Abstract: A biometric scanner for processing live seafood harvests streamlines regulation compliance workflows and produces verifiable catch data that integrates with enterprise resource planning (ERP) systems. The biometric scanner captures individual images and weights of a live catch and applies an inference pipeline to the images and weights to determine one or more physical characteristics. Based on the one or more physical characteristics, the biometric scanner generates a unique fingerprint, determines compliance statuses, and generates a processing priority indicia for each individual unit of the live catch. Determining the compliance status requires factoring in all relevant certification and regulation-related policies and is intended to serve as a proxy for onboard oversight or auditing requirements. The processing priority indicia may comprise one more visual, auditory, or haptic feedback cues signaling a recommendation for how to prioritize the contents of a live harvest.

Abstract: A pelletized road marking composition includes a binder mixture, a filler mixture and bentonite clay. The binder mixture includes at least one alkyd ester, at least one wax, at least one ethylene copolymer, and at least one plasticizer. The filler mixture includes at least one coloring additive, reflective elements, and at least one inert inorganic filler. The components of the road marking composition are mixed and melted and processed into pellets. The bentonite clay added to the composition prevents the pellets from clumping when stored at elevated temperatures.

Abstract: Disclosed are apparatuses and methods including incorporation of additives into a bulk materials container by coating, impregnating, or otherwise applying the additives to at least a portion of the container and/or the material comprising the container. The container may be intended for containing bulk material used in a batch or continuous process, where the container can be consumed by the process along with the bulk material. The additives incorporated into the container can be substances that may be used by the process. The additives can modify the process. The additives can modify and/or condition the product being formed by the process.

Abstract: A liquid dispenser for containing and dispensing a sanitizing liquid is described that comprises a container body defining a container chamber in fluid communication with both a dispenser port and a fill port. The fluid dispenser comprises an atomizer operably connected to the dispenser port and a cover operably connectable to the container body and movable between a cover-open position in which the fill port is exposed and a cover-closed position in which the fill port is covered.

Abstract: Integrated circuit (5) includes substrate (10) with surface (20) and structure (30) including base levels (45.i, 45.(i+1)), terminating cells (48, 49), and block (40) of standard cells arranged in rows (42.i, 42.(i+1)), and another type of block (60) outside block (40). Standard cells at at least two edges of block (40) have the following protections: (1) block (60) has strip of separation (41.j) having at least a minimum width from the edges of block (40), and protected by one of the following: (2) terminating cells (48, 49) reduce context effect and some terminating cells (48) are placed at at least one end of rows (42.i, 42.(i+1)) of standard cells within first-named block (40), and (3) the terminating cells (48, 49) reduce context effect and some terminating cells (49) are at one end of a column of standard cells within block (40). Other structures, devices, and processes are also disclosed.

Abstract: Disclosed are apparatuses and methods including incorporation of additives into a bulk materials container by coating, impregnating, or otherwise applying the additives to at least a portion of the container and/or the material comprising the container. The container may be intended for containing bulk material used in a batch or continuous process, where the container can be consumed by the process along with the bulk material. The additives incorporated into the container can be substances that may be used by the process. The additives can modify the process. The additives can modify and/or condition the product being formed by the process.

Abstract: Disclosed are apparatuses and methods including incorporation of additives into a bulk materials container by coating, impregnating, or otherwise applying the additives to at least a portion of the container and/or the material comprising the container. The container may be intended for containing bulk material used in a batch or continuous process, where the container can be consumed by the process along with the bulk material. The additives incorporated into the container can be substances that may be used by the process. The additives can modify the process. The additives can modify and/or condition the product being formed by the process.

Abstract: A pelletized road marking composition includes a binder mixture, a filler mixture and bentonite clay. The binder mixture includes at least one alkyd ester, at least one wax, at least one ethylene copolymer, and at least one plasticizer. The filler mixture includes at least one coloring additive, reflective elements, and at least one inert inorganic filler. The components of the road marking composition are mixed and melted and processed into pellets. The bentonite clay added to the composition prevents the pellets from clumping when stored at elevated temperatures.

Abstract: The invention is a method and apparatus, automatic down hole blow out preventer wherein external elastomer rings are placed on the exterior of a grooved section of drill pipe. Below the external elastomer rings is an external pressure deflector ring, which is designed to be lifted up in a kick. When a kick occurs, the increased pressure will force the external pressure deflector ring up, causing the external elastomer rings to flip up and out as to inhibit or block the further flow of fluid up the annulus.

Abstract: Disclosed are apparatuses and methods including incorporation of additives into a bulk materials container by coating, impregnating, or otherwise applying the additives to at least a portion of the container and/or the material comprising the container. The container may be intended for containing bulk material used in a batch or continuous process, where the container can be consumed by the process along with the bulk material. The additives incorporated into the container can be substances that may be used by the process. The additives can modify the process. The additives can modify and/or condition the product being formed by the process.

