Patent Grant
10222006
Tubular light emitting diode (TLED) lamps are a recent development in the lighting industry, and can be used as replacements for fluorescent (FL) lamps. Accordingly, TLED lamps typically have a similar construction (i.e., size and shape) to FL lamps. For example, TLEDs may be generally long tubes (e.g., 2′, 4′, etc.) with an outer diameter of less than 2″. Further, the TLEDs include bases that are disposed at opposite longitudinal ends of the tube.
These bases can be of any number of configurations, including for example, G13 medium bi-pin connectors or connections. Further, the same or similar connectors can be used on both FL lamps and TLED lamps. However, the TLED lamps can have different operating requirements than FL lamps. For example, some TLEDs run on AC power, while others run on low voltage DC power. Additionally, some TLEDs integrate driver electronics, while others have the driver electronics located outside of or external to the TLED lamp.
As a result of the connectors being unchanged from FL lamps to TLED lamps, a TLED lamp can be physically installed in a fixture with FL sockets. While physically interchangeable, the TLED lamp may not be electrically compatible with the FL fixture, thereby providing the opportunity for a variety of operating issues.
According to an aspect of the present disclosure, a tubular light emitting diode lamp includes a lamp body, a plurality of light emitting diodes disposed on the lamp body, and a first lamp base and a second lamp base that are disposed at opposite ends of the lamp body. At least one of the first lamp base and the second lamp base includes at least one primary pin and at least one secondary pin. The tubular light emitting diode lamp also includes a driver electrically connected to the plurality of light emitting diodes, the at least one primary pin, and the at least one secondary pin. The least one primary pin provides power to the driver to cause the plurality of light emitting diodes to emit light and the at least one secondary pin provides a signal to the driver that is distinct from the power.
According to another aspect, a lighting assembly includes a tubular light emitting diode lamp. The lamp includes a lamp body, a plurality of light emitting diodes disposed on the lamp body, and a first lamp base and a second lamp base that are disposed at opposite ends of the lamp body. At least one of the first lamp base and the second lamp base includes at least one primary pin and at least one secondary pin. The tubular light emitting diode lamp also includes a driver electrically connected to the plurality of light emitting diodes, the at least one primary pin, and the at least one secondary pin. The least one primary pin provides power to the driver to cause the plurality of light emitting diodes to emit light and the at least one secondary pin provides a signal to the driver that is distinct from the power. The lighting assembly also includes a first lamp socket and a second lamp socket that are spaced from one another so as to receive the first lamp base and the second lamp base, respectively. At least one of the first lamp socket and the second lamp socket includes at least one power contact configured for electrical connection with the at least one primary pin and at least one signal contact configured for electrical connection with the at least one secondary pin.
The lamp 92 can include a lamp body 98 that extends between the bases 96, 96′ in a tubular manner and houses a plurality of light emitting diodes 99 and a driver 100. Notably, the light emitting diodes 99 provide sufficient lumen output to be acceptable for general illumination. The lamp body 98 may be of polymer construction and cooperate with a lens 105 to define an interior chamber for receiving the light emitting diodes 99 and the driver 100. As will be appreciated, the lens 105 is of a material that allows for the transmission of light therethrough, whereas the lamp body 98 may be of a material that does not allow for the transmission of light therethrough.
The bases 96, 96′ of the lamp 92 are identical in construction, unless otherwise noted. For simplicity, the following description will be directed to the first base 96, but it will be understood to be equally applicable to the second base 96′. The base 96 includes a perimeter wall 103 that at least partially surrounds the lamp 92 in a circumferential manner. From an end view, the base 96 has a generally circular shape and includes a base face 103a that is generally orthogonal to the perimeter wall 103.
A protrusion 107 extends from the base face 103a in a direction away from the lamp body 98. The protrusion 107 includes at least one side wall 107a and a protrusion face 107b. The protrusion face 107b is outwardly spaced from the base face 103a. The protrusion 107 may be integral or separate from the base 96 without departing from the scope of the disclosure.
