Generally, this application relates to electronic flameless candles. Such a flameless candle includes one that simulates a flickering effect on an artificial flame element that is viewable to an observer.
According to certain techniques described herein, a flameless candle includes a candle body, a light source, and a flame element. The candle body includes an inner region and an upper surface including an aperture. The light source is energized and de-energized selectively to control whether or not a light is emitted. The light source may be located in the inner region of the candle body. The flame element has an interior region, an interior surface, and an exterior surface. The light emitted by the light source is emitted towards the interior region of the flame element, such that it passes through the interior region and onto the interior surface. The flame element is at least partially transparent or translucent, such that it permits the light to propagate through the flame element and outwardly from the exterior surface. The flame element may have at least one ridge on the interior surface and/or the exterior surface. Such ridge(s) distort the light. While the light is emitted, the flame element moves with respect to non-moving portions of the candle body.
The flame element may move by floating on a fluid. Such a fluid may be a liquid or forced air. Also during operation while the light is emitted, at least a portion of the flame element extends through the aperture in the upper surface. When the light is not emitted, a smaller portion or no portion of the flame element may extend through the aperture.
If the fluid is forced air, the candle may include a fan that forces the air towards the flame element during operation of the candle. A deflector may be employed, where the deflector includes at least one obliquely-oriented portion (i.e., not perpendicular or parallel to the primary axis of the candle). The deflector induces turbulence in the forced air before the air impinges on the flame element. The candle may include an airflow director with a hollow region. The flame element may rise through the hollow region after the fan is turned on. When the flame element reaches a predetermined height (either inside or outside of the airflow director), the flame element stops rising and begins hovering. It should be understood that hovering may cover activity when the flame element momentarily rises and falls. In other words, hovering as used herein does not imply that the flame element has a perfectly constant altitude during operation of the candle. The flame element may begin hovering at the predetermined elevation based on the positioning of at least one air recycling feature in the airflow director.
Instead of air, the fluid may be a liquid. The flameless candle may have a component that perturbs the liquid while the light is emitted. This causes the flame element to move.
The candle may have a first magnet coupled to the flame element and a second magnet configured to repel the first magnet, such that the flame element levitates above the second magnet.
The candle may also have a light pipe that pipes light from the light source at least partially in an upward direction towards the flame element. According to some techniques, the light source moves with respect to non-moving portions of the candle body while the light is emitted.
According to certain techniques described herein, a flameless candle has a candle body, a light source, a fan, and a flame element. The candle body has an inner region and an upper surface with an aperture. The light source selectively emits a light when it is energized or de-energized. The fan forces air upwardly while the light is being emitted. The flame element receives the light, for example, on an interior or exterior surface of the flame element. The flame element also receives the air. While the light is being emitted, the flame element floats on the air. The flame element is uncoupled from any other portion of the flameless candle while the light is emitted. The candle may further include a deflector including at least one obliquely-oriented portion, wherein the deflector induces turbulence in the air before the air is received by the flame element. The candle may further include an airflow director including a hollow region, wherein the flame element rises through at least a portion of the hollow region of the airflow director after the fan is turned ON such that when the flame element reaches a predetermined elevation, the flame element ceases rising and begins hovering. The predetermined elevation may be determined by at least one air recycling feature in the airflow director, such as a notch or hole. An upper contour of the airflow director may include a chamfered surface.
The foregoing summary, as well as the following detailed description of certain techniques of the present application, will be better understood when read in conjunction with the appended drawings. For the purposes of illustration, certain techniques are shown in the drawings. It should be understood, however, that the claims are not limited to the arrangements and instrumentality shown in the attached drawings. Furthermore, the appearance shown in the drawings is one of many ornamental appearances that can be employed to achieve the stated functions of the system.
Techniques described herein provide a more realistic flame movement over certain existing flameless candles. Many such existing candles employ pivots or magnets with an artificial flame element to reproduce the look of a real candle flame. This construction may limit the degrees of movement of the flame element. Techniques described herein allow the flame element to move in up to five degrees of movement (or more) during operation of the flameless candle. Such movement capabilities may more faithfully imitate the motion of a natural candle flame. Consider that real flames are fluids and, as such, they behave according to the laws of fluid dynamics. Certain techniques described herein also employ fluids to simulate a true candle flame, and may improve the effect of the illusion.
The techniques described herein provide for a candle that has a flame element that floats on a fluid (either air or liquid) during operation. Further, the techniques described herein also provide for a candle that has a moving flame element that receives light in an interior region and emits it outwardly from its exterior surface.
