1. Field of the Invention
The present invention relates to a ceiling mount light with a motion sensor. More specifically, this invention relates to a ceiling mount light with a single spherical-shaped lens to provide 360-degrees of motion-sensing coverage in any direction, whereby motion sensitivity can be adjusted up to about 30 feet in any direction with light mounted at 8 feet.
2. Description of the Related Art
Conventional decorative wall mounted light fixtures with motion sensors are available for serving as light sources in a variety of areas, such as passageways, streets, parking lots, and gardens, and are energy-efficient and have longer lifetimes due to their non-successive use. Passive infrared sensors have been utilized in various motion-sensing devices, such as light fixtures, to sense and alert the motion and/or presence of a person. Improvements came about when these passive infrared sensors were developed to include a number of lenses, facets, and detector heads, all of which can be oriented so that a person can be detected.
In view of known deficiencies associated with earlier motion detection light fixtures, the present invention is an motion activated ceiling mount light fixture which has at least one illumination source and a single spherical-shaped lens and a single motion sensor which can detect movement of heat in a 360-degree range viewing field. The motion detector assembly is removably mounted to the base plate and positioned within the lamp shade assembly such that the single spherical lens protrudes through a hollow recess, or opening, in the lamp shade assembly, which in turn is removably mounted to the base plate.
The motion sensor may be set to a set sensitivity range such that when a heat source passes within the 360-degree range viewing field, within the set sensitivity range, the luminaire emits a luminance for a set period of time, and within the set sensitivity range, the infrared motion sensing ceiling mount light may emit a lower lighting level when a heat source is not passing near the sensor. Integrated passive infrared electronics may be used as the motion sensing component mounted in the lamp housing which covers the electrical components of the light fixture. Optionally, the sensitivity regulating switch may be used to adjust the level of sensitivity of the motion sensor up to about 30 feet in any direction with light mounted 8 feet from the ground and the time regulating switch may be used to adjust the length of illumination after detection by the motion sensor. The lamp shade assembly may include a support frame, a base frame, a decorative ring encircling the hollow recess or opening, and a plurality of panels, which may be of glass. The base frame may include socket assemblies for light bulbs and a cross bar assembly to mount the fixture to the electrical junction box in the ceiling.
In another embodiment, the ceiling mount light for motion sensing may include a single spherical lens, a motion sensor with a 360-degree range viewing field, a motion detector case encasing a switch cover, a time regulating switch, two level lighting control switch and a sensitivity regulating switch, which is used to adjust the level of sensitivity of the motion sensor up to about 30 feet in any direction with light mounted 8 feet high. A rubber plug and an extension cylinder are positioned between the printed circuit board assembly and a heat shield. The lamp shade assembly has a support frame, a frame base, a bottom panel, a plurality of side panels, and a decorative ring encircling a hollow recess or opening positioned in the middle of the bottom panel. The frame base of the lamp shade assembly is removably mounted to the base plate. The motion detector assembly is also removably mounted to the base plate and positioned within the lamp shade assembly such that the single spherical lens protrude through the hollow recess in the lamp shade assembly.
Optionally, the bottom panel and the side panels are glass panels, and the bottom panel may be partitioned into multiple individual panels. The single spherical lens may be encircled with a heat sink and a partition may be positioned between the single spherical lens and a circuit control board. The heat sink may be attached to an internal triac to allow the required power to be dissipated by the device and the partition may be utilized for UL safety requirements in order to prevent access to the electronics.
In another embodiment, the motion detector includes a lamp shade assembly, a motion detector assembly, and a base plate. The motion detector assembly has a single spherical lens protruding through a hollow recess in the lamp shade assembly and is positioned on a circuit board assembly. A sensitivity regulating switch is used to adjust motion sensitivity up to about 30 feet in any direction, and the motion sensor detects motion in a 360-degree range of viewing field.
The hollow recess through which the single spherical lens protrudes may be located in the center of the lamp shade assembly. A switch case may envelop the printed circuit board assembly, a sensitivity regulating switch, a time regulating, a two level lighting control switch and switch covers. The time regulating switch may be used to adjust the length of time of illumination after motion detection. Optionally, a heat sink may encircle the single spherical lens, and a rubber plug and an extension may be removably mounted on the base plate and positioned between the printed circuit board assembly and a heat shield. A partition may be positioned between the printed circuit board assembly and the single spherical lens. The lamp shade assembly may have a support frame, a frame base mounted to the base plate, a bottom panel, side panels, and a decorative ring encircling the hollow recess. The bottom panel may be divided into a plurality of individual panels. The base plate may comprise socket assemblies and a cross bar assembly for mounting the motion detector to the electrical junction box in the ceiling.