A pair of primary pins 111a, 111b extend from the protrusion face 107b in a direction away from the lamp body 98. Although the following discussion refers to the primary pins 111a, 111b as being a pair of pins, it will be appreciated that there could merely be at least one primary pin without departing from the scope of the disclosure. The primary pins 111a, 111b are made of an electrically conductive material and have a cylindrical shape. The primary pins 111a, 111b are spaced from one another according to industry standards, and are for the introduction of electricity into the lamp 92. Notably, the primary pins 111a, 111b may be the size and position so as to be physically interchangeable with other lamps that have a G13 base.
As illustrated, the lamp 92 can include another pair of pins 111a, 111b of the second base 96′ at the opposite end of the lamp 92. Further, a distance between the primary pins 111a, 111b of the base 96 and the pins 111a, 111b of the base 96′ would comply with all standards for dimensional requirements for linear lamps. Further still, the primary pins 111a, 111b of the first base 96 are aligned with the primary pins 111a, 111b of second base 96′ such that a respective primary pin 111a of the first base 96 shares a common axis with a respective primary pin 111a of the second base 96′ and a respective primary pin 111b of the first base 96 shares a common axis with a respective primary pin 111b of the second base 96′.
Stated another way, from the free end of the primary pins 111a, 111b of the base 96 to the free end of the primary pins 111a, 111b of the base 96′ defines a maximum overall length of the lamp 92. The maximum overall length of the lamp 92 is according to industry standard and allows for installation of the lamp 92 in traditional lamp sockets which may differ in appearance and layout from the lamp sockets 94, 94′ described herein. The primary pins 111a, 111b of the base 96′ may or may not allow for the introduction of electricity into the lamp 92.
The base 96 of the lamp 92 can also include secondary pins 113a, 113b. Although the following discussion refers to the secondary pins 113a, 113b as being a pair of pins, it will be appreciated that there could merely be at least one secondary pin without departing from the scope of the disclosure. The secondary pins 113a, 113b may be made of an electrically conductive material. As illustrated, the secondary pins 113a, 113b extend from the base face 103a of the base 96 in a direction away from the lamp body 98 and such that the secondary pins 113a, 113b of the base 96 are generally parallel to the primary pins 111a, 111b of the base 96. The secondary pins 113a, 113b of the first base 96 are aligned with the secondary pins 113a, 113b of second base 96′ such that a respective secondary pin 113a of the first base 96 shares a common axis with a respective secondary pin 113a of the second base 96′ and a respective secondary pin 113b of the first base 96 shares a common axis with a respective secondary pin 113b of the second base 96′.
Further, the secondary pins 113a, 113b of the base 96′ are generally parallel to the primary pins 111a, 111b of the base 96′. Further still, the secondary pin 113a is generally parallel to the secondary pin 113b and the primary pin 111a is generally parallel to the primary pin 111b. Finally, the secondary pins 113a, 113b of the base 96 are generally parallel to the primary pins 111a, 111b of the base 96′ and the primary pins 111a, 111b of the base 96 are generally parallel to the secondary pins 113a, 113b of the base 96′.
The secondary pins 113a, 113b are shown as a pair; however, it will be appreciated that a single pin could be utilized. As shown, the secondary pins 113a, 113b are cylindrical in shape. This cylindrical shape can allow for easy installation of the bases 96, 96′ of the lamp 92 into the lamp sockets 94, 94′ during rotation of the lamp 92. Thus, at least one of the first lamp base 96 and the second lamp base 96′ includes at least one primary pin 111a, 111b and at least one secondary pin 113a, 113b.
Other shapes of the secondary pins 113a, 113b are possible without departing from the scope of the disclosure. Further, the secondary pins 113a, 113b extend from the base face 103a a distance that is less than a distance between the base face 103a and the free end of the primary pins 111a, 111b of the base 96. Further, the secondary pins 113a, 113b extend from the base face 103a a distance that is less than a distance that the protrusion face 107b is spaced from the base face 103a.
