1. Technical Field
The present disclosure relates to lamp sockets, and in particular, to a lamp socket adapted ensure a lamp is fully engaged prior to being energized.
2. Description of Related Art
Fluorescent lamps typically comprise a hermetically sealed structure or tube containing one or more gases with a small amount of mercury contained therein. The tube is typically coated with a phosphor-based power along the inside of the tube. Additionally, fluorescent lamps also generally contain two electrodes spaced apart and configured such that current flows through the gas and mercury in certain conditions. When sufficient electric charge is applied between the electrodes, electrons migrate through the gas away from one electrode and towards the other. As aggregate electric charge is displaced, some of the electrons collide with the vapor-phase mercury thus exciting electrons contained therein into higher energy states (sometimes incorrectly referred to as “orbital” states). Quickly thereafter, these excited vapor-phase mercury atoms (ionized mercury gas) quickly drop to a lower excitation state and release one or more photons equal to the energy loss resulting from the reduced excitation state of the gas-phase mercury atom. The photons released from the mercury gas are mostly in the ultraviolet region of the light spectrum, and consequentially, are invisible to the human eye and are not directly desirable for human lighting. However, these UV photons are absorbed by the phosphor-based coating. The absorption of the UV photons excites the phosphor atoms, which after rising to a higher energy state, quickly return to a lower energy state giving off light mostly in the visible spectrum.
These fluorescent lamps typically include at least one pin and commonly two pins electrically connected to an electrode. Each electrode is at the end of the hermetically sealed tube. In some configurations, current is injected between the two pins of the electrode to heat the electrodes thereby “boiling off” electrons from the metal surface sending them into the gas thus partially ionizing the gas. However, in some embodiments, this function is bypassed and the two pins are simply electrically connected together in the control circuitry, the lamp socket and/or in the lamp housing.
These fluorescent lamps have a life span and therefore need frequent replacing from time to time. Several fluorescent lamp designs have been standardized including their respective lamp sockets; for example, T5, T8 and T12 are standard fluorescent lamp designs. Lamp sockets are usually designed so that fluorescent lamps may be quickly installed and/or removed. Typically, the lamp sockets are installed by a technician that inserts the pins of the florescent lamp into a socket (usually from the side) and rotates the lamp to secure the lamp within the lamp fixture. These florescent lamps are usually electrically connected immediately upon insertion or after a very minimal amount of rotation. When a florescent lamp is inserted into a lamp socket and not fully rotated, the lampholder may not be fully seated which may be undesirable.
The present disclosure relates to lamp sockets, and in particular, to a lamp socket adapted ensure a lamp is fully engaged prior to being energized.
In one embodiment of the present disclosure, a multi-pin socket assembly includes a rotor assembly, a housing, and at least one electrical contact. The rotor assembly has an axis of rotation and defines a channel having a length about perpendicular to the axis of rotation. The rotor assembly is adapted to receive at least one lamp pin within the channel from an edge of the rotor assembly. Each of the at least one lamp pin defines a longitudinal axis. Each of the axis of each of the at least lamp pin is about parallel to the axis of rotation when each of the at least one lamp pin is received from the edge of the rotor assembly to within the channel. the housing is adapted to receive the rotor assembly such that the rotor assembly is rotatable along its axis of rotation therein. The housing defines a notch adapted to receive each of the at least one lamp pin when each of the axis of each of the at least one pin is about parallel to the axis of rotation. The rotator assembly is rotatable to at least first and second positions and the channel of the rotor assembly aligns with the notch of the housing when in the first position such that each of the at least one lamp pin is received through the notch of the housing and into the channel of the rotor assembly. A least one electrical contact is disposed within the housing and an electrical contact of the at least one electrical contact is adapted for operative engagement with a lamp pin of the at least one lamp pin. The electrical contact is operatively disengaged from the lamp pin when the rotor assembly is in about the first position and operatively engages the lamp pin when the rotor assembly is rotated at least substantially to the second position.
