权利要求:
CLAIMS
I Claim:
1. A wearable cooling system comprising:
• a garment insert configured to be worn across a dermal surface and comprising: o a textile panel defining:
■ an inner surface configured to contact the dermal surface;
■ an outer surface opposite the inner surface; and
■ a set of grid receptacles, each grid receptacle, in the set of grid receptacles, extending between the inner surface and the outer surface; and o a set of grid structures, each grid structure, in the set of grid structures, arranged within and spanning a grid receptacle, in the set of grid receptacles, and defining:
■ an inner face facing the inner surface of the textile panel;
■ an outer face opposite the inner face and facing the outer surface of the textile panel; and
■ a grid array of apertures arranged in a first pattern and extending between the inner face and the outer face of the grid structure;
• a set of cooling units, each cooling unit in the set of cooling units: o configured to transiently mate with a grid structure, in the set of grid structures, to seat within a corresponding grid receptacle in the set of grid receptacles; and o comprising a heatsink structure:
■ defining:
• a base section defining an interior surface configured to contact the dermal surface; and
• a set of heatsink columns: o extending from the base section opposite the interior surface; o arranged in a second pattern corresponding to the first pattern; and o each heatsink column, in the set of heatsink columns, configured to seat extending through an aperture, in the grid array of apertures; and
configured to wick moisture from the dermal surface toward surfaces of the set of heatsink columns to cool the dermal surface.
2. The wearable cooling system of Claim 1, wherein each cooling unit, in the set of cooling units, further comprises a polymer frame:
• bonded to the heatsink structure and arranged about a perimeter of the base section; and
• configured to abut surfaces of the base section to surfaces of the grid receptacle to flexibly retain the cooling unit within the grid receptacle in an assembled configuration.
3. The wearable cooling system of Claim 2:
• wherein the polymer frame: o is formed of a flexible material exhibiting a glass transition temperature less than a threshold temperature; and o defines a first cross-section corresponding to a second cross-section of the grid receptacle and is configured to nest within the grid receptacle to locate the cooling unit within the assembled configuration.
4. The wearable cooling system of Claim 1, wherein the cooling unit is configured to insert into the grid array of apertures, from the inner face of the grid structure, to transiently seat the base section against the inner face of the grid structure within the grid receptacle and locate the interior surface of the base section approximately flush the inner surface of the textile panel in an assembled configuration.
5. The wearable cooling system of Claim 1, wherein the heatsink structure comprises:
• a substrate defining: o the base section and the set of heatsink columns defining an exterior surface of the heatsink structure; and o an open network of pores extending between the interior surface and the exterior surface; and
• a coating: o formed of a porous, hydrophilic material; o extending across the interior surface of the substrate; o lining the open network of pores;
o defining a void network configured to filter hydrophobic molecules; and o configured to cooperate with the substrate to wick moisture from the dermal surface, through the void network lining the open network of pores, and to the exterior surface, to cool the heat source.
6. The wearable cooling system of Claim 5:
• wherein the grid structure is formed of a silicone material and configured to contour about the dermal surface;
• wherein the substrate is formed of a graphite material exhibiting a target conductivity and a target durability;
• wherein the coating is formed of a cementitious mixture of water and cement; and
• wherein each cooling unit, in the set of cooling units, further comprises a polymer frame: o formed of a polycaprolactone material and exhibiting a target flexibility; o bonded to the heatsink structure and arranged about a perimeter of the base section; and o configured to abut surfaces of the base section to surfaces of the grid receptacle to flexibly retain the cooling unit within the grid receptacle in an assembled configuration.
7. The wearable cooling system of Claim 1:
• wherein the garment insert is integrated into a headband configured to be worn across a forehead of a human user;
• wherein the inner surface of the textile panel is configured to contact the forehead; and
• wherein the heatsink structure is configured to wick moisture from the forehead toward surfaces of the set of heatsink columns to cool the human user.