Further still, a distance between a free end of the primary pins 111a, 111b on the first lamp base 96 and a free end of the primary pins 111a, 111b on the second lamp base 96′ is greater than a distance between a free end of the secondary pins 113a, 113b on the first lamp base 96 and a free end of the secondary pins 113a, 113b on the second lamp base 96′. It is also noted that the secondary pins 113a, 113b are in electrical communication with the driver 100 within the lamp 92 as will be described in more detail hereinafter.
With attention once again to the lamp socket 94, 94′, corners (unnumbered) of the housing portion 102 can be rounded. However, it will be appreciated that the housing portion 102 could be of any number of shapes without departing from the scope of this disclosure. It is envisioned that the housing portion 102 could be made of a variety of materials, including for example, porcelain or composite polymer materials. Further, the housing portion 102 may be an electrical insulator.
The housing portion 102 includes a first end 106 and a second end 108. The first end 106 and the second end 108 are disposed at generally opposite ends of the housing portion 102. Near to the first end 106, the housing portion 102 can including a housing face 102a that define at least one blind bore 109. As illustrated, the blind bore 109 is ring-shaped. As will be appreciated, the housing face 102a would face the base face 103a when the lamp 92 is in the installed state.
Disposed within the blind bore 109 are power contacts 110a, 110b. The power contacts 110a, 110b are of an electrically conductive material and provide electrical communication between the TLED lamp 92 and an external power source (not shown). The power contacts 110a, 110b can be G13 bi-pin sockets or connectors or another type of power contact (e.g., which may be spaced differently, sized differently, etc.).
The power contacts 110a, 110b are configured to supply mains power to primary pins 111 of the TLED lamp 92 when the lamp 92 is inserted into the lamp socket 94 so as to power the lamp 92. A TLED fixture could include a pair of lamp sockets 94, 94′ disposed at longitudinally opposite ends of the fixture. These lamp sockets could be of identical construction of one another. Alternatively, the lamp socket assemblies could be in different configurations from one another. For example, power could be supplied to the TLED lamp 92 through only one of the lamp sockets. As will also be appreciated, the external power source could be any number of voltages, currents, and phases without departing from the scope of the disclosure.
Disposed near the second end 108 of the housing portion 102, is the auxiliary interface portion 104. As illustrated, the auxiliary interface portion 104 extends from the housing portion 102 so as to define an interior direction. It is envisioned that the auxiliary interface portion 104 could be of any number of shapes. For example, the auxiliary interface portion 104 could be rectangular, rounded, elliptical, etc. without departing from the disclosure. Further, the auxiliary interface portion 104 can be made of the same or similar materials as the housing portion 102. The auxiliary interface portion 104 can be integral to the housing portion 102, as illustrated, or can be a separate component. When a pair of lamp sockets 94, 94′ are utilized, the auxiliary interface portions 104 of the respective sockets 94, 94′ would extend toward one another.
The auxiliary interface portion 104 includes a mounting face 112 and a lamp engagement face 114 that can be generally orthogonal to one another. Further, the lamp engagement face 114 can be generally orthogonal to the housing face 102a and the mounting face 112 can be generally parallel to the housing face 102a. Generally, the mounting face 112 would face toward the base face 103a and the lamp engagement face 114 would face toward the side wall 107a of the protrusion 107 when the lamp 92 is in the installed state.
The auxiliary interface portion 104 has one or more signal contacts 116a, 116b that are electrically conductive for electrical engagement with the secondary pins 113a, 113b. As shown, the signal contacts 116a, 116b are disposed on the lamp engagement face 114. As illustrated, the auxiliary interface portion 104 has a curved shape and the signal contacts 116a, 116b share similar alignment. It will be understood that the shape of these components contributes to easy installation of the lamp 92 into the lamp sockets 94, 94′.
