The present invention is directed to connectors, and, more particularly, to connectors for making low voltage direct current electrical connections between conductive elements.
The electrical grid connecting America's power plants, transmission lines and substations to homes, businesses and factories operate almost entirely within the realm of high voltage alternating current (AC). Yet, an increasing fraction of devices found in those buildings actually operate on low voltage direct current (DC). Those devices include, but are not limited to, digital displays, remote controls, touch-sensitive controls, transmitters, receivers, timers, light emitting diodes (LEDs), audio amplifiers, microprocessors, other digital electronics and virtually all products utilizing rechargeable or disposable batteries.
Installation of devices utilizing low voltage DC has been typically limited to locations in which a pair of wires is routed from the voltage source. Increased versatility in placement and powering of low voltage DC products is desirable. Specifically, there is an increasing desire to have electrical functionality, such as power and signal transmission, in the interior building environment, and specifically in the ceiling environment, without the drawbacks of existing systems.
A conventional grid framework, such as one used in a surface covering system, includes main grid elements intersected by cross grid elements therebetween. The main and cross elements form a grid of polygonal openings into which components such as panels, light fixtures, speakers, motion detectors and the like can be inserted and supported. Known systems that provide electrification to devices, such as lighting components, in conventional framework systems utilize a means of routing discrete wires or cables, principally on an “as needed” point-to-point basis via conduits, cable trays and electrical junctions located in the space behind the grid framework.
These known systems suffer from the drawback that the network of wires required occupy the limited space behind the grid framework and are difficult to service or reconfigure. Moreover, the techniques currently used are limited in that the electricity that is provided is not reasonably accessible from all directions relative to the framework plane. For example, electricity can be easily accessed from a ceiling plenum, but not from areas within or below the plane of the grid framework of a suspended ceiling system. Further, the electrical power levels that are typically available are not safe to work with for those not trained, licensed and/or certified.
In known systems utilizing track systems, the connecting devices have terminals that provide electrical connections to conductors provided in a track. These tracks also typically require wiring and mechanical support from the are behind the grid framework. In addition, existing track systems are typically viewable from the room space and are aesthetically undesirable. Further still, known track systems typically utilize higher voltage AC power and connect to AC powered devices, requiring specialized installation and maintenance.
What is needed is a grid framework system that provides low voltage DC power connections that can be safely utilized from all angles relative the plane of the grid framework. The present invention accomplishes this need and provides additional advantages.
The present invention includes an electrified framework system having a grid element which includes a top portion having a pair of conductors for distributing low voltage electricity disposed thereon. The conductors have opposing polarity and are disposed on opposing surfaces of the top portion of the grid element. The system also includes a connector which is mounted on the top portion of the grid element. The connector includes a means for providing a low voltage power connection between the pair of conductors and another conductive element capable of distributing low voltage electricity.
In accordance with one example embodiment of the invention, an improved connector is provided for installation in the lower box of an electrified grid element. The lower box has a slot and a pair of low voltage conductors. The connector includes a housing which has a wide base portion for lying against the lower box and a narrower top portion for entering the lower box slot. The top portion has a pair of contact elements movably mounted thereon in that the contact elements have end portions for engaging the low voltage conductors housed in the lower box. The connector has a rotator which includes a pair of wings extending therefrom. The winged rotator is rotatable between first and second positions and is coupled to the base portion of the housing. The winged rotator is rotatable without having to rotate any other portion of the housing. The connector also has a cam member mounted on the winged rotator. The cam member interposes the pair of contact elements in the top portion and provides the means for coupling the winged rotator to the contact elements. As the winged rotator is rotated between the first and second positions, the cam member urges the contact elements against the low voltage conductors in the box.
Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts.
The present invention includes connectors for use with an electrified framework. For illustrative purposes,
Conductive material is disposed on a surface of at least one of the plurality of grid members. In the example embodiment shown in
One or more connectors is needed to provide low voltage power connections. For example, a connector is needed to bring power from a power supply to the conductive material disposed on the grid framework. Additionally, a connector is needed to provide an electrical connection between the conductive material on the grid framework and a device such as a light. The various connectors of the electrified framework system are described in greater detail below.