The flameless candle 100 includes a candle body 110. The candle body 110 has an outer surface visible to a viewer. The outer surface includes a lateral (or circumferential) surface wrapping around a primary axis of the flameless candle 100, a lower surface underneath the flameless candle 100, and an upper surface 111 of the flameless candle 100. The upper surface 111 includes an aperture 112. The aperture 112 may be substantially in the center of the upper surface 111. For example, the primary axis of the flameless candle 100 may pass through the aperture 112. The aperture 112 may also be offset from the center of the upper surface 111. The upper surface 111 may be flat or may have another geometric shape, such as one with a concave recess as depicted. The flameless candle 100 may have a rim 113 from which the upper surface 111 extends at least partially downwardly and inwardly towards the aperture 112. According to certain configurations, the upper surface 111 may cover an upper surface of the rim 113—i.e., portions of outer surface of the rim 113 may be co-extensive with the upper surface 111. The candle body 110 also has an inner region within which one or more of the other components of the flameless candle 100 are housed—either partially or in full. The inner region may be substantially hollow.
The candle body 110 may house the power source 180 (e.g., AA or C batteries or rechargeable batteries), or the power source 180 may be located outside of the candle body (e.g., a transformer electrically connected to the electrical systems of the candle 100).
The flameless candle 100 may further include an underside, as depicted in
As shown in the embodiment of
The candle 100 operates when a user interacts with the user interface 190 or remote control. The user interface 190 may include one or more actuators. The actuators may allow the user to turn the candle 100 ON or OFF. Other features potentially controllable through the actuators include controlling the speed of the fan 140, the intensity or character of the light emitted by the light source 120, the implementation of a timer, the actions taken when sensor inputs are sensed, and/or other features. Such features and functionality are described herein and need not be repeated here. User interaction may also be effectuated through a remote control in combination with or in lieu of the user interface 190.
The user causes the fan 140 and/or light source 120 to turn ON or OFF. When the fan turns ON, air is forced onto the flame element 130 or a component attached thereto. This causes the flame element 130 to rise and extend through the aperture 112 of the upper surface 111. Light is projected from the light source 120 onto an interior surface of the flame element 133, such that it projects through the flame element 130 and outwardly to the observer's eye. Subsequently, the user can turn both the fan 140 and light source 120 OFF, thereby causing the flame element 130 to fall down such that the candle 100 no longer appears to have a visible flame, and the illusion of a candle ceases.
The light source 120 may include an LED or incandescent device. The light source 120 may also include circuitry that influences the character of the emitted light. Such circuitry may include circuitry embedded in an LED package (for example, an ASIC) and/or external circuitry, such as circuitry 170 discussed below. According to some techniques, the circuitry includes a processor that influences or controls the character of the light emitted by the light source 120. Such a processor executes machine-readable instructions stored in memory to operate the light source 120 as described herein.
The light source 120 may emit light having different colors or only a single color. The associated circuitry of the light source 120 may cause different colors of light to be emitted simultaneously and/or at different times. Light may be emitted that varies in intensity over time due to operations of the associated circuitry. For example, the light source 120 may emit a light that emulates a true, flickering flame. Alternatively or in addition, the light source 120 may emit light with a constant intensity—possibly at controllable or selectable intensity levels.
The light source 120 may include one or more light emitting components (e.g., multiple LED packages in different locations and/or multiple dies in a single LED package). For example, the light source 120 may include a plurality of light-emitting components, such as multiple LED packages or multiple dies within a single LED package. If the light-emitting components emit light having different colors, they can be controlled to achieve an overall light output having a selected color. The intensities of the outputs of the light-emitting components can be varied to arrive at different selected colors.
When the light source 120 includes a plurality of light-emitting components, the different light-emitting components may be oriented such that the emitted light beams impinge on different locations of the interior surface 133 of flame element 130. In such a configuration, the intensities and/or colors of the light beams may vary over time in a distinct manner such that movement of a true flame is simulated to a viewer looking at the flame element 130.
When multiple light-emitting components are employed, the associated circuitry may independently control one or more different aspects of the light projected by the different light-emitting components (e.g., two components). For example, the circuitry may be capable of separately controlling the intensity and/or color for each light-emitting component. The intensities of each light-emitting component may be adjusted by varying a pulse-code modulated signal or a pulse-width modulated signal provided to the given light-emitting component. The associated circuitry may cause each light-emitting component to emit light with different sequences of intensities over time. Such sequences may include random sequences, semi-random sequences, or predetermined sequences. A sequence may include a repeating loop (for example, a 5-10 second loop). Such sequences may include frequencies that are out of phase from each other. For example, one predetermined sequence may be applied to a first light-emitting component, and the same predetermined sequence may be applied to a second light-emitting component, but out of phase. As another example, a first predetermined sequence may be applied to a first light-emitting component and a second predetermined sequence may be synchronously applied to a second light-emitting component. The second predetermined sequence may result from filtering or adjusting the first predetermined sequence. Such filtering may include high-pass and low-pass filtering, and such adjusting may include attenuating the amplitudes of the first predetermined sequence.
