The present invention relates to outdoor lighting devices, particularly such as those used in gardens or to mark trails.
There has been a long felt need for a garden light having a relatively long run time, which is also battery operated, and is relatively inexpensive to manufacture.
The present invention provides a lighting device having a battery housing to hold a battery, a light housing having a light source and a lens assembly into which said light source will emit light when activated, said battery and said light source being in circuit with a switch to open and close said circuit, said light housing being moveable relative to said battery housing to motivate said switch to open and/or close said circuit.
The light housing is preferably a part of or is connected to an intermediate body portion. The intermediate body portion is slidably connected to said battery housing. The light housing or the intermediate body portion is preferably biased away from said battery housing with the bias being produced by a compression spring.
The battery housing can include an elongated switch engagement member. The intermediate body portion preferably houses a printed circuit board on which is mounted the light source and switch. The lens assembly can include a reflector around the light source. Preferably a second reflector is located away from said light source. Preferably the lens assembly includes a cylindrical lens. The cylindrical lens can have its internal surfaces frosted to assist the diffusion of light over the surface of the lens. The outside surface of the cylindrical lens can include striations or lenticules therearound.
The light housing and battery housing can be elongated. The battery housing can include a screw-on cover to access the internal portions of the battery housing. The base preferably includes a recess to receive a mounting spike. The base can also be adapted to be received by an attachable foot.
Movement of the light housing relative to the battery housing is preferably limited. The limitation of movement is preferably by means of parts of the intermediate body portion engaging formations on the battery housing.
The intermediate body portion can include at least two shoulders to engage the battery housing at two spaced locations preferably the shoulders one annular or port annular. Preferably the light source is an LED or low wattage lamp and preferably the battery is of a D size. A cap can be positioned over the lens assembly to assist in maintaining structural integrity and water resistance.
In a further preferred embodiment the circuit of the lighting device further includes a light sensitive element adapted to detect an ambient light level, and wherein said light source is illuminated in response to said detected ambient light level.
Preferably the said light source is deactivated if the detected ambient light level is above a predetermined ambient light threshold. Preferably the light source is illuminated if the detected ambient light level is below a predetermined ambient light threshold.
Preferably the light sensitive element is selected from the following light sensitive elements:
a light dependent resistor, a photodiode or a phototransistor.
Preferably the brightness of said light source is varied in response to said detected ambient light level. In use when the detected ambient light level falls within a predetermined range of ambient light levels the brightness of said light source can be either increased or decreased when said ambient light level increases. In use when the detected ambient light level falls within a predetermined range of ambient light levels the brightness of said light source can be either increased or decreased when said ambient light level decreases.
An embodiment of the present invention will now be described, by way of example only, with reference to the accompanying drawings in which:
As illustrated in
At the top of the light housing 10 is a cap 12. The battery housing cover 6 has depending therefrom a mounting spike 14 which terminates in a pointed head 16. The mounting spike 14 is indicated in
As illustrated in
The battery housing 4 includes at its upper end an elongated switch contact column 46 which terminates in a flat contacting surface 48 to engage a switch 82 mounted on the underside of printed circuit board 81.
Beneath the surface 48 and around the column 46 is a flange 41 to provide a bearing surface against which compression spring 24 can act.
The cylindrical outer surface of the battery housing 4 includes annular surfaces 43, 45, 47 and 49 which provide bearing surfaces against which parts of the intermediate body portion 8 can bear and slide. As can be seen from
The internal cylindrical surface of the intermediate body portion 8, together with flanges 83 and 85 engage and slide relative to the annular surfaces 43, 45, 47 and 49 making the slidable interconnection between the battery housing 4 and intermediate body 8 structurally sound for the purposes to which the outdoor light 2 will be put, whilst achieving slidable relative movement between the two components.
The battery housing cover 6 includes a positive battery contact 64 which makes contact with a metal contact (not illustrated) contained within the battery housing 4. The opposite end of this contact, within the battery housing 4 is connected by a wire (not illustrated) to the printed circuit board 81.
The screwed connection of the battery housing cover 6 to the battery housing 4 helps to prevent ingress of water from this connection.
The battery housing cover 6 includes in its lower portions a central, cylindrical wall 66 which receives in the internal portions thereof, the outside diameter of the mounting spike 14. The mounting spike 14 receives in its proximal end a pointed head 16.
The upper portion of the intermediate body 8 includes radially inwardly directed shoulders 84 which support the printed circuit board 81. The printed circuit board 81 is held against the shoulder 84 by means of a shaped LED support 86 which helps to prevent the LED from laterally moving relative to the printed circuit board 81. The LED 30 extends from the printed circuit board 81 so that the diode of the LED extends into the light housing 10.
The light housing 10 at its base 102 is held by means of a shoulder 104 in a groove 106 on the intermediate body 8. An internal wall 108 surrounds the LED support 86 and clamps the LED support 86 and printed circuit board 81 into position as illustrated in
The upper portion of the light housing 10 is a lens assembly 110. The lens assembly 110 is made from a transparent or translucent material with the internal wall 112 having a frosted finish to help diffuse light over the cylindrical surface of the lens assembly 110.
The external surface of the lens assembly 110 is made up of striations or lenticules 114 which are generally annular in nature and surround the external surface of the lens assembly 110. The upper end of the lens assembly 110 includes a reflector surface 116 whilst the internal face 118 of the surface 108 is also a reflector surface. Thus any light emitted by the LED 30 will reflect off the surfaces 118 and 116 which helps to reflect light through the cylindrical wall of the lens assembly 110.
