The present invention relates generally to the field of portable light used to illuminate various surfaces.
Portable lights are often used in a commercial and residential setting to illuminate surfaces. A variety of portable lights have been proposed in the art, such as U.S. Pat. No. 6,854,862 which discloses a system that allows a user to illuminate objects with an infinitely adjustable light fixture and a knock down base frame.
These and other prior art approaches generally increase the quality of light and the functionality of adjusting the light to an infinite amount of freedom.
Nevertheless, there are limitations associated with such approaches including the ability to reduce the size of the light to an easily transportable volume. The placement of the electrical cord providing power to the light fixture has also remained an unassailable hurdle for such approaches. Likewise, the protection of the light fixture while in transport greatly limit the effectiveness and operational performance of such systems.
There is therefore a continued need for improvements to address these and other limitations in the art, and it is to such improvements that preferred embodiments of the present invention are generally directed.
Various embodiments of the present invention are generally directed to an apparatus and associated method for operating a portable light assembly.
In accordance with some embodiments, a frame providing a bridge and defining a transport region and a deployment region is slidingly connected to a mast. An arm is further connected to the mast by a hinge while a light fixture is connected to the arm. In various embodiments, the light fixture is capable of transitioning from a deployed position where the mast engages the deployment region and a transport position where the mast and light fixture are disposed within the transport region.
In accordance with other embodiments, a frame having a bridge defining a transport region and a deployment region is provided. A mast is slidingly connected to the frame and an arm is connected to the mast by a hinge while a light fixture is connected to the arm. The light fixture is subsequently transitioned from a deployed position where the mast engages the deployment region to a transport position where the mast and light fixture are disposed within the transport region.
Further in other embodiments, a hinge is capable of selectively securing a first protrusion in relation to a second protrusion. The hinge encloses a cord that connects an electrical device connected to the first protrusion with a power source positioned adjacent to the second protrusion.
These and various other features and advantages which characterize the various embodiments of the present invention can be understood in view of the following detailed discussion in view of the accompanying drawings.
Preferred embodiments of the present invention are generally directed to a portable light suitable for use in illuminating various surfaces, such as automobile bodies or aeronautical interiors.
As discussed in greater detail below, the portable light preferably includes a novel collapsible position in which the light fixture is protected from harm.
Referring now to
Further in various embodiments, a mast 110 is connected to the bridge 104 and is capable of being manipulated into a deployed position to which the mast 110 engages a deployment region 112 defined by the base 102 as well as the bridge 104. In contrast, the mast can also be manipulated into a transport position to which the mast 110 is disposed within a transport region 114 defined by the base 102 and bridge 104. While the mast can comprise a single unitary component, the mast can alternatively be configured to provide a number of extensions 116 that allow enhanced vertical precision of an attached hinge 118 through selected securement of one, or many, clamps 120.
In addition, the hinge 118 can be connected to an arm 122 and provide, in some embodiments, an infinite number of adjustment positions in a single plane. That is, the hinge 118 can adjust and secure the arm 122 in an infinite range of motion along a single plane. As shown in
It should be noted that the handle 124 can be adjusted and secured along the length of the arm 122 alone, or in combination, with the adjustment of the orientation of the light fixture 126. Likewise, the placement and configuration of the electrical cord 128 should be noted as providing advantageous practical adjustment of the arm 122, handle 124, and light fixture 126 due, at least in part, to the placement of the cord 128 within the mast 110, hinge 118, and handle 124, but external to the arm 122.
That is, the cord 128 is enclosed individually by the mast 110, hinge 118 and handle 124 during operation and adjustment while being external and adjacent to the arm 122. Such a combination of internal and external placement of the cord 128 allows for adjustment and operation of the various components of the light assembly 100 without risk of inadvertently snagging or abusing the cord. Hence, safety and efficiency of the light assembly 100 is vastly improved with the cord 128 configuration shown in
It can be appreciated that the electrical cord 128 can be connected to either a stationary power source or a mobile power source. For example, the cord 128 could be configured to tap power from a wall mounted electrical receptacle or a unitary mobile battery. In the case of a mobile power source, the base 102 can be configured to provide straps to restrict movement and maintain position in the transport region 114 of the base 102. However, the number, size, and orientation of any power source straps is not limited and can be constructed as needed to efficiently supply power to the light assembly 100.
Furthermore, a preferred embodiment of the present invention connects the mast 110 to the bridge 104 with a coupling 130 that allows rotational movement about the bridge 104 while maintaining a sliding relationship with the mast 110. That is, the coupling 130 operates in conjunction with either the deployment region 112 or the transition region 114 to secure the mast 110. As a result, the mast 110 is preferably disengages a region (e.g. 112 or 114) by sliding through the coupling 130 before engaging the opposing region.
For clarification, an exploded view of the portable light assembly 100 of
While the light assembly 100 is depicted in a deployed position in
As discussed above, the coupling 130 preferably provides a sliding engagement of either the deployment region 112 or the transport region 114. As such, the mast 110 laterally slides into the transport region 114 so that the coupling 130 traverses a portion of the mast 110, in a preferred embodiment. However, it should be noted that the light fixture 126 can be manipulated into the transport region 114 and transported without rotating the coupling 130. For example, the mast 110 can be removed from the coupling 130 and slid into the transport region 126.
Further in various embodiments of the present invention, the light fixture 126 is preferably positioned in the transport region 114 with the light source facing the base 102 and legs 106. As a result, the light source, such as a light bulb, is protected from damage during transportation. Similarly, the arm 122, handle 124, and cord 128 are also protected from abuse during transportation by being disposed within the transport region. That is, the preferred configuration of the light fixture 126 within the transport region 114 positions the arm 122, handle 124, and cord 128 between the mast 110 and the light fixture 126.
