating a service part replacement criteria for a part of the pressurized fluid cutting system and setting forth a protocol to manage maintenance of the pressurized fluid cutting system.

Abstract: A transportable fold-out at least partial enclosure includes in one aspect of the invention a stationary platform having a major surface defining a stationary plane, a plurality of side edges, a front edge and a back edge. A primary platform has a major surface defining a primary plane, an inside edge, an outside edge, a front edge, a back edge, the inside edge being joined to the stationary platform, the primary platform having a folded position in which the primary plane and stationary plane are oblique or orthogonal, and the primary platform having an extended position where the primary platform is unfolded from the stationary platform. An end wall assembly has at least two segments, each segment having a major surface defining a segment plane, side edges, a top edge and a bottom edge, the side edges of the segments being joined to each other, the bottom edges of each segment being joined to one of the stationary platform and the primary platform.

Abstract: A pressurized fluid jet cutting head is provided. The cutting head includes a body having one or more component parts coupled together, wherein a junction in the cutting head is defined between a first component part having a first engagement surface and a second component part having a second engagement surface, wherein the first and second engagement surfaces abut at the junction. A temperature sensor is positioned in thermal communication with the body and is configured to measure a temperature value of at least one of the first component part, the second component part, and the junction. The temperature value is communicated to a controller for analysis, wherein the controller receives the measured temperature value and communicates operating instructions for the cutting head based on a comparison of the measured temperature value to a predetermined value.

Abstract: An orifice assembly for a liquid jet cutting system includes a generally cylindrical base, an orifice member, and an orifice cap. The base includes a conduit that extends through a central axis from a top surface to a bottom surface of the base. The base also includes a pedestal that defines a protrusion from the top surface, the pedestal having a planar top region substantially parallel to the planar bottom region of the base. The orifice member sits on the planar top region of the pedestal. The orifice member defines an intermediate conduit therethrough, the intermediate conduit in fluid communication with the base conduit. The orifice cap defines an upper conduit therethrough, the upper conduit in fluid communication with the intermediate conduit of the orifice member. The orifice cap is configured to secure the orifice member to the pedestal.

Abstract: An orifice assembly for a liquid jet cutting system includes a generally cylindrical base, an orifice member, and an orifice cap. The base includes a conduit that extends through a central axis from a top surface to a bottom surface of the base. The base also includes a pedestal that defines a protrusion from the top surface, the pedestal having a planar top region substantially parallel to the planar bottom region of the base. The orifice member sits on the planar top region of the pedestal. The orifice member defines an intermediate conduit therethrough, the intermediate conduit in fluid communication with the base conduit. The orifice cap defines an upper conduit therethrough, the upper conduit in fluid communication with the intermediate conduit of the orifice member. The orifice cap is configured to secure the orifice member to the pedestal.