The secondary pins 113a, 113b each include a perimeter surface face and a free end face. The secondary pins 113a, 113b extend from the base face 103a such that the free end face is generally parallel to the base face 103a. Further, a perimeter surface face is adapted to electrically interface with a respective lamp socket 94 such that less than 50% of a surface area of the perimeter surface face directly contacts the signal contacts 116a, 116b of the lamp socket 94. This limited engagement ensures that the lamp 92 is easily installed into the socket 94 with minimum rotational force required.
Although the figures illustrate the auxiliary interface portion 104 as having two signal contacts 116a, 116b, additional or fewer signal contacts 116a, 116b may be utilized. Similarly, additional signal contacts may be provided, such as one or more Ethernet signal contacts (e.g., resulting in four, eight, or any number of signal contacts) without departing from the present disclosure. When the driver 100 is integrated into the TLED lamp 92, control signals may be desired for operation, such as dimming signals or digital communication.
Thus, the auxiliary interface portion 104 can provide for an effective way for control of the TLED lamp 92. It is also noted that the driver 100 is schematically shown in
As such, it will be appreciated that the driver 100 is electrically connected to the plurality of light emitting diodes 99, the at least one primary pin 111a, and the at least one secondary pin 113a. The at least one primary pin 111a provides power to the driver 100 to cause the plurality of light emitting diodes 99 to emit light and the at least one secondary pin 113a provides a signal to the driver 100 that is distinct from the power provided from the primary pin 111a.
The signal contacts 116a, 116b are configured to interface with the secondary pins 113a, 113b of the TLED lamp 92 when the primary pins 111a, 111b of the TLED lamp 92 are received by the power contacts 110a, 110b. As will be appreciated, the secondary pins 113a, 113b of the TLED lamp 92 have a size and shape that allow for connection with the signal contacts 116a, 116b. These signal contacts 116a, 116b are configured to provide communicate with the TLED lamp 92, which could include communicating control signals to the TLED lamp 92 via the driver 100.
Examples of control signals include dimming control signals (e.g., to control the brightness of the TLED lamp) or operation control signals (e.g., to control logic associated with operation of the TLED lamp). The control signals can be low-voltage control signals, thereby enabling a close spacing of the signal contacts 116a, 116b (e.g., such that they can be tightly packed). As will be appreciated, these control signals are separate from the power that is supplied to the lamp 92 that causes the driver 100 to illuminate the light emitting diodes 99. Stated plainly, the two primary pins 111a, 111b are electrically distinct and separate from the two secondary pins 113a, 113b.
As noted hereinbefore, a TLED fixture can include two lamp sockets 94, 94′ disposed at opposite ends for receipt of the TLED lamp 92. In that instance, the first lamp socket 94 could be as previously described and the second lamp socket 94′ could include one or more power contacts, but lacking any signal contacts.
With reference to
Due to the position of the separator wall 118, some legacy lamps may not be able to be physically installed into the lamp sockets 94, 94′ due to contact with the separator wall 118. Thus, only lamps that are compatible with the electrical supply from the power contacts 110a, 110b can be installed into the lamp sockets 94, 94′, thereby ensuring that the installed lamp can operate at peak performance and be appropriately controlled.
As a result, legacy lamps (e.g., FL) would not fit in the lamp sockets 94, 94′. Conversely, the TLED lamp 92 compatible with the lamp sockets 94, 94′ shown of
In this way, the separator wall 118 provides a keying feature which prevents incompatible legacy lamp products, including lamps with a traditional G13 type base, from being installed in the lamp sockets 94, 94′. This provides numerous benefits including ensuring that the most compatible lamps are installed in the lamp sockets 94, 94′ and also providing enhanced communication and control of the TLED lamp installed therein. Further, the separator wall 118 can protect inadvertent contact with the signal contacts 116a, 116b.
It will be appreciated that variations of the above-disclosed and other features and functions, or alternatives or varieties thereof, may be desirably combined into many other different systems or applications. Also that various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art which are also intended to be encompassed by the following claims.
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