In
Additionally in
In a similar manner, a symmetrically designed light fixture 134 is illustrated in
To position the light fixture in either the deployed region 112 or the transport region 114, the hinge 118 is preferably utilized to adjust the arm 122 in relation to the mast 110.
Further, the first and second flanges 140 and 142 are configured in contacting abutment with a plurality of caps 146. The caps 146 can advantageously aid in the retention of lubrication in the hinge 118 while keeping unwanted particles out of the moving components. To facilitate securement of the arm 122 in relation to the mast 110, a pressure lever 148 capable of applying pressure to the friction member 144 is connected through the hinge 118. However, it should be noted that the use of a lever to apply pressure to the hinge 118 is not limiting as a variety of pressure applications can be utilized to secure the position of the arm 122 with respect to the mast 110.
In an alternative embodiment, a manipulation lever 150 is connected to the second flange 142 to provide efficient precision of any adjustments in the position of the arm 122. It can be appreciated that the manipulation lever 148 can be any number of configurations, sizes, and shapes as desired. While the hinge 118 is shown having an infinite number of adjustable positions in only one plane, the hinge 118 is not limited to a single plane of operation. For example, a rotating joint can be connected to the first flange 140 to allow lateral rotation of the hinge 118 in combination with the vertical rotation shown in
Turning to
In some embodiments, the recess 152 is internal to the friction member 140. As shown by the segmented recess 152, the cord 128 can occupy the recess 152 while being completely enclosed within the friction member 140. Further in various embodiments, the friction member 140 can comprise multiple pieces combine to form the recess 152. In addition, the preferred operation of the friction member 140 provides various adjustment and range of motion while maintaining the cord 128 within the recess 152 of the friction member 140. For example, the friction member 140 can have mirrored interior chambers that allow the cord 128 to enter the member 140 one side and exit the member 140 on the opposing side while remaining internal to the friction member 140 during various adjustments of the hinge 118.
In
Upon selection, any compression force on the arm 122 is removed and adjustment of the handle 124 is available. Thus, the trigger 164 allows operative selection of adjustment of the handle 124.
It should be noted that the electrical cord 128 transitions from an external position to an internal position throughout the handle 124. However, the cord 128 returns to an external position as it connects to the light fixture. The internal configuration of the cord 128 provides improved performance and safety due to the ability to adjust the handle 124 and light fixture 126 without concern for the location of the cord 128. Such lack of loose entanglements around points of adjustment such as the handle 124, hinge 118, and light fixture 126 ensure precision and safety.
Furthermore, a calibration screw 176 can be adjusted to modify an amount of frictional force applied by the handle 124 to the arm 122. It should be noted that the shape, size, and orientation of the handle 124 is not limited to the design displayed in
It can be appreciated that the exploded views of
Turning now to
Further in various embodiments, a lens 192 can engage and be secured in the lens region 184 without a fastener in a variety of different configurations, shown by segmented lines 194 and 196. That is, a lens 192 can be secured in the lens region 184 by contactingly engaging the first and second open hems 186 and 188 to form a number of different shapes, such as the convex and concave shapes of lenses 194 and the flat shape of lens 192. However, it should be noted that the number and size of open hems is not limited as a single open hem could be facilitated to secure a lens 192.
In addition, the light fixture 180 preferably includes a light source 198, such as a light bulb, that is positioned in front of the lens region 184. To clarify, the light source 198 is positioned so that a lens 192 can only modify indirect light 199. For example, if a green tinted lens 192 is secured in the lens region 184, the light will emit normal colored direct light 199′ in combination with green tinted indirect light 199 that reflects off the lens 192. Hence, the placement of the light source 198 at the same elevation as the second open hem 188 advantageously allows a large amount of indirect light to be reflected towards a desired target.
Further in step 208, the mast slides into a contacting engagement with the deployment region to provide support for the mast, arm, and light fixture. A plurality of legs can be rotated about the base in step 210 in order to provided additional support for the base and subsequent components. However, step 210 can be performed at any time during the deployment operation 200 without deterring from the spirit of the present invention.
In addition, the hinge is adjusted and secured in step 212 to provide the arm in a desired position relative to the mast. Step 214 preferably involves selecting, adjusting, and securing the radial and lateral position of the handle as well as the position of the light fixture simultaneously. Finally, in step 216 a mobile power source is attached to the transport region of the base and connected to the cord that supplies power to the light fixture.
It will now be appreciated that the various embodiments presented herein provide various advantages over the prior art. The use of these successive steps in the deployment of the novel portable light assembly can result in significant improvement in efficiency and precision of light production.
It is to be understood that even though numerous characteristics and advantages of various embodiments of the present invention have been set forth in the foregoing description, together with details of the structure and function of various embodiments of the invention, this detailed description is illustrative only, and changes may be made in detail, especially in matters of structure and arrangements of parts within the principles of the present invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.
The present application is a divisional of co-pending U.S. patent application Ser. No. 12/399,791 filed on Mar. 6, 2009, which makes a claim of domestic priority to U.S. Provisional Patent Application No. 61/034,770 filed Mar. 7, 2008.
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Number | Date | Country | |
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20120063127 A1 | Mar 2012 | US |
Number | Date | Country | |
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61034770 | Mar 2008 | US |
Number | Date | Country | |
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Parent | 12399791 | Mar 2009 | US |
Child | 13299830 | US |