Power-In/Power-Out Connector
The connector 120 shown in
The second contacting portion 132 of the crimp contact is also in contact with conductive material. The second contacting portion 132 of the crimp connector, e.g. 122, includes a receptacle 134 which is attachable to the wiring of a low voltage power source when the connector 120 is to be used to power the conductive material disposed on the grid. The second portion is also attachable to the wiring of a low voltage device, where the conductive path is already being electrified by another source and power is needed to be transported away from the conductive material to a device.
The connector shown in the example embodiment of
An outer clamp 126 can also be used. The clamp 126 which is made of rigid, yet somewhat compliant material, snaps over the insulative housing. Although the clamp can be installed, or even pre-assembled, on the housing prior to attaching the connector to the grid element, the clamp can be installed in at least two other ways to minimize insertion forces. First, the clamp can be installed after fully seating the housing on the grid element to provide for low insertion forces. Alternatively, the clamp can be partially installed on the housing in an up position and then fully seated after the housing is in the fully mated position which also provides low insertion forces but require the clamp to be pre-assembled on the housing.
This firm, yet compliant clamp provides several additional advantages. One advantage is that the clamp 126 provides strength to this otherwise flexible “U” shaped housing 124 to assure a tight and electrically sound connection to the conductor paths on the grid framework. The clamp 126 also assists in assuring that the connection is sufficiently strong to prevent it from being dislodged from the grid upon entry and/or removal of devices such as ceiling tiles or other panel devices. In addition, an optional sloping surface of the top portion of the clamp provides ease of entry for devices such as ceiling tiles when the connector interferes with the insertion of the device into the openings formed by the grid framework. Similarly, the bottom, or perch, end of the housing has a sloping surface to assist in removal of devices without causing accidental dislodging of the connector.
An optional feature of the connector 120 is a location/polarization feature. This feature is designed to assure that the connector 120 can only be installed and fully engaged at pre-determined locations on the grid framework. More specifically, the polarization feature, an example of which is shown in
More than one “keying” slot 144 can be positioned on the grid member 109, e.g. at opposing ends, to provide a polarization, or “shorting out”, feature. Due to the angle of these sloping slots 144, if a power supply is attached to both, the power will short out. Moreover, the polarization feature can only be attached to the conductive material “one way” to maintain polarity from the power supply. Also, it is worth noting that in order to comply with current Underwriter Laboratory standards, the connector component(s) providing power from the power supply to the conductive material on the grid framework must be separate from other connector components, and specifically, the connector which provides the power-out electrical connection between the conductive material and a device.
Power-Out/Fixture Connector
An example embodiment of a second connector is shown in
In the example embodiment shown, the first member 152 of the connector 150 is mounted onto the top portion 112, e.g. bulb portion, of the grid member 109 such that the contacts 158 and 158′ touch and make an electrical connection with the two conductors of opposite polarity, 108 and 108′, positioned on opposing sides of the top portion of the grid element. Each contact includes a clamp portion 160 and a spring portion 162. The clamp portion is composed of a resilient material which assures that the connection to the bulb is secure and prevents accidental dislodgement.
The outer surface of the clamp 160 also serves as the mating contact area for the fixture contact springs which will be described in more detail below. This mating contact area is relatively large and is designed to accommodate a wide tolerance range of fixture positioning. Also, in the example embodiment shown, the top and bottom surfaces of the first member, and, in turn, at least the clamp 160, have a sloping surface which allows the grid to rotate or cam away from the interference of a ceiling tile, or other device, upon installation or removal. This rotation of the grid also assists in preventing accidental dislodgement of the connector.
