Systems and method for pushing a busbar against a battery cell using magnetic force

What is claimed is: 1. A contactless welding system, comprising: a magnet disposed on a first side of a battery cell, wherein the first side of the battery cell is arranged opposite a second side of the battery cell, and wherein the magnet emits a magnetic field that causes a magnetic force to be applied to a tab for the battery cell; a laser welder disposed on the second side of the battery cell, the laser welder configured to weld, via a laser beam emitted from the laser welder, the tab to a terminal disposed on the second side of the battery cell; a controller, configured to: send a control signal to an actuator and move a position of the magnet relative to the battery cell producing the force that causes the tab to come into physical contact with the terminal of the battery cell without touching the tab or the terminal of the battery cell with the magnet or other physical member; and while the magnetic force causes the tab to come into physical contact with the terminal of the battery cell, activate the laser welder to weld the tab to the terminal of the battery cell from the second side of the battery cell, via the laser beam emitted from the laser welder. 2. The contactless welding system of claim 1 , wherein the tab comprises at least two protrusions extending from a surface of the tab, and wherein the tab is caused to come into physical contact with the terminal of the battery cell at a surface of each of the at least two protrusions and a surface of the terminal of the battery cell. 3. The contactless welding system of claim 2 , wherein activating the laser welder further comprises: focusing, by the controller, the laser beam emitted from the laser welder on an area of the tab comprising the at least two protrusions. 4. The contactless welding system of claim 1 , wherein the magnet is an electromagnet. 5. The contactless welding system of claim 4 , wherein the controller activates a switch that provides power to a winding of the electromagnet. 6. The contactless welding system of claim 5 , wherein the controller activates the switch when the tab is presented in physical proximity to the terminal of the battery cell but before the controller activates the welder. 7. The contactless welding system of claim 6 , wherein the controller maintains power to the electromagnet while the weld is completed. 8. The contactless welding system of claim 7 , wherein the electromagnet includes a core disposed on the first side of the battery cell that moves along a longitudinal axis of a body of the battery cell in a direction toward the tab without contacting the battery cell. 9. The contactless welding system of claim 8 , wherein the core is moved in the direction toward the tab to create a force according to Lenz's law. 10. The contactless welding system of claim 1 , wherein the magnet pulls the tab onto the terminal of the battery cell. 11. A contactless welding method, comprising: providing a tab to be welded to a terminal of a battery cell; providing the battery cell comprising the terminal; moving the tab or battery cell such that the tab is in physical proximity to the terminal of the battery cell; providing a magnet disposed on a first side of the battery cell, wherein the first side of the battery cell is arranged opposite a second side of the battery cell, and wherein the tab is disposed on the second side of the battery cell; when the tab is within physical proximity of the terminal, moving a position of the magnet relative to the battery cell producing a magnetic force that causes the tab to come into physical contact with the terminal without touching the tab or the terminal with the magnet or other physical member; and while the magnetic force causes the tab to come into physical contact with the terminal of the battery cell, activating, via a controller, a laser welder causing the laser welder to emit a laser weld beam that welds the tab to the terminal of the battery cell at the second side of the battery cell. 12. The contactless welding method of claim 11 , wherein the magnet is an electromagnet, wherein the controller activates a switch that provides power to a winding of the electromagnet, and wherein the laser welder is disposed on the second side of the battery cell. 13. The contactless welding method of claim 12 , wherein the controller activates the switch when the tab is moved in physical proximity to the terminal of the battery cell but before the controller activates the laser welder. 14. The contactless welding method of claim 13 , wherein the controller maintains power to the electromagnet while the weld is completed. 15. The contactless welding method of claim 12 , wherein the electromagnet includes a core disposed on the first side of the battery cell that moves along a longitudinal axis of a body of the battery cell in a direction toward the tab without contacting the battery cell. 16. The contactless welding method of claim 15 , wherein the core is moved in the direction toward the tab to create a force according to Lenz's law, and wherein the electromagnet pulls the tab onto the terminal of the battery cell. 17. A method of manufacturing a laser welded battery cell and busbar connection, comprising: providing a connector, wherein the connector is metal, and wherein the connector includes a bent portion configured to be welded to a terminal of a battery cell; providing the battery cell comprising the terminal, wherein the battery cell comprises a first side and a second side disposed opposite the first side, wherein the first side and the second second side of the battery cell; moving the connector or battery cell such that the bent portion of the connector is substantially parallel and in physical proximity to the terminal at the second side of the battery cell; providing a magnet disposed on the first side of the battery cell; when the bent portion of the connector is within physical proximity of the terminal, moving a position of the magnet relative to the battery cell producing a magnetic force that causes the bent portion of the connector to come into physical contact with the terminal of the battery cell without touching the tab or the terminal of the battery cell with the magnet or any other physical member; and while the magnetic force causes the bent portion of the connector to come into physical contact with the terminal of the battery cell, activating, via a controller, a laser welder causing the laser welder to emit a laser weld beam that welds a portion of the bent portion of the connector to the terminal of the battery cell at the second side of the battery cell. 18. The method of manufacturing of claim 17 , wherein the magnet is an electromagnet, wherein the controller activates a switch that provides power to a winding of the electromagnet, and wherein the controller activates the switch when the bent portion of the connector is in physical proximity to the terminal of the battery cell but before the controller activates the laser welder. 19. The method of manufacturing of claim 17 , wherein the controller maintains the position of the magnet while the laser welder emits the laser weld beam. 20. The method of manufacturing of claim 18 , wherein the electromagnet includes a core disposed on the first side of the battery cell that moves along a longitudinal axis of a body of the battery cell in a direction toward the tab to create a force according to Lenz's law, and wherein the magnet pulls the bent portion of the connector onto the terminal of the battery cell.