8. The wearable cooling system of Claim 1:
• wherein the garment insert is integrated into an armband configured to be worn across a forearm of a human user;
• wherein the inner surface of the textile panel is configured to contact the forearm; and
• wherein the heatsink structure is configured to wick moisture from the forearm toward surfaces of the set of heatsink columns to cool the human user.
9. The wearable cooling system of Claim 1:
• wherein the set of grid structures comprises: o a first grid structure:
■ spanning a first grid receptacle in the set of grid receptacles;
■ defining a first inner face facing the inner surface of the textile panel;
■ defining a first outer face opposite the first inner face and facing the outer surface of the textile panel; and
■ defining a first grid array of apertures arranged in the first pattern; o a second grid structure:
■ spanning a second grid receptacle in the set of grid receptacles;
■ defining a second inner face facing the inner surface of the textile panel;
■ defining a second outer face opposite the second inner face and facing the outer surface of the textile panel; and
■ defining a second grid array of apertures arranged in the first pattern; and
• wherein the set of cooling units comprises: o a first cooling unit transiently seated within the first grid receptacle, mated with the first grid structure, during a first time period; and o a second cooling unit transiently seated within the second grid receptacle, mated with the second grid structure, during the first time period.
10. The wearable cooling system of Claim 1:
• wherein the set of grid structures comprises a first grid structure: o spanning a first grid receptacle in the set of grid receptacles; o defining a first inner face facing the inner surface of the textile panel; o defining a first outer face opposite the first inner face and facing the outer surface of the textile panel; and o defining a first grid array of apertures arranged in the first pattern; and
• wherein the set of cooling units comprises: o a first cooling unit transiently seated within the first grid receptacle, mated with the first grid structure, during a first time period; and o a second cooling unit transiently seated within the first grid receptacle, mated with the first grid structure, during a second time period succeeding the first time period.
11. The wearable cooling system of Claim 1:
• wherein the set of grid structures comprises: o a first grid structure:
■ spanning a first grid receptacle in the set of grid receptacles;
■ defining a first inner face facing the inner surface of the textile panel;
■ defining a first outer face opposite the first inner face and facing the outer surface of the textile panel; and
■ defining a first grid array of apertures arranged in the first pattern; o a second grid structure:
■ spanning a second grid receptacle in the set of grid receptacles;
■ defining a second inner face facing the inner surface of the textile panel;
■ defining a second outer face opposite the second inner face and facing the outer surface of the textile panel; and
■ defining a second grid array of apertures arranged in the first pattern; and
• wherein the set of cooling units comprises a first cooling unit transiently configured to: o transiently seat within the first grid receptacle, mated with the first grid structure, during a first time period; and o transiently seat within the second grid receptacle, mated with the second grid structure, during a second time period succeeding the first time period.
12. The wearable cooling system of Claim i, wherein the set of cooling units comprises a first cooling unit comprising a first heatsink structure:
• comprising a first base section defining a first interior surface configured to contact the dermal surface;
• comprising a first set of heatsink columns: of a first size: o of a first size; o extending from the first base section opposite the first interior surface; o arranged in the second pattern; and o each heatsink column, in the first set of heatsink columns, configured to seat extending through an aperture in the grid array of apertures; and
• configured to wick moisture from the dermal surface toward surfaces of the first set of heatsink columns to cool the dermal surface at a first rate corresponding to the first size.
13- The wearable cooling system of Claim 12, wherein the set of cooling units comprises a second cooling unit comprising a second heatsink structure:
• comprising a second base section defining a second interior surface configured to contact the dermal surface;
• comprising a second set of heatsink columns of a second size, exceeding the first size, and: o extending from the second base section opposite the second interior surface; o arranged in the second pattern; and o each heatsink column, in the second set of heatsink columns, configured to seat extending through an aperture in the grid array of apertures; and
• configured to wick moisture from the dermal surface toward surfaces of the second set of heatsink columns to cool the dermal surface at a second rate corresponding to the second size, the second rate exceeding the first rate.