The cap 12 has a cylindrical recess 122 to receive the upper end of the lens assembly 110. The lens assembly 110 and the intermediate body 8 are made from two halves which are sonically welded together. However, for structural integrity, the cap 12 is positioned by means of a compressed fit and/or sonically welded to the lens assembly 110 thus helping to keep the lens assembly 110 as an integral unit.
In use, the outdoor light 2 is assembled by first pushing the mounting spike 14 with pointed head 16 into the ground. If desired, additional mounted spikes 14 and pointed heads 16 can be added end on end to produce a conjoined mounting spike of a desired height. Once the mounting spike 14 is in the ground, an assembly of the battery cover 6, battery housing 4, intermediate body portion 8, lens assembly 10 and cap 12 is positioned onto the mounting spike 14 by sliding the cylindrical recess formed by cylindrical wall 66 over the upper end of mounting spike 14.
Once fully assembled, the outdoor light 2 can be switched on by pushing downwardly in the direction of arrow 200 against the cap 12 which will force the light housing 10 and intermediate body portion 8 to move relative to the battery housing 4 against the bias of spring 24, thereby pushing the switch 82 against the surface 48 atop of the column 46. This downward action will close the circuit if it is open thus illuminating the LED 30 and the lens assembly 110. To switch off the outdoor light 2, the cap 12 is pushed in the direction of arrow 200 to open the circuit.
In another embodiment, the outdoor light 2 can include circuitry to switch off the LED 30 as the level of ambient light increases. Such a light sensitive embodiment will include at least one light detector, such as a light dependent resistor (LDR), photodiode, phototransistor, or other optically sensitive circuit component. The light detector(s) is mounted on the light 2, such that it is able to detect the level of ambient light in the vicinity of the outdoor light 2.
In order to prevent the light emitted from the outdoor light 2 activating the light detector and turning the LED 30 off, the light detector should be mounted such that the light omitted from the LED 30 does not impinge upon it, for example by mounting the light detector facing upward on the top face of cap 12, or on the lower end of the intermediate body portion 8. Other measures to prevent the LED 30 activating the light detector may also be employed, such as selecting the LED 30 or light detector such that the omission spectrum of the LED 30 falls outside the response spectrum of the light detector. The sensitivity of the light detector, or associated circuitry, can also be selected such that the light emitted by the LED 30 of the outdoor light 2, or an adjacent outdoor light of the same type, does not activate the power down mode.
It is envisaged that by selecting appropriate circuitry the light sensitive power down mode can operate to turn the LED 30 off when the ambient light reaches a particular intensity. Advantageously, once the user has placed their outdoor light 2 in the ground and activated it by pushing down on the cap 12, the user then does not need to turn the light off. This will automatically occur when the sun comes up or a brighter light source is used to illuminate an area. In either case, the use of the outdoor light in bright conditions would be unnecessary and lead to an unwanted drain on the light's batteries.
Alternatively the light detector could be configured to switch the LED 30 on and off as appropriate as the ambient light changes. Thus once the user has placed their outdoor light 2 in the ground and activated it by pushing down on the cap 12 the LED will come on and turn off as required. This embodiment is particularly advantageous when setting up the outdoor light during the day, for use during the night. Thus the outdoor light can be placed in a desired position and activated, but will not turn on the LED until the sun sets, thus allowing early activation of the light, without unnecessary use of the battery's power while the sun is up when the outdoor light will have limited effect.
In a further embodiment, the circuit and light detector can be configured to control the intensity of the LED's 30 output to compensate for changes in ambient light. This embodiment is similar to that described above. However, rather than simply using the light detector to turn the LED on or off, the circuit is configured such that the light emitted by LED 30 ramps down as the ambient light increases, or ramps up as the ambient light decreases. A combination of the two modes of operation can also be used. In such an embodiment the LED is not illuminated until the ambient light falls below a predetermined threshold, but once the LED is illuminated, its intensity is varied to compensate for changes in ambient light. If the ambient light increases over a predetermined level the LED is deactivated.
Alternatively, the variation in illumination intensity of the LED may be varied so that over a predetermined range of ambient light levels the brightness of the light source increases with increasing ambient levels, so as to render the brightness of the LED as perceived by a viewer, to be constant. This mode of operation may be particularly advantageous if the outdoor light is being used to mark a path, walkway or the like, and it is necessary to ensure the pathway can be easily discerned in conditions of varying light.
Illustrated in
In
It will be understood that the invention disclosed and defined herein extends to all alternative combinations of two or more of the individual features mentioned or evident from the text or drawings. All of these different combinations constitute various alternative aspects of the invention.
The foregoing describes embodiments of the present invention and modifications, obvious to those skilled in the art can be made thereto, without departing from the scope of the present invention.
Number | Date | Country | Kind |
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PR5749 | Jun 2001 | AU | national |
This is a continuation of application Ser. No. 11/633,746, filed on Dec. 5, 2006, now U.S. Pat. No. 7,520,631, which was a continuation of application Ser. No. 10/481,374, filed Jun. 1, 2004, now U.S. Pat. No. 7,188,967, which was the National Stage of International Application No. PCT/AU 02/00720, filed Jun. 4, 2002, which claims the benefit of Australian Application No. AU PR 5749, filed Jun. 18, 2001.
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Number | Date | Country | |
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20090195167 A1 | Aug 2009 | US |
Number | Date | Country | |
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Parent | 11633746 | Dec 2006 | US |
Child | 12365221 | US | |
Parent | 10481374 | US | |
Child | 11633746 | US |