Sequences may be dynamically influenced by other factors or inputs. For example, an output signal from a light sensor (not shown) could be received by the associated circuitry, which may, in turn, adjust the intensity levels in sequences according to the light sensor output signal (for example, boost the intensities under higher light). As another example, an output signal from a sound sensor (not shown) could be received by the associated circuitry, which may, in turn, adjust the intensity levels in sequences according to the sound sensor output signal (for example, adjust the frequency of the intensity changes in response to the character of received sound).
According to one example, it may be possible to provide distinct circuitry for each light-emitting component. Each distinct circuitry may be integrated into an epoxy case that houses a light-emitting diode. The two distinct circuitries may be synchronized or coordinated through a signal communicated between the distinct circuitries.
The light source 120 may also include components that alter the shape, color, or intensity of the light emitted directly out of light-emitting component(s). Such altering components may include one or more lenses, collimators, filters, and/or other optics. Such optics may have a static position and/or may move while the light is emitted to cause a time-varying intensity (e.g., an effect that emulates flickering of a true candle flame).
As will be further discussed, the light source 120 may be housed in the inner region of the candle body 110 or may be outside. If the light source 120 is housed in the inner region of the candle body 110, it may emit light through the aperture 112. The light source 120 may alternatively be positioned above the aperture 112 in the upper surface 111, but may be encompassed by the flame element 130 as depicted in
A sheath 121 may surround all or part of the lateral portions of the light source 120. The sheath 121 may provide a barrier against wind. The sheath 121 may also provide support for the light source 120. As shown, the sheath 121 surrounds the leads of the light source 120 (which is depicted as an LED). The sheath 121 may provide a feature on which the light source 120 is seated.
The flame element 130 may have a portion 131 that resembles the shape of a candle flame (i.e., a flame shape). The flame element 130 may also include other portions aside from the flame-shaped portion 131 as further described. The flame-shaped portion 131 may be shaped and positioned to receive light emitted from the light source 120 and/or light pipe 125. At least part of the flame-shaped portion 131 extends upwardly from the upper surface 111 or aperture 112. For example, the flame-shaped portion 131 (or a part thereof) may extend through the aperture 112 while light is emitted, such that a viewer can view the flame-shaped portion 131.
The flame-shaped portion 131 may receive light on an exterior surface 132 or an interior surface 133 of the flame element 130. In the event that the flame element 130 receives light on the interior surface 133, it includes an interior region through which the light first passes. In this configuration, the flame-shaped portion 131 may be transparent or translucent. The light may be directed towards the interior region of the flame element 130. The interior region of the flame element 130 may be at least partially (or entirely) hollow. Light may pass through the interior region, onto an interior surface of the flame element 130. The flame element 130 may then allow the light to propagate through the flame element 130 and outwardly from the exterior surface.
The interior region of the flame element 130 may include a light pipe that routes light through the interior region to the exterior surface 132. Portions of the flame element 130 may act as a light pipe, such that light can be transferred from underneath the flame element 130 (or underneath a portion of the flame element 130) to a selected location on the surface of the flame element 130.
In the event that the flame element 130 receives light on the exterior surface 132, the flame element 130 may or may not have a hollow interior region. In this configuration, the flame-shaped portion 131 may be substantially opaque or translucent.
As depicted in
According to one technique, phosphor can be applied to the flame element 130. A blue LED can emit light onto the phosphor, thereby creating a white color. Phosphor paint could be injected in the flame element 130 during manufacturing, or painted inside or outside the flame element 130. According to a technique, only a portion of the flame element 130 may be coated or infused with phosphor. For example, an upper region of the flame element 130 may have the phosphor while a lower region does not. This may cause an illusion of a real candle flame with a blue region in the lower area and a white region in the upper area of the flame element 130.