In yet another embodiment of the present disclosure, a socket assembly includes a mounting structure and a lamp socket. The mounting structure has a plurality of snaps adapted to secure the mounting structure to a receiving portion of a surface. Each of the plurality of snaps includes an elongated length defining an axis and each of the plurality of snaps includes a flange disposed at an end thereof. Each flange of each of the plurality of snaps extends at a radial angle of the axis and at least two of the plurality of snaps have different radial angles of extending flanges. The lamp socket is adapted to receive a lamp. The lamp socket operatively connected to the mounting structure to operatively secure the lamp to the receiving portion of the surface.
In yet another embodiment of the present disclosure, a socket assembly includes a rotor assembly, a housing, and at least one electrical contact. The rotor assembly defines an axis about perpendicular to a surface of the rotor assembly. The rotor assembly further defines a channel having a length about perpendicular to the axis of the rotor assembly. The rotor assembly is adapted to receive at least one lamp pin within the channel from an edge of the rotor assembly. Each of the at least one lamp pin defines a longitudinal axis and each of the axis of each of the at least lamp pin is about parallel to the axis when each of the at least one lamp pin is received from the edge of the rotor assembly to within the channel. The housing is adapted to receive the rotor assembly such that one of the housing and/or the rotor assembly is rotatable about the axis about perpendicular to the surface of the rotor assembly. The housing defines a notch adapted to receive each of the at least one lamp pin when each of the axis of each of the at least one pin is about parallel to the axis. One of the housing and the rotator assembly is rotatable to at least first and second positions and the channel of the rotor assembly aligns with the notch of the housing when in the first position such that each of the at least one lamp pin is received through the notch of the housing and into the channel of the rotor assembly. The at least one electrical contact is disposed within the housing. An electrical contact of the at least one electrical contact is adapted for operative engagement with a lamp pin of the at least one lamp pin. The electrical contact is operatively disengaged from the lamp pin when the one of the housing and the rotor assembly is in about the first position and operatively engages the lamp pin when the one of the housing and the rotor assembly is rotated at least substantially to the second position.
In yet another embodiment of the present disclosure, a method of using a lamp includes: providing the lamp having a lamp pin disposed thereon; providing a lamp socket; inserting the lamp pin into the channel such that the lamp pin is received from the edge of the rotor assembly to within the channel; and rotating the rotor assembly to the second positions such that the electrical contact operatively engages the lamp pin.
These and other advantages will become more apparent from the following detailed description of the various embodiments of the present disclosure with reference to the drawings wherein:
Referring to the drawings,
Rotor assembly 104 can receive two-lamp pins (not shown) within channel 106 via notch 108. The lamps pins can cause rotor assembly 104 to rotate. The lamps pins cause rotation when the lamp is rotated. The lamp pins are received when about parallel to axis “A”. Once the lamp pins are within channel 106, rotor assembly 104 may be rotated around axis “A” thereby also rotating the lamp pins along with the attached lamp (not shown).
Initially, when the rotor assembly 104 is in the position as shown in
When the rotor assembly 104 is rotated 90 degrees about axis “A”, the lamp pins positioned therein make electrical contact with the pins when about fully rotated. This prevents the lamp from being energized because the two lamp pins are not in electrical communication until rotor assembly 104 is rotated to a second predetermined position, which in this embodiment as mentioned above, is 90 degrees of rotation around axis “A”.
Additionally, the electrical contacts may protrude (not shown) into the channel 106, thus “snapping” rotor assembly 104 into a semi-locked position while simultaneously and suddenly making full electrical contact with the lamp-pins with the electrical contacts disposed therein (discussed in more detail below). The electrical contacts within multi-pin socket assembly are adapted for being electrically wired for sufficient operation of the lamp, e.g., a fluorescent lamp may be wired to an electrical ballast via the internal electrical contacts. Additionally, multi-pin socket assembly 100 may have torque resistance from further rotation about axis “A” after positioned in the semi-locked position.