The spring 162, which can be thinner and less rigid than the clamp portion, extends from the interior wall of the outer clamp 160. The clamp 160 is positioned over the housing 156 such that each spring 162 mates with and is seated in a slot 164 (
The second member 154 of the fixture connector 150 is attached to a device 170 (represented in the drawings as an inverted T element) and includes an insulative housing 172 and two compliant fixture connector contact springs 174 and 174′. The insulative housing 172 accepts and houses the two compliant contact springs, 174 and 174′, and holds them in a position. As shown, the springs are in alignment and mate with the outer surface of a respective clamp 160 of the first member 152 of the fixture connector 150 which creates an electrical connection between the complaint springs 174, 174′ of the second member 154 and the conductive material 108 and 108′ disposed on the surface of the top portion 112 of the grid member 109. The two second member compliant connector springs 174, 174′ can accommodate a wide variation in fixture positioning in the grid framework.
Each of the two springs 174, 174′ have a poke-home type of receptacle connected thereto to receive the fixture wiring. The conductor is then pushed through the hole in the contact, thereby trapping the conductor between two metal surfaces, one being compliant and the other being rigid. The wire can be removed by pressing a pointed tool through the release hole adjacent to the wire, deflecting the compliant surface to release its grip on the wire thereby allowing removal of the conductor.
As shown in the various drawings, the second member can be attached to the side of a device 170 via a fastening means 178 such a mechanical fastener such as screws which engage with self-contained hex nuts.
In-Plane Single Connector
An alternative to the two-piece fixture connector 150 described above, is a connector 180 comprising a single piece as shown in
The single-piece connector, which is preferably attached to a device, rather than the grid element 109, via a fastening means such as a screw type fastener. The fastener can be inserted through aperture 182. Connector 180 includes an insulator housing 184 and two contacts 186. The insulator housing 184 accepts the compliant contacts 186 and holds them in proper opposing relation in order to align and mate the contacts 186 with the conductive material 108 and 108′ positioned on opposing sides of the grid member 109. As shown in the Figures, the housing 184 has a recess formed in the base thereof which generally conforms to the shape of the top portion 112 of a grid element 109 such that the housing 184, and, in turn, the connector 180, can be mounted over and down onto the top portion 112 of the grid member 109.
The connector housing 184 also includes a pair of apertures 189 for inserting the wiring from the device to which the conductor 150 is attached. The apertures 189 provide access to the contact springs 186 so that the wiring from a device, such as device 170, can be brought into contact with the body of the spring 186 in order for an electrical connection to be made between the conductive material 108 and 108′ on the grid and the device to be powered via the spring.
There are several differences, and, in many instances, advantages of the single-piece connector as compared to the two-piece connector described above. One difference is that the fixed contacts inside of connector provide controlled normal forces. As a result, the electrical interface is not dependent on grid opening dimensions. The result is improved fixture to grid tolerance control. Also, no independent installation of the connector to a grid member is required which improves cost of the connector as well as a reduction in labor time. Further, the single-piece can electrically connect the device anywhere along the grid, thereby eliminating potential interference with existing fixture features. Also, the one-piece connector provides greater flexibility in replacing devices, and, thus, it is “device supplier friendly”. Since the connector is attached to the fixture, no connector remains on the grid when the fixture is removed. Also, the one-piece has minimum electrical interfaces which translates to high reliability. The one-piece eliminates the potential to miss-locate or inadvertently disturb the grid mounted portion of the connector. Also, debris will not lodge in the electrical interface.
Underside Connector
In known track systems, the connecting devices have terminals that provide electrical connections to conductors provided in a track. These tracks have the drawbacks that they typically require wiring and mechanical support from the plenum space above the ceiling grid framework. In addition, the track systems are typically viewable from the room space and are aesthetically undesirable. Further still, known track systems typically utilize higher voltage AC power and connect to AC powered devices, requiring specialized installation and maintenance.