The flame element 130 may further include an extension 135. The extension 135 may be integrated with, attached to, or connected to other portion(s) of the flame element 130. The extension 135 may extend at least in a horizontal dimension away from the other portions of the flame element 130. The extension 135 may have a toroidal shape, and the center aperture of the extension 135 may fit around the flame element 130 (and possibly into a recess in the flame element 130) as shown, for example, in
The flame element 130 may move while light is emitted by the light source 120. The flame element 130 may also be uncoupled from all other non-moving portions of the candle 100 while light is emitted. The flame element 130 may move in multiple degrees of freedom (for example, pitch, roll, yaw, up, down, backward, and/or forward, or any subset thereof) while the light is emitted. Such movement of the flame-shaped portion 131 may resemble movement of a real candle flame.
The flame element 130 and/or the extension 135 receive forced air from a fan 140. The outlet of the fan 140 is positioned such that the fan 140 blows air upwardly onto the flame element 130 and/or extension 135. In any event, variations in air pressure generated by the fan 140 or otherwise cause the flame element 130 to rise upwardly during operation of the candle 100. The fan 140 may be a centrifugal fan as shown, or it may be another type of fan, such as an axial fan or a cross-flow fan. Exemplary airflow in the candle 100 is depicted in
Like the light source 120, the fan 140 may provide an uneven output over time. For example, the speed of the fan 140 may vary such that the pressure of the air applied to the flame element 130 and/or extension 135 changes over time during operation. This unevenness causes the flame element 130 to rise and fall (and possibly move in other dimensions or degrees of freedom as discussed) to enhance the illusion of a true candle flame (especially the illusion of air currents interacting with the true flame). For example, the fan 140 may momentarily stop, thereby allowing the flame element 130 to drop down, thereby resembling a real flame on a candle (under certain conditions). Similarly, the fan 140 may cause the flame element 140 to momentarily rise up as would a real flame. Furthermore, the fan 140 may operate at variable speeds, thereby controlling the rate at which the flame element 130 moves up and down. Such variation could be performed in a coordinated manner with varying the output of the light source 120. Alternatively, varying the fan 140 speed could be performed independently of the light source 120. For example, the fan 140 may vary speed but the light source 120 may maintain a constant output. According to one technique, the light source 120 provides a flickering light output at a given time and, coextensively, the speed of the fan 140 is varied to enhance the illusion of a flickering candle. The speeds of the fan 140 and output of the light source 120 can also be constant but periodically vary (either together or independently). According to such a technique, the appearance of the light emitted from the candle 100 may periodically or aperiodically vary during constant operation of the candle 100, whereby the light outputted by the light source 120 and/or position of the flame element 130 is constant during one phase and varies during another.
The fan 140 and/or the light source 120 may operate in response to a timer, such that they automatically turn OFF after a predetermined period of time. The fan 140 and/or the light source 120 may also automatically turn ON after a predetermined period of time. For example, once activated, the fan 140 and/or the light source 120 may automatically turn OFF after 5 hours. Then, 19 hours later, the fan 140 and/or the light source 120 may automatically turn ON. This automatic switching may continue as a cycle. The timer-based switching (cyclical or not) can be activated when a user turns the candle ON in a timer mode. The timer mode may be enabled or disabled by the user through the user interface or remote control.
The airflow director 160 includes a hollow interior region, which receives forced air from the outlet of the fan 140 at a lower area of the airflow director 160. As depicted in
The airflow director 160 may also include one or more airflow recycling features 162, which are openings or notches in the wall that forms the hollow interior region. The design of the airflow recycling features 162 may control the elevation and/or movement of the flame element 130. As the flame element 130 and/or extension 135 rise through the hollow interior region, the air pressure may be substantially constant. When the flame element 130 and/or extension 135 emerges from the top of the hollow interior region, the air pressure suddenly drops. The airflow recycling features 162 can be positioned to control or influence the degree that the air pressure drops.
During the ON operation, the air flow might be exhausted by the airflow recycling features 162 and a gap formed between the sidewall of the airflow director 160 and the extension 135. According to one technique, the majority of air may be expelled by the airflow recycling features 162 and a smaller amount through the gap between the airflow director 160 and the extension 135.
The airflow recycling features 162 may also control or influence the elevation at which the flame element 130 floats. For example, as depicted in
An upper surface or contour of the airflow director 160 may be chamfered to stabilize the air pressure applied to the flame element 130 and/or extension 135. The chamfered contour provides a tapered radius along the height of the surface, such that the lower region of the surface has a smaller radius than the upper region. As the flame element 130 and/or extension 135 travels up and down, the amount of air those components receive changes. In the lower region, relatively more pressure is applied. In the upper region, relatively less pressure is applied. This configuration may improve stability of the flame element 130 and/or extension 135. As those components travel upwardly, they receives less force, thereby allowing them to slow down. Eventually, the flame element 130 may reach a substantially stable height, such that the gravitational force and the force received from the forced air are offsetting.
