Mobile mixing devices, mobile mixing systems, and related methods are provided. A mobile mixing device can include a frame and a mixing drum securable to the frame. The mixing drum can include a body that forms an internal cavity and can have a forward end and a bottom end. The mixing drum can also include a mouth at the forward end of the body that provides access to the internal cavity of the mixing drum. The mobile mixing device can include a heater support arm having a heater secured to an end of the heater support arm that is distal from the mixing drum. The mixing drum can be used to process cement material when the heater support arm is in a stow-away position or asphalt when the heater support arm is in a heating position with the heater facing into the mouth of the mixing drum.

Presented herein is a system for dispensing media within a trench. The system includes a carriage having a chassis supported on one or more wheels, and a hopper supported on the carriage. The hopper is configured to receive media through an opening and output the media through an outlet. The system also includes a churning device at an inner portion of the hopper configured to agitate the media within the hopper. The media exits the hopper into a chute that is configured to deposit the media within the trench. The system can also include at least one liquid dispenser configured to dispense the liquid on the media after the media has been deposited in the trench. In certain embodiments, the system can include at least one tamp configured to compress the media into the trench after deposition of the media and the liquid.

Presented herein is a system for dispensing media within a trench. The system includes a carriage having a chassis supported on one or more wheels, and a hopper supported on the carriage. The hopper is configured to receive media through an opening and output the media through an outlet. The system also includes a churning device at an inner portion of the hopper configured to agitate the media within the hopper. The media exits the hopper into a chute that is configured to deposit the media within the trench. The system can also include at least one liquid dispenser configured to dispense the liquid on the media after the media has been deposited in the trench. In certain embodiments, the system can include at least one tamp configured to compress the media into the trench after deposition of the media and the liquid.

A hand tool includes an elongated handle suitably sized and shaped for handling HMA, and an implement attached to a distal end of the elongated handle. Such an implement includes: a non-stick, asphalt-resistant top layer, and a metal core directly attached to the non-stick, asphalt-resistant top layer, and a non-stick, asphalt-resistant bottom layer directly attached to the metal core. Notably, the metal core is intercalated between the non-stick, asphalt-resistant top layer and the non-stick, asphalt-resistant bottom layer. Advantageously, each of the non-stick, asphalt-resistant top layer and the non-stick, asphalt-resistant bottom layer prohibits hot mix asphalt from adhering onto the implement.

The present invention provides an improved heated hose for use with asphalt pavement repair machines that includes a flexible exterior cylindrical insulated hose portion with an inner cylindrical surface defining an inner cylindrical region, and a flexible metal sheath deployed coaxially in this region having an exterior surface, the surfaces defining an area through which hot asphalt flows. A heating element may be removably deployed inside and along the length of the coaxial metal sheath. Hot asphalt flowing through the hose between the inner cylindrical surface of the hose and the exterior surface of the coaxial metal sheath is kept hot by the conduction of heat from the heating element inside the flexible metal sheath. One end of the heating element extends to a far end of the inside of the sheath, and the other end of the heating element is accessible from outside of the near end of the hose, making it possible to easily remove and replace the heating element in the event of a failure. A novel connecting block is provided where the hose connects to the heating machine providing a passageway for the sheath that allows for removal and replacement of the heating element, while also providing a passageway that allows hot asphalt to enter into the hose around the sheath.

The present invention provides an improved heated hose for use with asphalt pavement repair machines that includes a flexible exterior cylindrical insulated hose portion with an inner cylindrical surface defining an inner cylindrical region, and a flexible metal sheath deployed coaxially in this region having an exterior surface, the surfaces defining an area through which hot asphalt flows. A heating element may be removably deployed inside and along the length of the coaxial metal sheath. Hot asphalt flowing through the hose between the inner cylindrical surface of the hose and the exterior surface of the coaxial metal sheath is kept hot by the conduction of heat from the heating element inside the flexible metal sheath. One end of the heating element extends to a far end of the inside of the sheath, and the other end of the heating element is accessible from outside of the near end of the hose, making it possible to easily remove and replace the heating element in the event of a failure. A novel connecting block is provided where the hose connects to the heating machine providing a passageway for the sheath that allows for removal and replacement of the heating element, while also providing a passageway that allows hot asphalt to enter into the hose around the sheath.

A portable dispensing device for dispensing a crack sealant, comprises an outer housing, a melting kettle for holding crack sealant to be melted, a guide mechanism in the housing below the kettle for positioning a burner below the kettle, a burner assembly removably mounted in an air gap between the outer housing and the melting kettle using the guide mechanism, the removable burner assembly configured to direct a flame against a surface of the melting kettle, a control valve fluidly connected to the melting kettle to dispense melted crack sealant, and a handle assembly for manually moving the portable dispensing device.

A portable dispensing device for dispensing a crack sealant, comprises an outer housing, a melting kettle for holding crack sealant to be melted, a guide mechanism in the housing below the kettle for positioning a burner below the kettle, a burner assembly removably mounted in an air gap between the outer housing and the melting kettle using the guide mechanism, the removable burner assembly configured to direct a flame against a surface of the melting kettle, a control valve fluidly connected to the melting kettle to dispense melted crack sealant, and a handle assembly for manually moving the portable dispensing device.

A method produces a composite material using a mixing system. The composite material comprises at least one aggregate, e.g. rock and/or glass, and the reaction product of a two-component polymeric binder composition comprising a first component, e.g. an isocyanate component, and a second component, e.g. an isocyanate-reactive component. The mixing system includes a mixing apparatus. The method includes the step of providing the aggregate, the first component and the second component into the mixing apparatus. The method further includes the step of mixing the first and second components to produce the reaction product of the two-component polymeric binder composition, and the step of applying the reaction product of the two-component polymeric binder composition to the aggregate within the mixing apparatus to produce the composite material. The composite material can be used for forming a paved structure, such as a sidewalk or a roadway.

Provided herein are roadways containing polyurethane materials. A roadway includes a base layer of a compacted in situ material and/or a wear layer disposed on the base layer. One or both of these layers may include the polyurethane material to bind other components in the layers and to form more robust and durable roadway structures capable of withstanding operating loads of the roadway. In some embodiments, the polyurethane material is added to the wear layer by mixing in situ soil and/or foreign aggregate with polyurethane material or by dispensing the polyurethane material over the existing partially formed wear layer. The base layer may or may not include a polyurethane material. The type, concentration, distribution, and processing of the polyurethane material in the wear layer may be the same or different than that in the base layer.