As shown in
The purpose of an underside connector is not only the flexibility of attaching the connector to the box of a grid member at any position along the length of the grid box but also to make a robust mechanical connection with the grid member and an electrical connection between the conductive material and various devices. The example connector 210 includes a connector housing 212 comprising two halves 213 and 213′. The connector housing 212 includes a narrow hanger portion 214 and a wider lower body portion 216. The connector 210 is installed by first inserting the hanger portion 214 through the slot of the box. The connector 210 is properly seated in the box 200 by pressing the connector into the box until the top of the lower body portion 216 is in contiguous relation with the pair of flanges 206 of the box which define the slot.
The hanger portion 214 includes two resilient spring contacts 220. The spring contacts 220 are interposed by a cam 222, or gear, housed in a rotator 225. In the example embodiment shown in Figures, the cam 222 is pressed onto the rotator 225. When the connector 210 is properly seated in the grid box 200, the contacts 220 are in parallel alignment with the longitudinally extending conductors 108, 108′ positioned on the sidewalls 204 of the box 200.
The connector is configurable in a first position (shown in
Upon rotation of the winged rotator from position 1 to position 2, the center cam 222 is also turned and the top portion 240 of the cam causes the contact elements to spring apart so that their contacting ends move against the conductors while the expandable hanger locks into the track. In other words, the cam and spring contacts provide a compliant biased contact configured to provide electrical contact to a conductive surface of the electrified ceiling framework. The connector can be disconnected from the grid member by rotating the rotator wings in the opposite direction which, in turn, allows the cam/gear to disengage and the expandable hanger and spring contacts to retract into their original unexpanded position.
The connector is operated by placing the expandable hanger into the grid box and turning the rotator wings which, through the gear drive mechanism will cause the lobes of the all three rotatable cams/gears to overlap the lower surface of the grid box as well as the expandable hanger and spring contacts to expand outwardly in the grid box, thereby making the aforementioned electrical and mechanical connections. The connector can be disconnected from the grid member by rotating the rotator wings in the opposite direction which, in turn, allows all three cams/gears to disengage and the expandable hanger and spring contacts to retract into their original unexpanded position. It should be noted that the cams/gears are synchronized in their movement, i.e. the cams/gears are geared on timing.
The connector is designed to hold a fixture and carry low voltage current thereto. A conventional threaded stud can be attached at the bottom of the connector housing to hold a fixture such as a camera or lighting device. The underside connector also includes miscellaneous conventional fixture mounting hardware such as strain reliefs, nipples, etc. for attaching a fixture, such as a pendant light, to the connector. The jacket of the two wires is strain relieved using a strain relief that interferes with the fixture mounting hardware. The ends of the wires are then attached to the connector spring contacts by placing them under and tightening the two binding head screws 260. The fixture wires are then threaded through the fixture mounting hardware.
The example connector shown in the drawings is assembled by: positioning the rotator on apertures extending through the lower body of the housing; positioning the preassembled cam/gear and cam/gear carrier into receiving features 230 in one housing half, dressing the lead wires; sandwiching all of the components in two housing halves; and securing the housing halves to one another via a mechanical locking mechanism, such as self tapping screws 235.
There are several advantages to the two underside connectors described above including, but not limited to: a stationary body in which the wires extending therethrough do not twist (thus a 360 degree opportunity is provided); additional spring not needed to lock connector grid box; long compliant spring contacts; mechanical amplification of contact movement to negate large grid box tolerances; spring contacts are concealed and therefore protected from abuse and damage; contacts provide small wipe with conductors in grid box to provide electrical interface, rotator has no longitudinal load; simple actuator means; large actuator levers for mechanical advantage and robustness; actuator is visibly apparent in open and closed positions for intuitive operation; rails at the top of housing prevent grid box from spreading; the connector cams into the grid box if not fully inserted when actuated; connector housing can be styled in many shapes (round, square, etc); the connector housing spring contacts and outboard cams/gears are twin components; and the outboard cams/gears are not necessary if connector is used at locations other than the grid intersections which, in turn, reduces the cost of the connector.
While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope of the appended claims.
This application claims the benefit under 35 U.S.C. §119(e) of U.S. provisional application Ser. No. 61/124,226, filed Apr. 15, 2008.
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