Abstract: A coating for pelletized thermoplastic road marking material is provided in which at least one of waxes, silica compounds, and inorganic compounds is provided on the surface of the thermoplastic pellet. The pellet is formed by mixing a binder mixture with a filler mixture, heating the mixed ingredients while mixing into a homogenous molten mixture and then extruding the molten mixture. The extruded material is cooled, cut into individual pellets and then coated. The coating prevents clumping of the pellets and also imparts improved flowability and lower melting point properties. Preferred coatings include micronized polyethylene wax, silicates, silanes, silicones, siliconates, fluoropolymers, calcium carbonate and zeolite.

Abstract: Disclosed are apparatuses and methods including incorporation of additives into a bulk materials container by coating, impregnating, or otherwise applying the additives to at least a portion of the container and/or the material comprising the container. The container may be intended for containing bulk material used in a batch or continuous process, where the container can be consumed by the process along with the bulk material. The additives incorporated into the container can be substances that may be used by the process. The additives can modify the process. The additives can modify and/or condition the product being formed by the process.

Abstract: A coating for pelletized thermoplastic road marking material is provided in which at least one of waxes, silica compounds, and inorganic compounds is provided on the surface of the thermoplastic pellet. The pellet is formed by mixing a binder mixture with a filler mixture, heating the mixed ingredients while mixing into a homogenous molten mixture and then extruding the molten mixture. The extruded material is cooled, cut into individual pellets and then coated. The coating prevents clumping of the pellets and also imparts improved flowability and lower melting point properties. Preferred coatings include micronized polyethylene wax, silicates, silanes, silicones, siliconates, fluoropoymers, calcium carbonate and zeolite.

Abstract: Integrated circuit (5) includes substrate (10) with surface (20) and structure (30) including base levels (45.i, 45.(i+1)), terminating cells (48, 49), and block (40) of standard cells arranged in rows (42.i, 42.(i+1)), and another type of block (60) outside block (40). Standard cells at at least two edges of block (40) have the following protections: (1) block (60) has strip of separation (41.j) having at least a minimum width from the edges of block (40), and protected by one of the following: (2) terminating cells (48, 49) reduce context effect and some terminating cells (48) are placed at at least one end of rows (42.i, 42.(i+1)) of standard cells within first-named block (40), and (3) the terminating cells (48, 49) reduce context effect and some terminating cells (49) are at one end of a column of standard cells within block (40). Other structures, devices, and processes are also disclosed.

Abstract: Integrated circuit (5) includes substrate (10) with surface (20) and structure (30) including base levels (45.i, 45.(i+1)), terminating cells (48, 49), and block (40) of standard cells arranged in rows (42.i, 42.(i+1)), and another type of block (60) outside block (40). Standard cells at at least two edges of block (40) have the following protections: (1) block (60) has strip of separation (41.j) having at least a minimum width from the edges of block (40), and protected by one of the following: (2) terminating cells (48, 49) reduce context effect and some terminating cells (48) are placed at at least one end of rows (42.i, 42.(i+1)) of standard cells within first-named block (40), and (3) the terminating cells (48, 49) reduce context effect and some terminating cells (49) are at one end of a column of standard cells within block (40). Other structures, devices, and processes are also disclosed.

Abstract: Disclosed are apparatuses and methods including incorporation of additives into a bulk materials container by coating, impregnating, or otherwise applying the additives to at least a portion of the container and/or the material comprising the container. The container may be intended for containing bulk material used in a batch or continuous process, where the container can be consumed by the process along with the bulk material. The additives incorporated into the container can be substances that may be used by the process. The additives can modify the process. The additives can modify and/or condition the product being formed by the process.

Abstract: A coating for pelletized thermoplastic road marking material is provided in which at least one of waxes, silica compounds, and inorganic compounds is provided on the surface of the thermoplastic pellet. The pellet is formed by mixing a binder mixture with a filler mixture, heating the mixed ingredients while mixing into a homogenous molten mixture and then extruding the molten mixture. The extruded material is cooled, cut into individual pellets and then coated. The coating prevents clumping of the pellets and also imparts improved flowability and lower melting point properties. Preferred coatings include micronized polyethylene wax, silicates, silanes, silicones, siliconates, fluoropoymers, calcium carbonate and zeolite.

Abstract: Through various embodiments, a traceability system may comprise a first tracking device configured to receive a pre-generated session identification number, wherein the pre-generated session identification number is assigned to a first load and a MAC address of the device. The device is further configured to initialize one or more environmental sensors of the device and generate, through the one or more environmental sensors, environmental data pertaining to one or more factors of an environment surrounding the device. The device is additionally configured to execute a propagation query to generate a second session identification number adapted from the pre-generated session identification number, the second session identification number being related to a second load derived from the first load.