Abstract: A system for railroad directive management is presented. The system can receive a myriad of data related to a directive, track segments, and/or vehicle events on the track and/or track segments. Vehicle- and/or event-specific data can be compared with one or more thresholds, including force thresholds, temporal thresholds, environmental thresholds, and/or event thresholds to determine whether and what kind of directive modification should be instantiated. Specialized algorithms can be implemented to trace vehicle paths along the track to determine whether directive-related segments are traversed, and specialized clustering algorithms can be utilized to cluster data unique to a particular segment on a per-segment basis. The system can be integrated with existing track infrastructure and can further generate alerts to notify coupled systems and/or personnel of directives and/or modification thereof.

Abstract: Method and apparatus for identifying the authenticity of collectibles including sport and non-sport card collectibles. The apparatus comprises a marking device that places a mark on the collectible that is a unique characteristic of the collectible that authenticates the collectible as being an original collectible created, produced, or manufactured at a specific location, time or by the person or entity identified as such on the collectible. The original mark will remain attached to the collectible forever with the use of Blockchain and/or NFT technology. The original mark may be used to located the collectible.

Abstract: The present disclosure is directed to a thermoplastic polymer for additive manufacturing, wherein the thermoplastic polymer is derived from a chlorinated monomer unit, wherein the thermoplastic polymer has a melt flow rate (MFR) suitable for additive manufacturing. The present disclosure is also directed to a method of making a 3D product formed by additive manufacturing, wherein the 3D product comprises a thermoplastic polymer derived from a chlorinated monomer unit or a thermoplastic composition comprising at least one thermoplastic polymer derived from a chlorinated monomer unit; and at least one stabiliser, wherein the thermoplastic polymer or composition has a MFR suitable for additive manufacturing.

Abstract: A method of preparing and serving a meal package (10) comprising the steps of: preparing a meal package(10), including:disposing a food product (16, 17) into a container (11), the container (11) having an opening defining therein a volume for receiving the food product(16, 17); and sealing the container by securing a film (12) over or around the container (11);heating the meal package (10) in a microwave oven; removing the film from the container; serving the heated food product in the container; cleaning the used container after the food product has been consumed; and repeating the above steps for the used container.

Abstract: The present disclosure is directed to a thermoplastic polymer for additive manufacturing, wherein the thermoplastic polymer is derived from a chlorinated monomer unit, wherein the thermoplastic polymer has a melt flow rate (MFR) suitable for additive manufacturing. The present disclosure is also directed to a method of making a 3D product formed by additive manufacturing, wherein the 3D product comprises a thermoplastic polymer derived from a chlorinated monomer unit or a thermoplastic composition comprising at least one thermoplastic polymer derived from a chlorinated monomer unit; and at least one stabiliser, wherein the thermoplastic polymer or composition has a MFR suitable for additive manufacturing.

Abstract: The present disclosure is directed to a thermoplastic polymer for additive manufacturing, wherein the thermoplastic polymer is derived from a chlorinated monomer unit, wherein the thermoplastic polymer has a melt flow rae (MFR) suitable for additive manufacturing. The present disclosure is also directed to a method of making a 3D product formed by additive manufacturing, wherein the 3D product comprises a thermoplastic polymer derived from a chlorinated monomer unit or a thermoplastic composition comprising at least one thermoplastic polymer derived from a chlorinated monomer unit; and at least one stabiliser, wherein the thermoplastic polymer or composition has a MFR suitable for additive manufacturing.

Abstract: The present discolosure is directed to a thermoplastic polymer for additive manufacturing, wherein the thermoplastic polymer is derived from a chlorinated monomer unit, wherein the thermoplastic polymer has a melt flow rae (MFR) suitable for additive manufacturing. The present disclosure is also directed to a method of making a 3D product formed by additive manufacturing, wherein the 3D product comprises a thermoplastic polymer derived from a chlorinated monomer unit or a thermoplastic composition comprising at least one thermoplastic polymer derived from a chlorinated monomer unit; and at least one stabiliser, wherein the thermoplastic polymer or composition has a MFR suitable for additive manufacturing.

Abstract: Embodiments of the invention provide a canopy system and a method for manufacturing at least a portion of the canopy system. The canopy system may include: a canopy that includes a shaft and a canopy ball coupled to the shaft; a double socket arm connected to the canopy via the canopy ball; and a mount, the mount having a mounting ball, the mount connected to the double socket arm via the mounting ball, the canopy system thus configured for a wide range of canopy articulation with respect to the mount. Alternative embodiments are provided for the shaft, double socket arm and mounts. A manufacturing process is provided for securing the canopy ball to the shaft.

Abstract: Embodiments of the invention provide a canopy system and a method for manufacturing at least a portion of the canopy system. The canopy system may include: a canopy that includes a shaft and a canopy ball coupled to the shaft; a double socket arm connected to the canopy via the canopy ball; and a mount, the mount having a mounting ball, the mount connected to the double socket arm via the mounting ball, the canopy system thus configured for a wide range of canopy articulation with respect to the mount. Alternative embodiments are provided for the shaft, double socket arm and mounts. A manufacturing process is provided for securing the canopy ball to the shaft.

Abstract: The present disclosure addresses improvements to online advertising, including improvements that verify, validate, or otherwise confirm that online ad impressions and/or online ad views and the like meet the needs of advertisers. In various embodiments, the data describing online ad impressions and/or online ad views is tested to validate or verify that the data satisfies various criteria defined by or for advertisers, such as demographic, brand safety, visibility, geographic or anti-fraud requirements. The present disclosure also describes improvements in measurements and metrics that describe advertising audiences and effectiveness based on the data describing validated online ad impressions.

Abstract: Embodiments of the invention provide a canopy system. The canopy system may include: a canopy that includes a shaft and a canopy ball coupled to the shaft; a double socket arm connected to the canopy via the canopy ball; and a mount, the mount having a mounting ball, the mount connected to the double socket arm via the mounting ball, the canopy system thus configured for a wide range of canopy articulation with respect to the mount. Alternative embodiments are provided for the shaft, double socket arm and mounts.