For a better understanding of the present invention, together with other and further objects thereof, reference is made to the following description, taken in conjunction with the accompanying drawings, and its scope will be pointed out in the appending claims.
Embodiments of the present invention are described below, by way of example only, with reference to the accompanying drawings in which:
While this invention is susceptible of embodiments in many different forms, there are shown in the figures and will herein be described in detail, preferred embodiments of the invention with the understanding that the present disclosure is to be considered as an exemplification of the principles of the invention, and is not intended to limit the broad aspects of the invention to the embodiments illustrated.
The lamp shade assembly 20 may have a plurality of side panels 24 and a bottom panel 26. The panels may be glass or some other transparent or translucent material known in the art. The side panels 24 and the bottom panel 26 are supported by a support frame 22 and a frame base 30. The frame base 30 of the lamp shade assembly 20 is removably mounted to the base plate 60 in some manner, such as with a decorative nut 34, base screws 68, and base nuts 72. In the center of the bottom panel 26 of the lamp shade assembly 20 is a decorative ring 32 surrounding a hollow recess 28 through which the spherical lens 44 protrudes.
The motion sensor 48 of the motion detector assembly 40 is positioned inside the spherical lens 44 and is positioned in the center of a printed circuit board assembly 46. The motion sensor 48 is used to detect movement, and the motion sensor 48 may be a passive infrared sensor, such as, for example, Model RE200B from Nippon Ceramic Co., Ltd., and Model LHi 778 from Perkin Elmer Optoelectronics. A photocell 53 may also be utilized as a part of the electronics to make sure that the lights do not come on in the daytime. The photocell 53 is activated through light passing through spherical lens 44 and provides adequate light response to prevent on-off cycling of the light when the light is activated. A spherical partition 45 may be used to separate the spherical lens 44 from the printed circuit board assembly 46 in order to isolate the electronics from the user to prevent access to the electronics. Further, the photocell may be recessed thereby increasing the accuracy of the dark detection scheme utilized by the electronics. A time regulating switch 54 and a sensitivity regulating switch are attached to the printed circuit board assembly 46 which may be a single pole mechanical slide switch to connect different fixed resistor values to change the timing or the sensitivity of the sensor. The time regulating switch 54 and the sensitivity regulating switch 56 positioned within the motion detector assembly 40 may be adjustable switches, a variable resistor, or a variable capacitor, for manually adjusting the length of time the illumination stays on and the level of sensitivity of the motion detector. The time regulating switch 54 and sensitivity regulating switch 56 may each be covered with a switch cover 50. The printed circuit board assembly 46, the motion sensor 48, the time regulating switch 54, the sensitivity regulating switch 56, and each switch cover 50 may be enveloped in a switch case 52, which is partitioned for assembly and each part is detachable with case screws 47.
Directly above the printed circuit board assembly 46 on the opposing side of the motion sensor 48 is a rubber plug 58 which has a plurality of openings through which electrical wiring can be threaded. Rubber plug 58 prevents the ingress of moisture into the electrical compartment of the motion sensor assembly 40. The rubber plug 58 is mounted to a hollow extension cylinder 41, through which electrical wiring can be threaded. The extension cylinder 41 fits snuggly through a heat shield 43 and is attached to the center of the base plate 60 by screws 70 or other attachment mechanisms. Motion sensors in general tend to malfunction when the ceiling mount light temperature increases above about 40° C., and the heat shield 43 serves to isolate the motion sensor 48 from radiant heat generated by the light bulbs. To further prevent heat building up inside the fixture, cross-ventilation is provided in the ceiling mount light 10. Also attached to the base plate are a plurality of socket assemblies 62 for an illumination source, such as a bulb 64. The illumination sources may be incandescent or other light emitting mechanisms known in the art. The base plate 60 is attached to a cross bar assembly 66 with screws 70 and nuts which are used to mount the ceiling mount light 10 to an electrical junction box.
In the embodiments shown, the electronics and the motion detector mechanisms 40 may be kept in close proximity below the heat shield 43 due to the generation of heat from lamps 64. Temperature indications within the lamp shade area 20 may be as high as 100° C. However, since the motion sensor 48 determines movement based upon temperature fluctuations, it is necessary to separate the motion sensor 48 from the higher temperature areas of the lamp shade assembly 20. As shown in the drawings, since the ceiling mount light having 360 degree motion sensing 10 of the present invention is inverted, the heat will tend to rise away from the motion sensor 48 and electronics thereby allowing adequate readings and sensor activation. Further, the fixture 10 may have venting apertures 63a formed in the base 30 which acts in conjunction with the aperture or opening 75 to allow air to flow through the interior of the fixture and reduce the heat in the interior thereof. Of course, alternative constructions are available such that the motion sensor 48 may be completely separated from the motion detector electronics. Thus, by referring to the motion detector assembly 40, it is understood that the constituent elements may be placed in alternative and separate locations.
