Wax candles and candle lamps which use liquid fuel are traditionally used in multitudes of settings and applications. Open flames present a danger to both people and property. Open flame devices have inherent tendencies to extinguish in windy conditions or when it is raining. Open flame devices consume natural resources and expel dangerous toxins and particulates, which make them a concern for the health of any person within their vicinity. The present invention is designed to address all of these problems and provide solutions.
Conventional candles, and similar lighting devices with open flames for their light output, have a flame which “flickers”. The flicker in conventional candles typically appears to be random. In order to emulate the look of an open flame device, the present invention combines the pseudo-random flickering of a light-emitting device driven by electronic circuitry and encloses these components in a material which hides the components, yet allows the light output of the components to penetrate through the outside material.
The present invention may be powered be battery, or plugged into an A.C. power outlet with the addition of an AC to DC power supply. More than one candle may also be used together with a two-conductor wire allowing for multiple units driven by one low voltage power supply, approximately 3-14 volts or less. These multiple units can be commonly, but not exclusively, used in a fireplace instead of an actual fire, clustered in a chandelier to give a more realistic appearance, or as an outside arrangement on a patio or deck.
The electronic circuit, which includes a micro-controller or a solid state passive circuit, manipulates the amount of electrical current transmitted to the light-emitting device at any given time. The appearance of the invention can be changed in a multitude of ways by changing either the software code in the microcontroller, or changing the resistor values in the passive circuit. As a result of changing the resistor values (for example, a potentiometer may be used) or the software, the appearance of the flame of the candle will also change. The deviations in the software or the resistors represent a substitution in one or more of the values of the formula that governs the light emitting device, but does not require a change in the design or layout of the circuits. Both circuit designs allow for the use of a single on/off switch, or multiple switches. In the multiple switch configuration, the user can change the speed of the flicker and/or the type of the flicker providing a more realistic simulation, particularly when multiple units are grouped together and set at different flicker speeds and flicker types.
As the light-emitting device of the present invention is powered by electricity, it releases none of the toxins or particulates that are commonly associated with open flame devices. These toxins and particulates increase the risk of health problems and can be especially problematic for young people and people with lung or asthma conditions. Individuals who use oxygen to assist their breathing cannot be in the vicinity of an open flame due to the flammability of oxygen. The present invention allows these people to enjoy the appearance of candle light or a flame without the risks that an open flame would pose.
The present invention is designed to replace wax candles, liquid fuel lighting containers as well as many other applications in which flames have been used. The present invention includes an apparatus comprising one or more light emitting devices, attached to a circuit which may be driven by either a microcontroller or passive components. An open flame emulator is disclosed which is powered electrically, and comprises an electronic circuit driving a light-emitting device in a pseudo-random manner. The components of the invention are housed in a material that will both hide the components and allow the light produced by the light-emitting device to be transmitted through the material providing a realistic emulation of a traditional open flame.
The electronic circuit of the present invention, in all of the embodiments, is designed to control the amount of electricity which flows into the light-emitting device at any given time period. The electronic circuit may be housed inside of a plastic enclosure or pod which may be inserted, for example, in the underside of a cylindrical candle. The pod is designed to be readily removable from the housing so that the consumer can change the circuits for driving the light emitting device such that the consumer can decide which features are desirable at any time. The entire pod with the circuits enclosed is inserted into an outer housing.
The electronic circuit is adjustable by way of various switch configurations also located on the underside of the housing. In a preferred embodiment of the invention, a slide switch or switches permits adjustment of the type and/or speed of the flicker.
The housing, in a preferred embodiment, is made with scented wax with additives which improve the stability and longevity of the wax itself. Other materials which provide a substitute for wax may also be used which include a self-skinning, expanding polyurethane foam which is almost identical in appearance to wax. An aromatic liquid or strip may also be added to provide a desired scent. The final apparatus can be placed in a multitude of applications and can be used to replace any type of product that uses, or can use, an actual flame to produce light.
The maximum current level in the circuit of the first embodiment shown in
The transistors Q1 and Q2 are arranged as a multi-vibrator circuit. When Q1 is on and Q2 is off, the base voltage of Q2 will increase gradually as the capacitor connected to the collector of Q1 begins to discharge through the resistor R4. When the base voltage of Q2 reaches approximately 0.6 volts, the base-to emitter voltage of Q2, Q2 changes state from on to off. When the base voltage of Q1 reaches approximately 0.6 volts, Q1 changes from off to on. The oscillation frequency determines the flicker frequency of the candle. The oscillation frequency of the multi-vibrator is set by the time constant, the values of the resistors and the capacitors.
The output of the multi-vibrator is a pulse or square wave form. However, in order to simulate the flicking candle flame, the pulse must be transformed to a modified sine wave or a type of triangle wave is required. The square wave is transformed into a a modified sine wave (hereinafter called the “RC wave”) using Capacitors C1 and C2 forming the RC circuit. The magnitude of the base current of Q3 is controlled by the selection of the resistor values of R5 and R6 which also sets the RC time constant and the frequency of the sine wave. Thus, when Q2 is off, Q3 effectively acts as a diode, such that all of the current will flow from output of capacitor C2, in the form of the RC wave, through the lamp slowly changing the brightness of the lamp making the light flicker. When Q1 is on, the idling current will follow from the collector of Q3 through the lamp L1 and will produce the minimum amount of brightness.
