LIGHT FIXTURE MOUNTING BRACKET ASSEMBLY

Abstract

A mounting plate assembly has a mounting plate for mounting a light fixture in holes of different diameters and wherein a guide rail assembly is secured to a rear face of the mounting plate on opposed sides of an aperture. Each guide rail assembly has a novel displaceable spring clamp structure having to a displaceable base coupled for sliding displacement along a guide rail assembly. Spring biasing elements are provided between the displaceable base and the guide rail assembly to urge a bottom face of the displaceable base against a flat top surface of a mounting base to which the guide rails are secured. A retention formation is provided in the bottom surface of the displaceable base for retention coupling with a selected one of space-apart engageable retainers immovably secured to the flat top surface of the mounting base and aligned with the retention formation to arrest the displaceable base at a desired location to position the spring clamp structures at a desired location with respect to the size of a hole formed in the sheet material and to which a light fixture is to be secured.

Claims

1. A mounting plate assembly for mounting a light fixture in holes of different diameters formed in sheet material, said mounting plate assembly comprising a mounting plate having an aperture to provide a passage there through, a displaceable spring clamp structure secured to a rear face of said mounting plate on opposed sides of said aperture, each displaceable spring clamp structure being displaceable along an associated guide rail assembly, each displaceable spring clamp structure having a displaceable base coupled for sliding displacement along its associated guide rail assembly, a spring biased clamp arm secured to said displaceable base, spring biasing means between said displaceable base and said guide rail assembly to urge a bottom surface of said displaceable base against an engageable surface there under, a retention formation provided in said bottom surface of said displaceable base for retention coupling with a selected one of space-apart retainers immovably secured to said engageable surface and aligned with said retention formation to arrest said displaceable base at a desired location with respect to the size of a hole formed in said sheet material and to which a light fixture is to be secured, said spring biased clamp arms providing a spring force for urging said mounting plate in a direction of said hole with said spring biased clamp arms spring biased against an inner surface of said sheet material adjacent said hole.

2. The mounting plate assembly as claimed in claim 1 wherein said displaceable base is a mounting base with said guide rail assembly being constituted by opposed straight guide rails secured to said mounting base in spaced parallel relationship, said displaceable base being retained for captive displaceable retention between opposed elongated channels formed by said guide rails.

3. The mounting plate assembly as claimed in claim 2 wherein said spring biasing means is provided by spring elements secured between opposed flange formations of said displaceable base and a projecting shoulder formation of said elongated channels to permit said displaceable base to be moved upwardly in a vertical space formed between said flange formation and an underface of said projecting shoulder formation by the application of an upward pulling force on said displaceable base.

4. The mounting plate assembly as claimed in claim 3 wherein said retainers are comprised by projecting nipple heads mounted on engageable surface and disposed in a straight line at predetermined space intervals, said retention formation being a retention hole formed in said bottom surface of said displaceable base and disposed in alignment with said straight line, said retention hole being dimensioned for close captive retention of one of said projecting nipple heads when disposed thereover.

5. The mounting plate assembly as claimed in claim 4 wherein said mounting base has a flat bottom wall for connection to said mounting plate rear face on said opposed sides of said aperture, said opposed straight guide rails projecting upwards at right angle from opposed side edges of said flat bottom wall with said projecting shoulder formations facing inward and spaced above a top surface of said flat bottom wall constituting said engageable surface, said shoulder formations defining a flat underface extending parallel to said top surface of said flat bottom wall and spaced a predetermined distance wherein said vertical space is greater than the height of said projecting nipple heads.

6. The mounting plate assembly as claimed in claim 5 wherein said opposed flange formations are elongated flat flanges of rectangular cross-section having a thickness inferior to said vertical space of said elongated channels permitting vertical displacement of said mounting base a distance equal to or greater than said height of said projecting nipple heads.

7. The mounting plate assembly as claimed in claim 3 wherein said spring elements are constituted by a compression spring module sized for retention in a hole formed in a top surface of said opposed flange formations and projecting thereabove to engage a said underface of said projecting shoulder formation.

8. The mounting plate assembly as claimed in claim 7 wherein said compression spring has a friction head to provide a smooth engaging wear-resistant surface against said uderface of said projecting shoulder formation.

9. The mounting plate assembly as claimed in claim 3 wherein there is further provided an electrical junction box secured to said rear surface of said mounting plate over said aperture wherein said aperture provides access to the interior of said electrical junction box.

10. The mounting plate assembly as claimed in claim 3 wherein there is further provided an LED lamp driver module secured to said rear surface of said mounting plate over said aperture wherein said aperture provides passage of wiring from said driver module for connection to LED lamps provided in a light housing secured to said mounting plate and projecting forwardly thereof.