14. The wearable cooling system of Claim 1:
• further comprising: o a water supply configured to transiently store a volume of water; and o a set of fluid channels:
■ fluidly coupled to the water supply; and
■ extending through the set of grid structures; and
• wherein each grid structure, in the set of grid structures, defines an array of pores configured to transientlyrelease water from fluid channels, in the set of fluid channels, extending through the grid structure, toward surfaces of a cooling unit, in the set of cooling units, mated with the grid structure to wet the set of heatsink structures.
15. Awearable cooling system comprising:
• a garment insert, integrated into a garment, configured to be worn across a dermal surface, and comprising: o a textile panel defining:
■ an inner surface configured to contact the dermal surface;
■ an outer surface opposite the inner surface; and
■ a first grid receptacle extending between the inner surface and the outer surface; and o a first grid structure:
■ arranged within and spanning the first grid receptacle; and
■ defining:
• an inner face facing the inner surface of the textile panel;
• an outer face opposite the inner face and facing the outer surface of the textile panel; and
• a grid array of apertures arranged in a first pattern coplanar the first grid receptacle; and
• a first cooling unit comprising: o a first heatsink structure:
■ defining:
• a base section defining an interior surface configured to contact the dermal surface; and
• a set of heatsink columns: o extending from the base section; o arranged in a second pattern corresponding to the first pattern; and o each heatsink column, in the set of heatsink columns, configured to seat extending through an aperture, in the grid array of apertures; and
■ configured to wick moisture from the dermal surface toward surfaces of the set of heatsink columns; and o a first polymer frame:
■ rigidly coupled to the first heatsink structure and arranged about the base section; and
■ configured to abut surfaces of the base section to surfaces of the first grid receptacle to flexibly retain the first cooling unit within the first grid receptacle in an assembled configuration.
16. The wearable cooling system of Claim 15:
• wherein the first grid receptacle is formed of a silicone material configured to contour about the dermal surface;
• wherein the first heatsink structure comprises: o a substrate:
■ formed of a conductive material;
■ defining the base section and the set of heatsink columns defining an exterior surface of the heatsink structure; and
■ defining an open network of pores extending between the interior surface and the exterior surface; and o a coating:
■ formed of a porous, hydrophilic material;
■ extending across the interior surface of the substrate;
■ lining the open network of pores;
■ defining a void network configured to filter hydrophobic molecules; and
■ configured to cooperate with the substrate to wick moisture from the dermal surface, through the void network lining the open network of pores, and to the exterior surface, to cool the heat source; and
• wherein the polymer frame is formed of a polymer material exhibiting a target flexibility.
17. The wearable cooling system of Claim 15:
• wherein the textile panel defines a second grid receptacle extending between the inner surface and the outer surface;
• wherein the garment insert comprises a second grid structure: o arranged within and spanning the second grid receptacle; and o defining:
■ a second inner face facing the inner surface of the textile panel and coplanar the inner face;
■ a second outer face opposite the second inner face and facing the outer surface of the textile panel; and
■ a second grid array of apertures arranged in the first pattern and coplanar the second grid receptacle;
• further comprising a second cooling unit comprising: o a second heatsink structure:
■ defining:
• a second base section defining a second interior surface configured to contact the dermal surface; and
• a second set of heatsink columns: o extending from the second base section;
o arranged in the second pattern corresponding to the first pattern; and o each heatsink column, in the second set of heatsink columns, configured to seat extending through an aperture, in the second grid array of apertures; and
■ configured to wick moisture from the dermal surface toward surfaces of the second set of heatsink columns; and
• a second polymer frame: o rigidly coupled to the second heatsink structure and arranged about the second base section; and o configured to abut surfaces of the second base section to surfaces of the second grid receptacle to flexibly retain the second cooling unit within the second grid receptacle in the assembled configuration.
