A melt system capable of heating hot melt pellets into a liquid includes a melter including a body, a chamber, a collector, channels, and a heater. The thermally conductive body forms an interior with a surface area. The chamber is at an upper end of the body for receiving the pellets. The collector
A melt system capable of heating hot melt pellets into a liquid includes a melter including a body, a chamber, a collector, channels, and a heater. The thermally conductive body forms an interior with a surface area. The chamber is at an upper end of the body for receiving the pellets. The collector is within the body and located below the chamber for receiving the liquid from the melted pellets. The channels extend between the chamber and the collector to increase the surface area of the interior, and the walls of the channels form heat exchange surfaces. The heater is for transferring heat to the body.
대표청구항▼
1. A melt system capable of heating hot melt pellets into a liquid, the melt system comprising: a melter comprising: a thermally conductive body forming an interior with a surface area;a chamber at an upper end of the body for receiving the pellets;a collector within the body and located below the c
1. A melt system capable of heating hot melt pellets into a liquid, the melt system comprising: a melter comprising: a thermally conductive body forming an interior with a surface area;a chamber at an upper end of the body for receiving the pellets;a collector within the body and located below the chamber for receiving the liquid from the melted pellets;a thermally conductive divider between the chamber and the collector, the divider defining a plurality of channels that extend between the chamber and the collector, wherein a plurality of walls of the plurality of channels form heat exchange surfaces wherein the divider has a surface-area-to-volume ratio that is greater than 4; anda first heater for transferring heat to the body, the first heater being positioned around the plurality of channels;a controller that causes the feed system to replenish the pellets in the melter; anda level sensor connected to the controller, the level sensor being configured to determine the melt level and send melt level data to the controller. 2. The melt system of claim 1, wherein the plurality of channels extends substantially vertically. 3. The melt system of claim 1, wherein the first heater located on an exterior of the body. 4. The melt system of claim 1, wherein the first heater is located on an exterior of the body, and the melt system further comprising: a second heater located on the interior of the body. 5. The melt system of claim 1, and further comprising: a base beneath the melter, the base including a basin that is fluidly connected to the collector and a base outlet that is fluidly connected to the basin. 6. A hot melt dispensing system comprising: a container for storing hot melt pellets;a thermally conductive melter capable of heating hot melt pellets into a liquid, the melter defining an interior and including: a divider located in the interior that has a plurality of channels defined by walls that act as heat exchange surfaces of the melter, wherein the divider has a surface-area-to-volume ratio that is greater than 4; anda first heater positioned around the melter for transferring heat to the plurality of channels;a feed system for transporting hot melt pellets from the container to the melter;a dispensing system for administering liquefied hot melt pellets from the melter;a controller that causes the feed system to replenish the pellets in the melter; anda level sensor connected to the controller, the level sensor being configured to determine the melt level and send melt level data to the controller. 7. The hot melt dispensing system of claim 6, wherein the melter further comprises: a chamber for receiving the pellets above the divider and fluidly connected to the plurality of channels; anda collector below of and fluidly connected to the plurality of channels. 8. The hot melt dispensing system of claim 6, wherein the plurality of channels extends substantially vertically. 9. The hot melt dispensing system of claim 6, wherein the first heater is located on an exterior of the melter for transferring heat to the melter. 10. The hot melt dispensing system of claim 6, and further comprising: a second heater located on the interior of the melter for transferring heat to the melter. 11. The melt system of claim 1, wherein a first volume of the chamber is approximately the same as a second volume of the plurality of channels. 12. The hot melt dispensing system of claim 6, and further comprising: a chamber at an upper end of the body for receiving the hot melt pellets;wherein a first volume of the chamber is approximately the same as a second volume of the plurality of channels. 13. The melt system of claim 3, wherein the first heater is secured around the body with a latch. 14. The hot melt dispensing system of claim 9, wherein the first heater is secured on the exterior of the melter with a latch. 15. The melt system of claim 1, wherein the divider has a surface-area-to-volume ratio of 4.59. 16. The melt system of claim 1, and further comprising: a base having disc-shaped ledge;wherein the body has a rim below the divider; andwherein the rim contacts the ledge to attach the melter to the base. 17. The melt system of claim 4, wherein the second heater is concentric with the first heater. 18. The melt system of claim 10, wherein the second heater is concentric with the first heater. 19. The melt system of claim 4, wherein the second heater extends through the first heater. 20. The melt system of claim 10, wherein the second heater extends through the first heater. 21. A hot melt dispensing system comprising: a container for storing hot melt pellets;a thermally conductive melter capable of heating hot melt pellets into a liquid, the melter defining an interior and including: a divider located in the interior that has a plurality of channels defined by walls that act as heat exchange surfaces of the melter, wherein an upper surface of the melt liquid in the melter represents a melt level of melt liquid in the melter; anda first heater positioned around the melter for transferring heat to the plurality of channels;a feed system for transporting hot melt pellets from the container to the melter;a dispensing system for administering the melt liquid from the melter; anda controller that causes the feed system to replenish the pellets in the melter to maintain the melt level to within twenty-five percent of a length of the divider from a top end of the plurality of channels. 22. The hot melt dispensing system of claim 21, and further comprising: a level sensor connected to the controller, the level sensor being capable of determining the melt level and sending melt level data to the controller.
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