11. The mounting plate assembly as claimed in claim 1 wherein said spring biased clamp arm is secured to a torsion spring supported at an elevated position by a vertical bridge support secured to said displaceable base, said clamp arm being biased by said torsion spring in a downward direction towards said rear surface of said mounting plate.

12. The mounting plate assembly as claimed in claim 1 wherein said mounting plate is one of a generally square contour, a rectangular contour and circular contour and variations thereof.

13. The mounting plate assembly as claimed in claim 1 wherein said mounting plate is further provided with junction box attachment slots disposed on two spaced apart circumferential axis spaced from said passage to provide connection to junction boxes of two different diameters for connection thereto by screw fasteners.

14. The mounting plate assembly as claimed in claim 1 wherein said displaceable spring clamp structure is secured on said opposed sides of said aperture in diametrically aligned relationship, there being one or two pairs of said guide rail assemblies with the pairs of guide rails disposed at right angle to one another..

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] The above noted features of the present invention will now be described with reference to certain example embodiments, when read with reference to the accompanying drawings in which:

[0018] FIG. 1 is a simplified perspective view of an embodiment of the mounting plate assembly of the present invention;

[0019] FIG. 2 is a rear top view of an example of another embodiment of the mounting plate assembly as secured to a flat rectangle shaped light fixture;

[0020] FIG. 3 is a side view of FIG. 2;

[0021] FIG. 4 is an exploded view of the component parts of the displaceable spring clamp structure showing the construction of its individual parts;

[0022] FIG. 5 is a fragmented section view illustrating the spring bias connection between the displaceable base and the guide rails as well as the retention formation engaged with a retention nipple head;

[0023] FIG. 6 is a bottom view of the displaceable base showing the location and shape of the retention formation and its displacement to secure it at different locations depending on the hole diameter;

[0024] FIG. 7 is a perspective view similar to FIG. 1 but showing an example of a further embodiment wherein an electrical junction box is secured to the mounting plate over the aperture;

[0025] FIG. 8 is a simplified side view showing the replacement of an existing light fixture by the use of the mounting plate of FIG. 1 and the securement of additional mounting plates of the embodiment of FIG. 9 with the power leads from the existing junction box providing power to the additional mounting plate assemblies whereby an existing light fixture can be replaced by two or more different light fixtures;

[0026] FIG. 9 is a rear top view of of an example of another embodiment of the mounting plate assembly as secured to a rectangular mounting plate to which is connected a rectangular light fixture, and

[0027] FIG. 10 is a side view of FIG. 9.

DETAILED DESCRIPTION OF THE DRAWINGS

[0028] Before any embodiments of the present invention is explained in detail, it is to be understood that the application is not limited to the details of construction and the arrangement of component part set forth in the following description or illustrated by the following drawings. Further, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting but should encompass equivalents thereof.

[0029] Referring now to the drawings and more particularly to the example of the preferred embodiment depicted by FIGS. 1 and 4, there is shown the basic component parts of the mounting plate assembly 10 and the displaceable adjustable spring clamp structure 12. The mounting plate assembly 10 has a mounting plate 11 usually constitute by a flat metal plate provided with cut-outs and holes for attachment to an electrical junction box and providing attachment thereto of a light fixture. The mounting plate assembly 10 of the present invention provides additional functions compared to known mounting plates and is provided with a novel displaceably adjustable spring clamp structure 12 which permits the mounting of the mounting plate assembly to pre-formed holes of different sizes formed in sheet material. The displaceable spring clamp structure 12 can also be easily adjusted by the use of a user person’s fingers without the need of tools.

[0030] The mounting plate 11 has an aperture 13 to provide a passage therethrough of wiring, when mounted over an electrical junction box, or for the mounting of a light source inside a recessed housing if the light fixture is of a canister type, not shown but obvious to a person skilled in the art. A guide rail assembly 14 is secured to a rear face 15 of the mounting plate 11 on opposed sides of the aperture 13, and as herein show, these are diametrically aligned with one another on a straight axis. Each guide rail assembly 14 supports an adjustable spring clamp bracket 20 mounted for its displacement along a pair of guide rails 16. The spring clamp bracket 20 is connected to a displaceable base 17 coupled for sliding displacement along and between its associated guide rails 16 to position the spring clamp bracket 20 at a desired location. The displaceable base 17 is arrested at the desired location by retention means, as described herein below, to permit and the mounting of the mounting plate assembly in a pre-formed hole of a certain diameter whereby to mount a new light fixture attached to such hole.