18. The wearable cooling system of Claim 15:
• wherein the first cooling unit is configured to mate with the first grid structure to seat within the first grid receptacle during a first time period; and
• further comprising a second cooling unit comprising: o a second heatsink structure:
■ defining:
• a second base section defining an inner surface configured to contact the dermal surface; and
• a second set of heatsink columns: o extending from the second base section; o arranged in the second pattern corresponding to the first pattern; and o each heatsink column, in the second set of heatsink columns, configured to seat extending through an aperture, in the grid array of apertures;
■ configured to wick moisture from the dermal surface toward surfaces of the set of heatsink columns; and
■ configured to mate with the first grid structure to seat within the first grid receptacle during a second time period succeeding the first time period; and a second polymer frame:
o rigidly coupled to the second heatsink structure and arranged about the second base section; and o configured to abut surfaces of the second base section to surfaces of the second grid receptacle to flexibly retain the second cooling unit within the second grid receptacle in the assembled configuration.
19. A wearable cooling system comprising:
• a garment insert configured to be worn across a dermal surface and comprising: o a textile panel defining:
■ an inner surface configured to contact the dermal surface;
■ an outer surface opposite the inner surface; and
■ a grid receptacle extending between the inner surface and the outer surface; and o a grid structure:
■ arranged within and spanning the grid receptacle; and
■ defining:
• an inner face facing the inner surface of the textile panel;
• an outer face opposite the inner face and facing the outer surface of the textile panel; and
• a grid array of apertures arranged in a first pattern coplanar the grid receptacle; and
• a cooling unit comprising: o a heatsink structure comprising:
■ a substrate defining:
• a base section defining an interior surface configured to contact the dermal surface;
• a set of heatsink columns: o extending from the base section opposite the interior surface; o defining an exterior surface; o arranged in a second pattern corresponding to the first pattern; and o configured to seat extending through the grid array of apertures in an assembled configuration; and
an open network of pores extending between the interior surface and the exterior surface; and
■ a coating:
• formed of a hydrophilic material;
• extending across the interior surface of the substrate and lining the open network of pores;
• defining a void network; and
• configured to cooperate with the substrate to wick moisture from the dermal surface, through the void network lining the open network of pores, and to the exterior surface, to cool the dermal surface; and o a polymer frame:
■ rigidly coupled to the heatsink structure and arranged about the base section; and
■ configured to abut surfaces of the base section to surfaces of the grid receptacle to flexibly retain the cooling unit within the grid receptacle in the assembled configuration.
20. The wearable cooling system of Claim 19:
• wherein the textile panel defines a second grid receptacle extending between the inner surface and the outer surface;
• wherein the garment insert is integrated into a garment and comprises a second grid structure: o arranged within and spanning the second grid receptacle; and o defining:
■ a second inner face facing the inner surface of the textile panel;
■ a second outer face opposite the second inner face and facing the outer surface of the textile panel; and
■ a second grid array of apertures arranged in the first pattern coplanar the second grid receptacle; and
• a second cooling unit comprising: o a second heatsink structure comprising:
■ a second substrate defining:
• a second base section defining a second interior surface configured to contact the dermal surface;
a second set of heatsink columns: o extending from the second base section opposite the second interior surface; o defining a second exterior surface; o arranged in the second pattern corresponding to the first pattern; and o configured to seat extending through the second grid array of apertures in the assembled configuration; and
• a second open network of pores extending between the second interior surface and the second exterior surface; and
■ a second coating:
• formed of the hydrophilic material;
• extending across the second interior surface of the second substrate and lining the second open network of pores;
• defining a second void network; and
• configured to cooperate with the second substrate to wick moisture from the dermal surface, through the second void network lining the second open network of pores, and to the second exterior surface, to cool the dermal surface; andcond polymer frame:
■ rigidly coupled to the second heatsink structure and arranged about the second base section; and
■ configured to abut surfaces of the second base section to surfaces of the second grid receptacle to flexibly retain the second cooling unit within the second grid receptacle in the assembled configuration.