The present description relates generally to lampholders for electrical devices, such as for example for tube lamps, and more particularly, to methods and apparatus for grounding an electrical device via a lampholder.
Traditional fluorescent tube lamps, such as for example T-5 and T-8 lamps, use fluorescent technology and only require two pins, e.g., electrical contacts, at the two ends of the tube lamp and in corresponding contacts in the lampholders. These lampholders, typically referred to as tombstone style lampholders are generally well known in the art.
For example, U.S. Pat. No. 2,247,117 describes a lampholder or socket for a lamp having a double end discharge, such as a fluorescent tube design. The described socket includes a base, a cover, and two contact members. The contact members cooperate with and engage the contact pins extending from a base at each end of the tubular lamp, such as a fluorescent lamp. The base and housing of the socket are typically made of any suitable insulating material. In use, the contacts of the tubular lamp are mounted to the socket by inserting the contacts of the lamp into a slot provided in the socket. Thereafter, the lamp is rotated ninety degrees to engage the contacts of the lamp with the contacts of the lampholder.
Recently, new light-emitting diode (LED) tubes have been designed to fit into the same lampholders as previously used in fluorescent tube lamps. An LED tube is made up of dozens of individual LEDs. They come in a variety of sizes (e.g., 2, 4 or 6 feet), different color temperatures (i.e., different colors of light), and varying lumen output. LED tubes can be purchased with new fixtures, or used for retrofitting existing fixtures. However, LED tubes don't require the ballasts that traditional fluorescents need, so the ballasts need to be removed when replacing fluorescent bulbs with LED tubes. Instead of a ballast, LEDs use a driver to convert the line AC voltage to DC and to provide other conditioning and control. Often the driver is contained in the same housing as the LEDs, meaning a line voltage shock risk is present Other times, even with the driver housed separately, the input DC voltage to the lamp can still be high enough to be a shock risk (NEC Circuit Class 1). As such, LED lamps can sometimes pose a safety risk due to exposed metal for reasons such as, for instance, heat-sinking or electrical contacts.
Recently some LED systems have been developed with switches in the LED tubes for safety purposes. These safety switches, while sufficient for their intended purposes, add cost and complexity to the lamp that may not be desirable in some manufacturing instances.
Still further, in other LED tube systems, such as the Japanese JELMA 801 standard, an incorporated ground path is provided for performance reasons. For instance, a GX16t-5 LED lamp includes a power input side, having two connectors, and a ground side at the opposite end. In operation, the user can insert the power side into the respective lampholder before inserting the ground side. Oftentimes, insertion of the power side first is without risk to the installer, but that may not always be the case, such as for instance, when the power level is not NEC Circuit Class 2.
Thus, there is a recognizable need for safe and convenient methods and apparatus for grounding an LED tube as disclosed herein.
The following description of example methods and apparatus is not intended to limit the scope of the description to the precise form or forms detailed herein. Instead the following description is intended to be illustrative so that others may follow its teachings.
In general, in one example, the present disclosure provides for a three terminal lampholder that assures the ground (earth) terminal of the lamp, such as, for example an LED lamp, makes first contact and break last relative to the power terminals. More particularly, as described herein, the example lamp includes a three terminal design, having two contact terminals and a ground terminal. In operation, as the lamp is inserted into the lampholder, the ground terminal of the lamp makes contact with a ground terminal of the example lampholder. In this instance, once the lamp is fully inserted, the ground terminal is fully engaged, and the power terminals are not yet energized as they do not contact the power terminals of the lampholder. The lamp may then be rotated to electrically couple the power contacts of the lamp and lampholder. The example lampholder may be self-grounding as the ground terminal may be in contact with the luminaire metal to provide a ground path without external wiring between the lampholder and the luminaire.
In another example, the present disclose may provide for the use a self-grounding terminal in a single terminal lampholder such as the ground end of a GX16t-5 as previously discussed. As with the ground terminal of the example three-terminal design disclosed herein, the single terminal lampholder may be provided with an exposed portion to self-ground the terminal to the luminaire.
Referring now to
In this example, the two power terminals are radially offset from a longitudinal axis L of the lamp 12, while the ground terminal 25 is generally coaxially aligned with the axis L. Thus, as will be appreciated, rotation of the lamp 12 about the axis L will changed the position of the power terminals 23, 27, while maintaining the general position of the ground terminal 25.
As shown in
Still further, it will be understood by one of ordinary skill in the art that the housing 14 may comprise, for example, multiple parts molded and/or otherwise formed and assembled to form the housing. In this manner, the contacts 22, 24, and 26 may be provided in the interior space 20. Additionally, the interior space 20 may include at least one support structure (not shown) for supporting and/or otherwise maintaining the contacts 22, 24, and 26 within the interior space 20 and in electrical contact with an installed lamp 12 as is well known in the art.
Turning to
While the ground contact 24 can include an inserted ground wire attached to the push-in type connector 24a, as illustrated in
Referring now to
By rotating the lamp 12 about the longitudinal axis L in any direction, such as for example, in the direction of the arrow A (
To withdraw the lamp 12, the process is repeated and the lamp is rotated again in any direction about its longitudinal axis L to align the terminals 23, 25, 27 in the insertion slot 30. As a result, the power terminals 23, 27 once again are disconnected from the contacts 22, 26, while the ground connection is maintained between the ground terminal 25 and the ground contact 24. In other words, the ground connection is the last to be broken. Once fully rotated, the lamp 12 can be withdrawn from the lampholder 10.
In the presently illustrated example, both when being inserted and when being withdrawn, the power terminals 23, 27 do not touch any live circuit part when they are pushed into or withdrawn from the insertion slot 30. It will be appreciated, however, that the terminals 23, 27 and/or the contacts 22, 26 may be modified in shape such that the lamp 12 does not need to be rotated and/or may only be required to be rotated an amount other than the ninety degrees illustrated above. In either case, the ground connection is the first connection made during insertion of the lamp 12 into the lampholder 10 to provide a constantly grounded circuit.
A further example of a self-ground lampholder 100 is illustrated in
As the example GX16t-6 lamp includes a cylindrical ground post, the first ground contact 124a and the second ground contact 124b together form a generally arcuate shape 125 corresponding to the outer shape of the ground contact of the lamp. Upon insertion of the lamp into the lampholder 100, the lamp is free to rotate about the ground contact as desired without breaking contact with the ground terminals 124a, 124b.
In the illustrated example each of the ground contacts 124a and 124b include a grounding extension 140a, 140b, respectively, extending from the housing 114 through apertures or slots 144 defined by the housing 114. As with the previous ground contact 24, in this instance, the example contact extensions 140a, 140b allow the ground contacts 124a, 124b to be in contact with a base 142 to provide a ground path without requiring additional wiring to the lampholder 100.
Although certain example methods and apparatus have been described herein, the scope of coverage of this patent is not limited thereto. On the contrary, this patent covers all methods, apparatus, and articles of manufacture fairly falling within the scope of the appended claims either literally or under the doctrine of equivalents.
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