Abstract: A machine for depositing toppings onto a loaf of dough includes a lower belt assembly, an upper belt assembly and a pair of side belt assemblies. The lower belt assembly includes a lower conveyor belt that rotates in a first direction at a first speed to carry the loaf of dough from an upstream end of the machine to a downstream end of the machine. The upper belt assembly includes an upper conveyor belt that rotates in the first direction. Each of the pair of side belt assemblies includes a side conveyor belt positioned between the lower conveyor belt and the upper conveyor belt. At least one of the side conveyor belts includes a non-vertical portion.

Abstract: An optical recording medium, comprises a substrate, an imaging composition disposed on said substrate, said compound comprising: a matrix, a color-forming agent, and a nucleating agent. The nucleating agent increases the nucleation density of at least one component of the color-forming agent.

Abstract: An optical recording medium, comprises a substrate, an imaging composition disposed on said substrate, said compound comprising: a matrix, a color-forming agent, and a nucleating agent. The nucleating agent increases the nucleation density of at least one component of the color-forming agent.

Abstract: An optical recording medium, comprises a substrate, an imaging composition disposed on said substrate, said compound comprising: a matrix, a color-forming agent, and a nucleating agent. The nucleating agent increases the nucleation density of at least one component of the color-forming agent.

Abstract: A foam polymer jacketed rigid strength member for a fiber optic cable is disclosed, as is the method for its production. The foam jacket is made by feeding into an extruder a base polymer material, preferably a resin, such as polypropyene. The base material is melted in the extruder and a blowing agent is admixed. As the mixture exits the extruder, the polymer is expanded into a cellular foam. The polymer is foamed onto a rigid strength member by means of a crosshead. The resulting jacketed rigid strength member demonstrates improved resistance to thermal contractions reducing the contribution of stresses in the fiber optic cable components.

Abstract: A foam polymer jacketed rigid strength member for a fiber optic cable is disclosed, as is the method for its production. The foam jacket is made by feeding into an extruder a base polymer material, preferably a resin, such as polypropyene. The base material is melted in the extruder and a blowing agent is admixed. As the mixture exits the extruder, the polymer is expanded into a cellular foam. The polymer is foamed onto a rigid strength member by means of a crosshead. The resulting jacketed rigid strength member demonstrates improved resistance to thermal contraction, reducing the contribution of stresses in the fiber optic cable components.

Abstract: A series of marks on an optical disc are sampled to yield a series of data pulses. The marks are at least substantially angularly equidistant to one another on the optical disc. A function is performed on the series of data pulses to yield an error-corrected series of data pulses. The function is one of: frequency domain filtering, signal averaging, and signal integration.

Abstract: An optical recording medium, comprises a substrate, an imaging composition disposed on said substrate, said compound comprising: a matrix, a color-forming agent, and a nucleating agent. The nucleating agent increases the nucleation density of at least one component of the color-forming agent.

Abstract: A method of controlling flow includes treating a region of a surface to have a non-wettable surface characteristic or a wettable surface characteristic in the region.

Abstract: A process for producing an optical fiber cable composite structural component, such as reinforcing members, buffer tubes, filler rods, jackets, and slotted cores, is disclosed. The composite structural components are produced by co-extruding a thermotropic liquid crystalline polymer (TLCP) and a thermoplastic matrix material into the composite structural component so that TLCP reinforcing fibrils are dispersed in the thermoplastic matrix material. The TLCP reinforcing fibrils undergo a high level of process induced orientation, are provided with a high aspect ratio, and small diameters. The composite structural component has a high modulus. The TLCP reinforcing fibrils may be made continuous or discontinuous.

Abstract: A light system to be installed under branches of a tree, particularly under the fronds of a palm tree. The system involves a flexible multiple bulb light rod or a continuous string of lights. A lower end of the light rod is installed to a trunk of a tree by way of a bracket. The upper end of the flexible light rod has one end of a cord attached thereto. The cord is passed along the light rod by way of hooks attached thereon. By pulling at the other free end of the cord the flexible light rod will be bent downwardly to simulate the curvature of a branch on the tree without being attached thereto. The free end of the cord is then tied to a lower end of the bracket. The support rod for the lighting string may be supported on both ends on individual columns to form an arch.