[0031] As shown in the exploded view of FIG. 4, the displaceable spring clamp structure 12 is described. The guide rail assembly 14 comprises a mounting base 21 to which is integrally formed the pair of spaced-apart substantially parallel guide rails 16. The displaceable spring clamp bracket 20 is retained between the pair of parallel guide rails 16 for displacement therealong. The displaceable spring clamp bracket 20 is secured to the displaceable base 17 which is held displaceably captive between the guide rails 16. The displaceable spring clamp bracket 20 has a spring biased clamp arm structure 22 secured to a torsion spring 23 supported at an elevated position by a horizontal bridge arm support 24 formed at a top end of a vertical bridge support plate 25 secured to the top surface 26 of the displaceable base 17 by an attachment flange 26 and a screw fastener 29 which engages in a preformed screw retention hole 30 in the top surface 31 of the displaceable base 17.

[0032] The torsion spring 23 has a helical spring section 23′ retained about the bridge arm support 24 and its opposed ends are formed as straight arms 32 disposed parallel to one another and extending in a common plane. The free ends of the straight arms 32 are interconnected by a surface engaging pad structure 33 formed of plastics material or other material not to damage the interior surface of the gypsum board sheeting material to which it is usually spring biased against. The spring biased clamp arm structure 22 is spring biased in a downward direction, as illustrate by arrow 27 by the torsion spring 23 and the pad structure 33 rests in a full downward position. Therefore, to position the spring clamp structures 12 in a hole, it is necessary to move the spring biased clamp arms of the clamp brackets 20 upwardly to place then in the hole while pushing the mounting plate towards the hole. The clamp arms are release as soon as the engaging pads 33 are inside the hole, and all of this procedure is well known in the art.

[0033] As herein shown, the displaceable base 17 is formed of a rigid metal piece of rectangular shape and defines a flat top surface 31 and a flat bottom surface 31′. The displaceable base is also formed with opposed flange formations 32 which project outwardly from a bottom section of the opposed side walls 33 of the displaceable base 17. The opposed guide rails 16 are formed with inwardly projecting shoulder formations 34 spaced above the flat top surface 26 of the mounting base 21 to form an open elongated channel 35 thereunder with the opening of the channel facing inwards over the flat top surface 26 of the mounting base 21. As shown in FIG. 5, these channels 35 have a height “h” greater than the thickness “t” of the flange formations 32 whereby to define a space 36 therebetween when said shoulders of said displaceable base is positioned thereunder, as herein illustrated. The flange formations 32 are elongated flat flanges of rectangular cross-section. In this particular embodiment the guide rail 16 is further provided with an attachment flange 16′ provided with holes 16″ for receiving fasteners (not shown) for securing the displaceable spring clamp structure 12 in u-shaped openings 11′ formed in the mounting plate 11 on opposed sides of the aperture 13. This is only one form of attachment of the displaceable clamp structure and other modifications are to be contemplated if it is to be mounted differently depending on the shape and mounting structure of different types of light fixtures.

[0034] Spring biasing means is mounted in a top surface 37 of the flange formations 32 to receive a spring elements 38 in the form of a small compression helical spring module sized for retention in a small retention hole 39 formed in the top surface 37 of the flange formation 32. The spring elements 38 have a friction head 40 to provide a smooth wear-resistant surface for displacement against an underface 34′ of the shoulder formations 34. As shown in FIG. 5, the opposed flange formations 32 of the displaceable base 17 project under the shoulder formations 43 in the space 36 when the displaceable base is secured to the guide rail assembly 14 for displacement therealong. The spring elements 38 spring biases the bottom surface 31′ of the displaceable base 17 against the flat top surface 26 of the mounting base 21.

[0035] With additional reference to FIG. 6, which is a bottom view of the displaceable base 17, it can be seen that a retention formation, in the shape of a hole 41, is formed at a predetermined position in the bottom surface 31′ of the displaceable base. As shown in FIGS. 3 and 5, retention formations in the form of rounded nipple heads 42 are secured to the flat top surface 26 of the mounting base 21 and disposed in predetermined spaced relationship along a straight axis which is aligned with the hole 41. Accordingly, when the displaceable base 17 is moved over the flat top surface 26 of the mounting base 21, and the hole 41 of the displaceable base is located over a nipple head 41, the displaceable base is arrested by the downward spring force exerted by the spring elements 38. In order to displace the displaceable base 17 over the flat top surface 26 of the mounting base 21 it is necessary for a user person to apply an upward pulling force on the displaceable base, to disconnect it from engagement with a nipple head, and this is accomplished by grasping the spring clamp bracket 20 with the fingers and pulling it upwards causing the spring elements 38 to compress and the displaceable base to move upwards out of its engagement. The displaceable base is then shifted toward another nipple head, see 42′ in FIG. 6, and released when in the vicinity of the other nipple head whereby its bottom surface 36 is biased against the other nipple head by the spring elements 38 and the hole will then clamp over the other nipple head as shown at 41′ being clamped over the nipple head at 42′. Accordingly, the spring clamp bracket immovably retained at a different location. As herein shown, two spaced nipple heads 42 are secured at predetermined locations corresponding to known hole sizes, such as holes of 4 or 6 inches. To identify the positioning of the base to place the spring clamp brackets at the proper position depending on the hole size, markings 62 can be printed or inscribed on the top surface of the guide rails 16, as shown in FIG. 4. FIG. 6 illustrates the base 17 engaged at these two positions of 4 and 6 inch spacing.

