In one embodiment, an LED lamp has a generally bulb shape. The LEDs are low power types and axe encapsulated in thin, narrow, flexible strips. The LEDs are connected in series in the strips to drop a desired voltage. The strips are affixed to the outer surface of a bulb form to provide structure to
In one embodiment, an LED lamp has a generally bulb shape. The LEDs are low power types and axe encapsulated in thin, narrow, flexible strips. The LEDs are connected in series in the strips to drop a desired voltage. The strips are affixed to the outer surface of a bulb form to provide structure to the lamp. The strips are connected in parallel to a power supply, which may be housed in the lamp. Since many low power LEDs are used and are spread out over a large surface area, there is no need for a large metal heat sink. Further, the light emission is similar to that of an incandescent bulb. In other embodiment, there is no bulb form and the strips are bendable to have a variety of shapes. In another embodiment, a light sheet is bent to provide 360 degrees of light emission. Many other embodiments are described.
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1. A solid state lamp comprising: one or more strips, each of the strips comprising first and second electrical contacts at opposing ends of the strip, a substrate, and one or more light emitting diodes (LEDs) disposed on the substrate operatively interconnected with the first and second electrical
1. A solid state lamp comprising: one or more strips, each of the strips comprising first and second electrical contacts at opposing ends of the strip, a substrate, and one or more light emitting diodes (LEDs) disposed on the substrate operatively interconnected with the first and second electrical contacts and configured to emit light during operation, wherein the substrate transmits at least some of the light emitted by the LEDs;a base structure having first and second electrical connection locations operatively connected, respectively, with the first and second electrical contacts of the strips and configured to provide electrical power to the one or more strips; anda connector affixed to the base structure and configured to operatively connect the base structure to an external power source,wherein the first electrical connection location is disposed proximate the connector and the second electrical connection location is disposed distal of the connector. 2. The solid state lamp of claim 1, wherein the one or more strips are shaped to mimic the appearance of filaments in an incandescent light bulb during operation. 3. The solid state lamp of claim 1, further comprising a bulb extending from the connector and surrounding the one or more strips and the base structure. 4. The solid state lamp of claim 3, wherein the bulb is substantially transparent. 5. The solid state lamp of claim 1, wherein each strip is configured to emit light around an axis of the strip. 6. The solid state lamp of claim 1, wherein the first and second electrical contacts of each strip are located at opposite ends of the strip. 7. The solid state lamp of claim 1, wherein each of the one or more strips further comprises a phosphor coating covering the one or more LEDs and the one or more LEDs are configured, during operation, to emit light towards the phosphor and the phosphor is configured to convert light received from the one or more LEDs into converted light. 8. The solid state lamp of claim 1, wherein the one or more LED strips are electrically connected in parallel. 9. The solid state lamp of claim 1, wherein the base structure comprises a transparent material. 10. The solid state lamp of claim 1, wherein the one or more strips are electrically connected in series. 11. The solid state lamp of claim 1, wherein the one or more strips extend along a straight line from the first electrical contact to the second electrical contact. 12. The solid state lamp of claim 1, wherein the base structure comprises a wire frame that includes the first and second electrical connection locations. 13. The solid state lamp of claim 1, wherein the connector comprises a screw socket connector or bayonet socket connector. 14. The solid state lamp of claim 1, wherein the connector is an Edison-type connector. 15. The solid state lamp of claim 1, wherein the connector is configured for connection to a socket by rotation about a connector axis, and the first and second electrical connection locations are at different positions along the connector axis. 16. The solid state lamp of claim 1, wherein the LEDs are LED dies. 17. The solid state lamp of claim 16, wherein the LED dies are encapsulated in the strip. 18. The solid state lamp of claim 17, wherein each strip comprises a layer of material extending over multiple of the LED dies. 19. The solid state lamp of claim 16, wherein sides of the LED dies are encapsulated by phosphor infused in a binder material. 20. The solid state lamp of claim 19, wherein the binder material is a silicone. 21. The solid state lamp of claim 16, wherein the LED dies are disposed on a single side of the substrate. 22. The solid state lamp of claim 16, wherein the LED dies are disposed in a single row on the substrate. 23. The solid state lamp of claim 16, wherein at least some of the strips are curved. 24. The solid state lamp of claim 16, wherein the connector defines a lamp axis about which the lamp is rotated when installing the lamp in a conventional light socket, and at least a portion of at least some of the strips extend along the lamp axis non-parallel to the lamp axis. 25. The solid state lamp of claim 24, wherein at least a portion of at least some of the strips extend along the lamp axis non-parallel to each other. 26. The solid state lamp of claim 24, wherein the connector is an Edison screw-in connector. 27. The solid state lamp of claim 1, wherein each LED emits light in a substantially Lambertian pattern. 28. The solid state lamp of claim 1, wherein the substrate is formed from a transparent material. 29. The solid state lamp of claim 1, wherein each strip comprises a phosphor in a binder material and the one or more LEDs are configured, during operation, to emit light towards the phosphor and the phosphor is configured to convert light received from the one or more LEDs into converted light. 30. The solid state lamp of claim 29, wherein the binder material is a silicon binder material. 31. The solid state lamp of claim 29, wherein the LEDs are encapsulated in each strip, the encapsulant comprising a layer of a material extending over multiple of the LEDs.
Le, Long Larry; Pickard, Paul; Lay, James Michael; Tong, Tao; Letoquin, Ronan; Keller, Bernd; Tarsa, Eric; Youmans, Mark; Lowes, Theodore; Medendorp, Jr., Nicholas W.; Van De Ven, Antony; Negley, Gerald, High efficiency solid state lamp and bulb.
Tong, Tao; Le Toquin, Ronan; Keller, Bernd; Tarsa, Eric; Youmans, Mark; Lowes, Theodore; Medendorp, Jr., Nicholas W.; Van De Ven, Antony; Negley, Gerald, LED lamp or bulb with remote phosphor and diffuser configuration with enhanced scattering properties.
Tong, Tao; Le Toquin, Ronan; Keller, Bernd; Tarsa, Eric; Youmans, Mark; Lowes, Theodore; Medendorp, Jr., Nicholas W.; Van De Ven, Antony; Negley, Gerald, LED lamp with remote phosphor and diffuser configuration.
Yuan, Zongjie; Tarsa, Eric; Tong, Tao; Letoquin, Ronan; Keller, Bernd; Le, Long Larry; Lay, James Michael; Demuynck, Randolph Cary, LED lamp with remote phosphor and diffuser configuration utilizing red emitters.
Lerman, Louis; York, Allan Brent; Henry, Michael David; Steele, Robert; Ogonowsky, Brian D., Solid state light sheet using thin LEDs for general illumination.
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