The circuitry 170 may control some or all of the operations of the light source 120 and/or fan 140 as described herein. The circuitry 170 may also receive inputs from the various sensors, actuators in the user interface 190, and/or remote controls described herein. The circuitry 170 may include a processor that executes a set of computer-readable instructions stored in a non-volatile memory to achieve the functionality described herein.
For the embodiments in which the flame element magnetically levitates, the flame element is coupled to a magnet. An opposing magnet is selectively positioned underneath the flame element magnet to cause levitation. In some embodiments, the opposing magnet may be an electromagnet. An additional electromagnet (aside from one used for levitation) may be used to perturb the floating magnet to cause the flame element to move in various additional ways.
The candle body 201 includes a reservoir 210, which retains a liquid 220. A flame element 230 is coupled to a flotation component 240, which floats on the liquid 220. Alternatively, the flotation component 240 may be integrated with the flame element 230 (i.e., the flame element 230 by itself floats). To effectuate floating, the flame element 230 and/or flotation component 240 may include a material such as polypropylene, LDPE, MDPE, HDPE, or polychloroprene.
The flame element 230 may be similar to flame element 130. For example, the flame element 230 may have features, such as ridges, ribs, or protrusions/recesses, which can distort light emitted from the flame element 230 as desired. The flame element 230 includes a hollow interior region. A light source 250 (e.g., one such as light source 120) is positioned within the hollow interior region of the flame element 230, such that when light is emitted, it projects from within the flame element 230. The light source 250 is supported by a support 260, which extends upwardly from the lower surface of the reservoir 210. The support 260 (or the light source 250) may constrain the lateral motion of the flame element 230. The light source 250 includes conductors which extend upwardly through the lower surface of the reservoir 210 and through the support 260. In addition to providing mechanical support for the light source 250, the support 260 may serve to insulate the conductors from moisture. The conductors deliver electrical power to the light-emitting portion of the light source 250, and such power may be transmitted from circuitry 290.
Underneath the reservoir 210 is an electromagnet 280 housed in the interior of the candle body 201. The electromagnet 280 may include a coil comprising a conductor, such as wire or a trace on a printed circuit board. The electromagnet 280 is electrically coupled to the circuitry 290, which may be capable of controlling the polarity and intensity of the magnetic field generated by the electromagnet 280 by applying a suitable voltage across the electromagnet 280. The circuitry 290 may vary the magnetic field to cause the flame element 230 to move in a desired, but irregular manner.
Within the reservoir 210 and liquid 220, there is a magnet 270, which responds to the magnetic force applied by the electromagnet 280. When the magnet 270 receives this force, it moves within the liquid 220. This movement, in turn, perturbs the liquid 220, thereby causing the flame element 230 to move. The magnet 270 may have a toroidal shape or otherwise have an aperture that sits over the support 260. According to this arrangement, the magnet 270 can be secured such that magnetic coupling is more efficient, and the magnet 270 can be prevented from undue lateral motion. The magnet 270 may alternatively have other shapes, such as a bar, a rod, or an irregular shape.
The candle 200 depicted in
Unlike candle 1000, however, the light source 1150 is positioned such that light is emitted onto the outer surface of the flame element 1130. Aside from its position in the candle 1100, light source 1150 may be similar to the aforementioned light sources. Additional light sources can be located at other positions around the flame element 1130, such that the flame element 1130 receives light from multiple different angles.
As will be appreciated, the various techniques described herein may be used together even if not explicitly stated. For example, magnets can be swapped out for electromagnets or vice versa. As another example, light pipes can be substituted (or vice versa) and light sources repositioned. Flame elements with internal projection can be substituted for those that are illuminated via external projection. As another example, magnets and/or electromagnets can be used in conjunction with the air-based candle techniques. These are but a few examples, and it will be appreciated that a given feature is not applicable only to a specifically described embodiment. The features can be mixed as will be appreciated. Additionally, the candles disclosed herein may incorporate fragrance releasing elements that, for example, are in the liquid or are imparted to the environment via air flow of the fan.
It will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the scope of the novel techniques disclosed in this application. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the novel techniques without departing from its scope. Therefore, it is intended that the novel techniques not be limited to the particular techniques disclosed, but that they will include all techniques falling within the scope of the appended claims.
The present application claims priority to and the benefit of U.S. Prov. Appl. 62/959,028, filed on Jan. 9, 2020, the entirety of which is herein incorporated by reference.
Number | Date | Country | |
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62959028 | Jan 2020 | US |