A switch on the housing may be used to apply power to the circuit in the on position, or cut off power in the off position as shown in
The entire circuit is connected directly to the battery source of DC power and can also be run from a standard AC outlet with an AC to DC power supply having a regulated output of approximately 2-5 volts DC. Diode D1 provides reverse battery protection in the event that the user inadvertently inserts the batteries backwards. Light-emitting device LP1, in this circuit, an incandescent bulb, is driven by transistor Q1. Transistor Q1 boosts the current capability of the microcontroller output from 0.02 amps to over 0.5 amps.
A pulse-width modulator may be created either with hardware or using software. Utilization of a microcontrollers, such as the one described above, implements a pulse-width modulator (PWM) using a timer interrupt. Using an internal 4.0 MHZ oscillator, the basic timer period of the clock is 100 microseconds, implemented on a hardware interrupt basis. The PWM period is selected to be 100 times the timer period (10,000 microseconds or 10 milliseconds) so that decimal numbers may be entered for the corresponding bulb amplitudes. The PWM modulation is implemented in software by looking up the time period of the “on” cycle from a table with pre-determined values, the table being selected by slide switch SW2. The number selected is a decimal number from. the look up table from 0 (off) to 100 (on for the entire time period) for the 10-millisecond period. The “off” period of the PWM is 10 milliseconds minus the on period. The ratio of on to off periods is the duty cycle of the PWM. With a 50% duty cycle, the PWM is ON for 50 milliseconds and off for 50 milliseconds, the net power delivered to the light emitting device is 50% of maximum. For a duty cycle of 10%, the PWM and light-emitting device are on for 10 milliseconds and off for 90 milliseconds. By varying the power delivered to the load on a repetitively timed basis, the light-emitting device can be made to flicker just as in an actual open flame device such as a candle, a fireplace or any pattern which the user finds attractive. The present invention is designed so that the consumer can experiment with different flicker frequencies, brightness patterns creating his own unique lighting sequences.
The mode and speed of operation is determined by two different slide switches, SW1 (4 positions, single pole) and SW2 (3 positions, single pole). However, it will be appreciated that many different types of control devices known in the art may be used to provide external control of the mode, speed and brightness of the light. In the preferred embodiment shown in
When the switch SW2 is placed in the “Smooth Mode” to generate the slower flicker, an internal table of 256 different 8-bit values is selected. The magnitude of the steps or pulses do not change drastically from step to step giving the appearance of smooth transitions in light levels from higher to lower levels and back, such as an open flame device flickering in a room environment.
When switch SW2 is in the “Abrupt Mode”, an internal table of 256 different 8-bit values is selected which corresponds to PWM levels that occasionally make more drastic differences in intensity from step to step. The “Abrupt Mode” emulates an open flame device that is being used in the presence of a “breeze” or more turbulent ambient air situations. Hence, the abrupt mode causes the lamp to flickers more from higher light intensity levels to lower levels and back.
The speed settings are also derived from the timer interrupt of 10 ms and determine the number of changes in intensity per second. An internal software divider implemented from the basic timer interrupt determines this value as input from slide switch SW1. On the slowest setting, there are 10 updates per second so the table of 256 values is repeated every 25.6 seconds. On the medium setting, the update is about 15 times per second so that the table is repeated about every 17 seconds, and on the fastest setting, the update is about 22 times per second so that the table is repeated about every 11 seconds.
The mode switch SW2 operates by selectively grounding Pins 2, Pin 5, or neither. These logic levels are monitored and selected internally by the software code listed in
When SW2 is in the “Continuous on Mode”, the light-emitting device is turned on at 100% power level (Constant on). There is no time-dependant modulation and the software pulse-width modulator is turned off. In the “Continuous on Mode”, the invention produces a non-varying light output with the software-created pulse width modulator turned off.
One of the preferred embodiments is a cylindrically-shaped wax housing, or simulated wax using self-skinned expanding polyurethane foam. This embodiment of the invention can be seen in Applicants' Design Pat. No. US D488,582 which is incorporated herein by reference.
It is desirable for the power supply to be at least one battery, in a preferred embodiment, so that when a wax candle is utilized, the power supply can be self-contained within the housing so that an AC power cord is not required. The batteries may be alkaline batteries or in another preferred embodiment, the batteries are rechargeable. When the electronic candles are use for “hospitality” purposes, such as at a restaurant table, with rechargeable batteries, the batteries can be removed each day, recharged, and returned to the candle. It substantially reduces restaurant owners' expenses to use rechargeable batteries rather than to replace them with new batteries. With prior art electronic candles, the batteries are not made to be replaceable, forcing the restaurant owners to purchase a new candle each time the batteries are no longer functional.
If scent, in addition to or in place of scented candle wax is desired, a removable scent strip may be added. Further, a reservoir of liquid scent can be added to the flame emulator apparatus which is activated upon application of heat generated by the electronic circuit.
Another preferred embodiment includes a photo sensor so that the flame emulating device can be automatically activated in response to changes in ambient light. For example, a circuit is disclosed in
The circuit disclosed in
The foregoing description of preferred embodiments is intended to be illustrative of possible devices which utilize the present invention and not intended to limit the scope of the present invention. It will be appreciated that there are various combinations using known components which are variations of the present invention as defined in the following claims.
This Application claims the benefit pursuant to 35 U.S.C. 119(e) of U.S. Provisional Patent Application Ser. No. 60/588,100, filed by the applicant on Jul. 15, 2004. Applicants also refer to their Design Pat. No. D488,582 issued Apr. 13, 2004 and incorporates it herein by reference.
Number | Date | Country | |
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60588100 | Jul 2004 | US |