Multi-pin socket assembly 100 may be adapted to receive several types of lamp sockets, including a T5 lamp, a T8 lamp and a T12 lamp. The lamps pins may be positioned at or near the periphery of rotor assembly 104 when positioned therein. Multi-pin socket assembly 100 may also be adapted to be attachable to a mounting structure (not shown in
Referring to the drawings,
Rotor assemblies 302 and 304 are each adapted to receive lamp pins (not shown) via channels 306 and 306, respectively. After the pins are received, each may be rotated about 90-degree which causes rotor assemblies 302 and 304 to make electrical contact to the lamp pins and semi-lock rotor assemblies 302 and 304 into the 90-degree position. Electrical contacts disposed within multi-pin socket assembly may protrude through channels 306 and 308 (discussed below). Mounting structure 306 mounts rotor assemblies 302 and 306 to a panel (not shown).
Referring to the drawings,
Referring to the drawings,
Rotor assembly 514 is disposed within housing 518 and is rotatable therewithin. Housing 518 defines a notch 520. Although notch 520 is shown as being about the same width as channel 516, notch 520 may be larger or smaller than the width of channel 516. Additionally or alternatively, notch 520 may be substantially surrounding rotor assembly 514, e.g., housing 518 may not extend flush with rotor assembly 514 thereby the “notch”, in this example, would extend all around rotor assembly 514 (not shown).
Multi-pin socket assembly 500 also includes securing members, i.e., snaps 504, 508, and 510. Snaps 504, 508, and 510 each include flanges 522, 524, and 526, respectively. Flange 522 defines an axis “E”, flange 524 defines an axis “F” and flange 526 defines an axis “G”. Note that flange 524 has a radial angle (along axis “F”) of about 180 degrees relative to the radial angles of flanges 522 and 526 (along axes “E” and “G”, respectively). The radial angle is defined by the angle in which the flange generally points. For example, snap 504 has a flange 522 that has a radial angle that is about parallel to axis “D”, i.e., note that flange 522 is pointing towards a direction about parallel to the direction axis “D” points towards.
Note that rotor assembly 514 is positioned within housing 518 and that the channel 516 is orientated in a first position therewithin. Refer now simultaneously to
Additionally, electrical contacts 528 and 530 may be configured to quickly and suddenly enter into channel 516 to semi-secure (i.e., resist further rotation about axis “D”) rotor assembly 514; this also facilitates direct and complete electrical contact with pins positioned within channel 516. The details of electrical contacts 528 and 530 are discussed below.
Referring again to
Rotor assembly 514 has a general circular shape to facilitate rotation along axis “D”. Pins 532 and 534 are of lamp 536. After pins 532 and 534 of lamp 536 are inserted into channel 516 via notch 520, lamp 536 may be rotated along axis “D” thereby rotating rotor assembly 514 therewith. Thereafter, electrical contacts 528 and 530 will contact pins 532 and 534, respectively, providing an electrical connection for proper operation of lamp 536. Also, multi-pin socket assembly 500 includes shunt 538 for electrically connecting together electrical contacts 528 and 530, thus keeping pins 532 and 534 in electrical communication.
Most fluorescent lamps (e.g., lamp 536) have four pins with two at each end. Each pair of pins at each end has an opposite charge relative to the other pair. Older ballast systems utilize pins 532 and 534 by communicating electrically to them separately, however, most modem electrical ballasts utilize them such that they are electrically connected.
Referring to
Additionally, when rotor assembly 524 is rotated along axis “D” about 90-degree to a second position, each of electrical contacts 528 and 530 extend into channel 516 thus providing torque resistance away from the second position, and securing lamp pins disposed therein to electrical contacts 528 and 530.
Referring to the drawings,
Refer now to
While several embodiments of the disclosure have been shown in the drawings and/or discussed herein, it is not intended that the disclosure be limited thereto, as it is intended that the disclosure be as broad in scope as the art will allow and that the specification be read likewise. Therefore, the above description should not be construed as limiting, but merely as exemplifications of particular embodiments.
Number | Date | Country | |
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Parent | 12243509 | Oct 2008 | US |
Child | 13014972 | US |