Referring to a second embodiment 100 of the present invention,
The lamp shade assembly 20 has a plurality of side panels 24 and plurality of bottom panels 26. The panels may be glass or some other transparent or translucent material known in the art. The side panels 24 and the bottom panels 26 are supported by a support frame 22 and a frame base 30. The frame base 30 of the lamp shade assembly 20 is removably mounted to the base plate 60 in some manner, such as with hollow rivets 38, base screws 68, and decorative nuts 73. In the center of the bottom panels 26 of the lamp shade assembly 20 is a decorative ring 32 surrounding a hollow recess 28 through which the single spherical lens 44 protrudes.
The motion sensor 48 of the motion detector assembly 40 is positioned inside the single spherical lens 44 and is positioned in the center of a printed circuit board assembly 46. The motion sensor 48 is used to detect the movement of heat and the motion sensor 48 may be a passive infrared sensor. A spherical partition 45 may be used to separate the single spherical lens 44 from the printed circuit board assembly 48 as noted herein. A heat sink 42 may be positioned around the single spherical lens 44 and mounted to a switch case 52 with pop rivet 49 or other attachment mechanisms.
A time regulating switch 54 a two level lighting control switch 56 and a sensitivity regulating switch 74 are attached to the printed circuit board assembly 46. The time regulating switch 54, the two level lighting control switch 56 and sensitivity regulating switch 74 positioned within the motion detector assembly 40 may be adjustable switches, a variable resistor, or a variable capacitor, for manually adjusting the length of time the illumination stays on when motion is sensed, stays on at reduced power level for accent lighting, and the detection range respectively. The level of sensitivity of the motion detector is up to about 30 feet. The time regulating switch 54 and sensitivity regulating switch 74 are each covered with a switch cover 50. The sensitivity regulating switch is externally adjustable with trimpot knob 51. The printed circuit board assembly 46, the motion sensor 48, the time regulating switch 54, the two level lighting control switch 56, the sensitivity regulating switch 74, each switch cover 50 and trimpot knob 51, are enveloped in the motion detector case 52, which is partitioned for assembly and each half is detachable, with case screws 47. The two level lighting control switch 56 may be utilized to allow the lights 64 to emit light at a first low luminance under non-motion sensing conditions, for example 50% illumination, and at a higher luminance when motion is detected by the motion sensor or other motion sensor 48. The time regulating switch 54 may allow the user to select how long after sensing motion the lights remain at a higher output.
Directly above the printed circuit board assembly 46 on the opposing side of the motion sensor 48 is a rubber plug 58 which has a plurality of openings through which electrical wiring can be threaded. The rubber plug 58 prevents ingress of moisture into the electronics compartment of the motion detector assembly 40. The rubber plug 58 is mounted to a hollow extension cylinder 41, through which electrical wiring can be threaded. The extension cylinder 41 fits snuggly through a heat shield 43 and is attached to the center of the base plate 60 with screws 70. Again, since these sensors and a combination of the electronics tend to malfunction when they are in contact with excessive temperatures, the heat shield 43 serves to isolate the motion sensor 48 from radiant heat. To further assist in minimizing buildup of heat in the ceiling mount light 100, ventilation holes 63 positioned between the lamp shade assembly 20 and the base plate 60 and clearance between spherical lens 44 and decorative ring 32 provide cross-ventilation.
Also attached to the base plate are a plurality of socket assemblies 62 for an illumination source, such as a bulb 64. The illumination sources may be any type of incandescent light emitting mechanism as is known in the art of motion activated light fixtures. The base plate 60 is attached to a mounting bracket 66 with mounting screws 70, which is used to mount the ceiling mount light 10 to an electrical junction box.
While there have been described what are believed to be the preferred embodiments of the present invention, those skilled in the art will recognize that other and further changes and modifications may be made thereto without departing from the spirit of the invention, and it is intended to claim all such changes and modifications as fall within the true scope of the invention.
This application is a continuation of U.S. Ser. No. 10/799,464, filed on Mar. 12, 2004, the entire disclosure of which is incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
Parent | 10799464 | Mar 2004 | US |
Child | 11532755 | Sep 2006 | US |