The present invention provides a heating device and a method for manufacturing a heated molding material. The method uses the heating device to continuously manufacture the heated molding material. The heating device includes a heating chamber for heating a molding material, at least one opening section for feeding or expelling molding material therethrough, and a means for using nitrogen gas or superheated steam to expel oxygen gas present in the heating chamber.

A melting kettle for processing of thermoplastic material. The kettle disclosed herein obtains heat transfer by use of an oil jacketed tank with an adjoining main tank for storage of hot oil and a hose tank for recovery of the hot oil. Oil expelled from the oil jacket is directed to the main tank through an opening. Spillage of oil from the hose tank is directed to the main tank through an aperture. The melting kettle reduces the space needed for oil storage, and increases operator safety by eliminating additional transfer lines. Dual kettles benefit by having the adjoining main tank placed therebetween.

Melting kettles for use on vehicles for continuous processing of material for applying lines, stripes, bitumen, crack sealant or the like. The kettles disclosed herein provide heat transfer by use of oil jacketed tanks. A coil may be placed along a lower section for heat transfer through a burner for heating recirculated oil. A coil may be placed in a lower section and an upper section for heating an oil jacket, as well as heat transfer from the entire circumference of a coil placed in the upper section. An upper coil can be fluidly coupled to a lower coil and positioned within the chamber a spaced apart distance from the interior wall of the melter kettle. A mixer system rotates paddles to cause continuous transfer of material around the upper coil. The melter kettle is cylindrical, but can be corrugated to increase heatable surface area.

A soap melting assembly includes a chest that is comprised of a microwave safe material thereby facilitating the chest to be heated in a microwave oven. A lid is hingedly coupled to the chest for closing the chest and the lid is comprised of a microwave safe material. A drawer is slidably positioned in the lid and the drawer is comprised of a microwave safe material. A block is stored in the drawer and the block is comprised of glass. The block is removable from the drawer and positioned on the plurality of soap slivers when the chest becomes filled with the soap slivers. Thus, the block compresses the soap slivers into a single bar when the chest and the soap slivers are heated in the microwave oven.

A conveying device for conveying a pasty mass in the manufacture of insulating glass includes a carrier for a cylindrical container with pasty mass. A follow-up plate is arranged above the carrier and is vertically displaceable for placing on the pasty mass. A conveyor line is connected to the follow-up plate for further transport of the pasty mass. The follow-up plate has an underside and at least an outlet opening arranged in the follow-up plate for connection with the conveyor line. On the underside several downwardly projecting projections are arranged around the outlet opening which are configured to be immersed in the pasty mass. At least one of the projections is formed as a rib extending radially outwards along the underside of the follow-up plate.

The device for feeding molten plastic material into a molding cavity (30) includes a melting chamber (20) in which metered solid plastic material is introduced, a sonotrode (10) provided for tightly inserting a portion thereof into said melting chamber (20), causing the plastic material to melt by means of vibration, and relative movement of the sonotrode (10) and melting chamber (20) allows driving the molten plastic material inside a molding cavity (30) communicated with said melting chamber (20), the device including resistance sensors (40) allowing an electronic control device (50) to know the resistance that the plastic material has against the movement of the sonotrode (10).

A hot melt delivery system includes a frame and a suspension device attached to the frame. The suspension device is configured to hang a hot melt storage container. The hot melt delivery system includes a vibratory feeder spaced below and from the suspension device. The vibratory feeder includes an inlet that is configured to receive hot melt material from the hot melt storage container. The vibratory feeder includes an outlet that is configured to deliver hot melt material to a melter. The vibratory feeder includes a vibration device that is configured to vibrate at least a portion of the vibratory feeder. A flow of hot melt material between the inlet and the outlet of the vibratory feeder is controllable.

A melt system that includes a melt unit. The melt unit includes a reservoir and a melt grid disposed above the reservoir. The melt grid is configured to expose solid polymer to a temperature sufficient to form a molten polymer and to deposit the molten polymer into the reservoir. The melt unit includes at least one hopper for holding a supply of the solid polymer. The melt unit includes a thermal isolation region disposed below the hopper to thermally isolate the hopper from the molten polymer in the reservoir.

Certain aspects of the present disclosure provide techniques for performing, by a user equipment (UE), radio link monitoring based on discontinuous reception mode operation of the UE. Certain aspects provide a method for wireless communication. The method generally includes operating, at a user equipment (UE), in a discontinuous reception (DRX) mode of operation. The method further includes evaluating, by the UE, link quality between the UE and a base station (BS) at least once every time period, wherein the time period is based on a length of a DRX cycle of the UE operating in the DRX mode of operation and a reference signal (RS) period, wherein the BS is configured to transmit RS periodically every RS period.

A pavement striping devices for heating and applying thermoplastic material to a road surface is provided. The pavement striping device includes of: a hopper for holding a supply of particulate thermoplastic marking material in a non-molten state, an air or oil-heat transfer medium melting kettle having a series of coaxial conveyored or unconveyored conduits within, a plastic extruder for transporting the thermoplastic particulate from the hopper to the series of coaxial conveyored or unconveyored conduits with the air or oil-heat transfer medium melting kettle, a heating mechanism for heating the air or oil-heat transfer medium melting kettle and the plastic extruder to a temperature suitable for melting thermoplastic, and a means for driving the stream of molten thermoplastic through the series of coaxial conveyored or unconveyored conduits to a sprayer or extrusion die, all of which form a means by which the molten thermoplastic is directed to the pavement surface.