Abstract: The present invention adds a gel-swellable layer in fiber optic cables to aid in protecting the fibers within the cable. The gel-swellable layer can be placed on the fibers, individual ribbons, stacks of ribbons and on the inner surface of tubes by various methods, such as co-extrusion, and can be cured by either heat curing or UV curing. The gel-swellable layers of this invention can be either smooth or textured. When the fibers are placed into the tubes and the tubes are filled with the water resistant gel, the gel-swellable layer absorbs some of the gel causing it to “swell”. As a result of the “swelling” a certain volume of gel is absorbed by the layer, thus reducing the capability of the gel to flow at elevated temperatures.

Abstract: A fiber optic cable is provided with an outer jacket material having a coefficient of thermal expansion less than approximately 6E?5 in the range from 23° C. to ?50° C. By utilizing an outer jacket material having a reduced coefficient of thermal expansion, the need for rigid strength members within the outer jacket is eliminated, thereby providing a fiber optic cable having a reduced size and weight.

Abstract: The present invention adds a gel-swellable layer in fiber optic cables to aid in protecting the fibers within the cable. The gel-swellable layer can be placed on the fibers, individual ribbons, stacks of ribbons and on the inner surface of tubes by various methods, such as co-extrusion, and can be cured by either heat curing or UV curing. The gel-swellable layers of this invention can be either smooth or textured. When the fibers are placed into the tubes and the tubes are filled with the water resistant gel, the gel-swellable layer absorbs some of the gel causing it to “swell”. As a result of the “swelling” a certain volume of gel is absorbed by the layer, thus reducing the capability of the gel to flow at elevated temperatures.

Abstract: The present invention adds a gel-swellable layer in fiber optic cables to aid in protecting the fibers within the cable. The gel-swellable layer can be placed on the fibers, individual ribbons, stacks of ribbons and on the inner surface of tubes by various methods, such as co-extrusion, and can be cured by either heat curing or UV curing. The gel-swellable layers of this invention can be either smooth or textured. When the fibers are placed into the tubes and the tubes are filled with the water resistant gel, the gel-swellable layer absorbs some of the gel causing it to “swell”. As a result of the “swelling” a certain volume of gel is absorbed by the layer, thus reducing the capability of the gel to flow at elevated temperatures.

Abstract: A fiber optic cable is provided with an outer jacket material having a coefficient of thermal expansion less than approximately 6E-5 in the range from 23° C. to −50° C. By utilizing an outer jacket material having a reduced coefficient of thermal expansion, the need for rigid strength members within the outer jacket is eliminated, thereby providing a fiber optic cable having a reduced size and weight.

Abstract: An optical fiber telecommunication cable including a sheath and at least one optical fiber is provided. The sheath encloses at least one optical fiber, and a hydrogen absorbing composition is disposed between the sheath and the at least one optical fiber. The hydrogen absorbing composition includes an oil, a thixotropic agent, an oxidant system and a carbon nanostructure component, wherein the carbon nanostructure component is hydrogen absorbent.

Abstract: An optical fiber cable including a buffer tube wherein the optical unit is maintained in an axial center location of the buffer tube and protected from contact with an inner wall of the buffer tube. At least first and second gel layers are interposed between the buffer tube and the optical unit, wherein the first gel layer surrounds the optical unit, the second gel layer surrounds the first gel layer, and the first and second gel layers have different rheological properties. The inner gel layer may have a yield stress and a viscosity which are lower than a yield stress and a viscosity of the outer gel layer. The lower yield stress and viscosity of the inner gel layer serves to maintain the optical unit in an axial center position within the buffer tube and facilitates easy re-positioning of the optical unit to the axial center position when the buffer tube is flexed or bent. As a result, the optical unit may be maintained in a low stress state and stress-induced attenuation may be prevented.

Abstract: The present invention is directed to a novel construction of buffer tubes for fiber optic cables which offers a way to access the optical fibers inside a buffer tube while reducing the risk of damaging the fibers, as sometimes occurs when cutting the outer layer of the buffer tube. A buffer tube for use in a fiber optic cable of the present invention comprises a tube having a tube wall, the wall having an inside and outside surface, wherein an inner portion of tube wall, nearest the inside surface, is made of a material having a higher notch-sensitivity than an outer portion of the tube wall nearest the outside surface.

Abstract: Fiber optic cable containing optical fibers and a silicone waterblocking gel for low temperature applications. The silicone waterblocking gel has an extremely low crystalline melting point and may be used in low temperature environments since it does not experience low temperature attenuation caused by crystallization of the base oil at temperatures below about −45° C. Examples of the waterblocking silicone gel are poly(alkyl)(aryl)siloxane and mono or polyhalogenatedsiloxane.