Flexible Interconnect Circuits for Battery Packs

1 . A flexible interconnect circuit for interconnecting batteries in a battery pack, the flexible interconnect circuit comprising: a first insulator layer forming a first edge and a second edge of the flexible interconnect circuit; a second insulator layer, stacked together with the first insulator layer; an interconnecting conductive layer comprising a first external terminal, a first conductive island, positioned proximate to the first edge, and a second conductive island, positioned proximate to the second edge, wherein: each of the first conductive island and the second conductive island is at least partially positioned between the first insulator layer and the second insulator layer and is used for forming direct mechanical and electrical connections to at least a portion of the batteries, and the first conductive island is electrically coupled to the first external terminal, positioned proximate to the first edge; and a return conductive layer comprising one or more bus bars and a second external terminal, wherein: each of the one or more bus bars extends between the first edge and the second edge, each of the one or more bus bars is configured to electrically couple to the second conductive island to form a return connection, positioned proximate to the second edge, and each of the one or more bus bars is electrically coupled to the second external terminal, positioned proximate to the first edge. 2 . The flexible interconnect circuit of claim 1 , further comprising a third insulator layer, wherein: the return conductive layer is at least partially positioned between the second insulator layer and the third insulator layer, and the second insulator layer is at least partially positioned between the return conductive layer and the interconnecting conductive layer and electrically insulates the return conductive layer and the interconnecting conductive layer away from the return connection. 3 . The flexible interconnect circuit of claim 2 , wherein each of the one or more bus bars and the second conductive island extend past an edge of the second insulator layer to directly interface with each other and form the return connection. 4 . The flexible interconnect circuit of claim 2 , wherein the first insulator layer and the third insulator layer are sealed against each other forming the second edge. 5 . The flexible interconnect circuit of claim 2 , wherein the second insulator layer comprises a return-connection opening such that a portion of the one or more bus bars extends through the return-connection opening forming the return connection, and the second insulator layer is sealed against each of the first insulator layer and the third insulator layer thereby collectively forming the second edge. 6 . The flexible interconnect circuit of claim 2 , wherein: each of the first conductive island and the second conductive island comprises contact-forming portions for forming electrical connections with the batteries, each of the first insulator layer, the second insulator layer, and the third insulator layer comprises insulator openings aligned with the contact-forming portions, and neither one of the one or more bus bars overlaps with the insulator openings. 7 . The flexible interconnect circuit of claim 1 , wherein the return conductive layer is positioned between the first insulator layer and the second insulator layer. 8 . The flexible interconnect circuit of claim 7 , wherein a portion of the flexible interconnect circuit, comprising the return conductive layer, is configured to bend relative to a portion of the flexible interconnect circuit, comprising the interconnecting conductive layer. 9 . The flexible interconnect circuit of claim 8 , wherein the portion of the flexible interconnect circuit, comprising the return conductive layer, is configured to bend relative to the portion of the flexible interconnect circuit, comprising the interconnecting conductive layer, to an angle of at least 90°. 10 . The flexible interconnect circuit of claim 1 , further comprising one or more additional conductive islands positioned between the first conductive island and the second conductive island. 11 . The flexible interconnect circuit of claim 1 , wherein each of the one or more bus bars is directly connected to the second conductive island to form the return connection, positioned proximate to the second edge. 12 . The flexible interconnect circuit of claim 1 , wherein each of the one or more bus bars is configured to electrically couple to the second conductive island through one or more of the batteries, to form the return connection, positioned proximate to the second edge. 13 . The flexible interconnect circuit of claim 1 , wherein the batteries are prismatic cells. 14 . The flexible interconnect circuit of claim 1 , wherein the batteries are cylindrical cells. 15 . The flexible interconnect circuit of claim 1 , further comprising an additional conductive layer stacked with and directly interfacing the interconnecting conductive layer. 16 . The flexible interconnect circuit of claim 15 , wherein the additional conductive layer and the interconnecting conductive layer have same thicknesses. 17 . The flexible interconnect circuit of claim 16 , wherein: each of the first conductive island and the second conductive island comprises contact-forming portions for forming electrical connections with the batteries, and the additional conductive layer extends over and is stacked with the contact-forming portions. 18 . The flexible interconnect circuit of claim 15 , wherein the additional conductive layer is thicker than the interconnecting conductive layer have same thicknesses. 19 . The flexible interconnect circuit of claim 15 , wherein the interconnecting conductive layer is formed from aluminum. 20 . The flexible interconnect circuit of claim 15 , wherein the interconnecting conductive layer has a thickness of at least 100 micrometers.