[0036] With reference to FIGS. 2 and 3, there is illustrated a mounting plate assembly 45 wherein the mounting plate 47 is of a square contour and has an LED driver module 46 mounted thereon. The aperture 13 provides access to the driver module 46 to connect wiring to provide operating current to LED lamps provided in a light fixture (not shown) securable to the mounting plate. Also, four displaceable spring clamp brackets 12 are mounted thereon and disposed in two pairs with the spring clamp brackets diametrically aligned and the pairs secured at right angles to one another. Such is desirable when supporting heavy light fixtures. As can be seen, the mounting plate 47 is herein provided with junction box attachment slots 48 and 48′ disposed on two spaced-apart circumferential axes to provide a different use for the mounting plate for connection to existing junction boxes of two different diameters and connectable thereto by screw fasteners. Accordingly, when the mounting plate 45 with the driver module 46 is secured to a junction box the power leads of the junction box secured to the LED driver module 46, with the module being of a small size housed within the junction box. As herein shown the LED light fixture frame 49 is secured to the mounting plate 47 by proper fasteners and its lens cover 50 thereafter attached to the frame 49 by conventional fasteners.

[0037] FIGS. 9 and 10 show as similar mounting assembly to that of FIGS. 2 and 3 but showing that the mounting plate 52 can be constructed of a different configuration, herein an elongated rectangular mounting plate and provided with only two displaceable clamp structure 12 secured in diametrical alignment. As shown, a junction box 63 or LED module 46 is mounted on the mounting plate 52. FIGS. 9 and 10 further illustrates the mounting plate 52 being attached to an elongated LED light fixture 65 and wherein the mounting plate 52 is secured to its frame 66 to which is attached a lens 67.

[0038] FIG. 10 shows the LED light fixture 65 mounted in a hole 68 formed in sheeting material 69 with the spring biased clamp arms 32 spring biased over the inner surface 70 of the sheeting material adjacent the hole 68.

[0039] With reference to FIGS. 7 and 8, there is shown a mounting plate assembly 10′ similar to FIG. 1, but wherein a junction box 55 is mounted about the aperture 13 which in this figure is concealed by the junction box 55 secured to the rear wall 15′ of the mounting plate 11′. The aperture 13 provides access to the junction box 55. The mounting plate 15′ may have different contour shapes, such as hexagonal as herein illustrated, or round, square or rectangular as shown in FIGS. 2 and 9, or variations thereof. Such an embodiment is desirable when replacing an existing light fixture with additional and different light fixtures. Such is illustrated in FIG. 8, wherein an old fixture 56, shown in phantom line, is removed from its junction box 57 and replaced by a more modern LED light fixture 58 having its driver module 59 which mounts inside the junction box 57 and further wherein additional LED light fixtures 58′ can be mounted at different locations with their power received from jumper wires 60 coupled to the power leads existing in the junction box 57. Accordingly, such mounting plate assembly 10′ permits a user person to replace an existing fixture, such as a chandelier or any type, with one or more modern LED fixtures or incandescent lamp fixtures of a different designs and such replacement can be made by a user person without the use of electricians or carpenters. The only work requirement is to remove the existing light fixture assembly and to disconnect its connecting wires from the power leads from the junction box. Holes are cut into the sheeting material at desired locations where additional replacement light fixtures 58′ need to be mounted and to bring the additional wiring 60 from the junction box to the new mounting holes to connect to the new fixtures and to mount the new fixtures in the holes by the use of the spring clamps 12′, as shown in FIG. 8.

[0040] Many modifications and other embodiments of the present invention as described above will come to mind to a person skilled in the art to which the invention pertains having the benefit of the teachings described herein above and the drawings. Hence, it is to be understood that the embodiments of the present invention are not to be limited to the specific examples thereof as described herein and other embodiments are intended to be included within the scope of the present invention and the appended claims. Although the foregoing descriptions and associated drawings describe example embodiments in the context of certain examples of the elements and members and for functions, it should be understood that different combinations of elements or substitutes and/or functions may be provided by different embodiments without departing from the scope of the present invention as defined by the appended claims. Furthermore, although specific terms are employed herein, they are used in a generic and descriptive sense only and other equivalent terms are contemplated herein with respect to the items that they relate to. It is therefore within the ambit of the resent invention to encompass all obvious modifications of the examples of the preferred embodiment described herein provide such modifications fall within the scope of the appended claims.