Adhesive dispensing device having optimized cyclonic separator unit

What is claimed is: 1 . An adhesive dispensing device comprising: a heater unit adapted to melt and heat adhesive material to an elevated application temperature; a receiving space defined by at least one sidewall and a top wall having an inlet aperture, said receiving space positioned to feed adhesive material through said heater unit, and said receiving space defining a first horizontal cross-sectional area; and a cyclonic separator unit coupled to said at least one sidewall of said receiving space, said cyclonic separator unit including a generally cylindrical pipe including a top end, a bottom end, and an interior surface extending from said top end to said bottom end, said generally cylindrical pipe including defining a second horizontal cross-sectional area along an entire length of said generally cylindrical pipe that is less than the first horizontal cross-sectional area of said receiving space, and said bottom end connected in fluid communication with said receiving space, said cyclonic separator unit further including a tangential inlet pipe coupled to the generally cylindrical pipe proximate to said top end, and an exhaust pipe configured to exhaust air flowing into said generally cylindrical pipe and said receiving space, said generally cylindrical pipe being adapted to receive a flow of air and adhesive pellets through said tangential inlet pipe to cause a spiral flow of air and adhesive pellets along said interior surface between said top and bottom ends, such that the air and adhesive pellets frictionally engage said interior surface, thereby decelerating the flow of air and adhesive pellets to a lower non-zero speed before deposit within the receiving space, said cyclonic separator unit decelerating the flow of air and adhesive pellets without directly opposing gravitational forces applied to the adhesive pellets, and said cyclonic separator unit including no significantly tapered sidewall portions such that said cyclonic separator unit presents an unrestricted flow path between said top and bottom ends to thereby prevent buildup of splashed adhesive from said receiving space and prevent buildup of adhesive caused by directly opposing gravitational forces applied to adhesive pellets during deceleration. 2 . The adhesive dispensing device of claim 1 , further comprising: a reservoir for receiving the adhesive material from said heater unit; a pump for directing the adhesive material from said reservoir out of the adhesive dispensing device; and a level sensor having an electrically driven electrode mounted along said at least one sidewall of said receiving space such that the amount of adhesive material in said receiving space is detected by a change in dielectric capacitance from said electrically driven electrode to a ground located at said at least one sidewall of said receiving space, said level sensor accurately and rapidly sensing when the adhesive material is removed from said receiving space such that additional adhesive material can be delivered to said receiving space and to said heater unit through said cyclonic separator unit to avoid emptying said receiving space and said reservoir during periods of high adhesive flow. 3 . The adhesive dispensing device of claim 1 , wherein said generally cylindrical pipe further includes a sidewall opening in said interior surface proximate to said top end, and said tangential inlet pipe is coupled to said generally cylindrical pipe at said sidewall opening. 4 . The adhesive dispensing device of claim 1 , wherein said cyclonic separator unit further comprises: a cyclone cap engaged with said top end of said generally cylindrical pipe and including said exhaust pipe and said tangential inlet pipe, said cyclone cap being removable as a unit with said exhaust pipe and said tangential inlet pipe to provide access into said generally cylindrical pipe. 5 . The adhesive dispensing device of claim 4 , wherein said cyclone cap includes a projecting flange defining a retention lip groove, and said generally cylindrical pipe includes at least one retention clip configured to snap into engagement with said projecting flange at said retention lip groove to retain said cyclone cap in position relative to said generally cylindrical pipe. 6 . The adhesive dispensing device of claim 1 , wherein said generally cylindrical pipe encloses an interior cylindrical space including an inner central space portion aligned with said exhaust pipe and an outer annular space portion surrounding said inner central space portion, and said outer annular space portion receives spiraling flow of air and adhesive pellets moving from said tangential inlet pipe to said bottom end while said inner central space portion receives exhaust flow of air moving from said bottom end to said top end. 7 . The adhesive dispensing device of claim 1 , wherein said tangential inlet pipe is positioned to cause rotating flow of air and adhesive pellets initially around said exhaust pipe. 8 . The adhesive dispensing device of claim 1 , wherein said exhaust pipe defines a flow cross section and is configured to receive at least a portion of an air filter adapted to filter exhaust air flow from said generally cylindrical pipe, and said exhaust pipe further includes a metal screen located adjacent to the portion of the air filter when inserted into said exhaust pipe, said metal screen extending across said flow cross section such that exhaust air flow must pass through said metal screen before passing through the air filter. 9 . The adhesive dispensing device of claim 1 , wherein said generally cylindrical pipe defines an inner diameter that remains constant from said top end to said bottom end. 10 . The adhesive dispensing device of claim 1 , wherein said receiving space is defined by a hopper including said at least one sidewall. 11 . A method for supplying adhesive pellets to a receiving space defining a first horizontal cross-sectional area in an adhesive dispensing device, the method comprising: delivering a flow of air and adhesive pellets through an inlet hose into a tangential inlet pipe of a cyclonic separator unit coupled to the receiving space; delivering the flow of air and adhesive pellets through the tangential inlet pipe and into a generally cylindrical pipe of the cyclonic separator unit so as to produce a spiral flow of air and adhesive pellets rotating about an interior surface of the generally cylindrical pipe, the generally cylindrical pipe defining a second horizontal cross-sectional area along an entire length of the generally cylindrical pipe that is less than the first horizontal cross-sectional area; decelerating the flow of air and adhesive pellets by frictionally contacting the air and adhesive pellets with the interior surface of the generally cylindrical pipe as the air and adhesive pellets rotate in the spiral flow, the decelerating of the flow of air and adhesive pellets being performed without directly opposing gravitational forces applied to the adhesive pellets, the cyclonic separator unit including no significantly tapered sidewall portions such that the cyclonic separator unit presents an unrestricted flow path to thereby prevent buildup of splashed adhesive from the receiving space and prevent buildup of adhesive caused by directly opposing gravitational forces applied to adhesive pellets during deceleration; and depositing the adhesive pellets into the receiving space directly from the generally cylindrical pipe, the adhesive pellets spreading out into the first horizontal cross-sectional area of the receiving space after deposit from the generally cylindrical pipe. 12 . The method of claim 11 , wherein the cycl