ITTO20110132A1 - DIMMER FOR LED BULB AND ASSOCIATED LED BULB. - Google Patents

Description

Dimmer for LED bulb and associated LED bulb.

The present invention relates to a dimmer and in particular relates to a dimmer for LED bulb and associated LED bulb.

It is known that the bulbs traditionally used for domestic lighting can be equipped with dimmers or various lights, instruments electrically connected in series between the bulb and the socket and capable of causing a variation in the luminous flux emitted by the bulb by varying amplitude. and form of the voltage and / or current supplied to the bulb.

Typically dimmers are used with filament bulbs or halogen bulbs.

It is also known that LED bulbs are becoming increasingly popular in the home environment; LED bulbs, for an equal electrical absorbed power in Watts, produce a much greater luminous flux than that obtainable with a filament or halogen bulb.

Since the LED bulbs need some electronic devices in order to be powered through the common voltage of 220-240V, 50 / 60Hz present in the vast majority of countries in the world (remember that LEDs are traditionally powered at much lower voltages, in the 'order of 1-6 Volts, depending on the type); LED bulbs for domestic applications, as illustrated in Figure 1, comprise a bulb 1 within which one or more LEDs 2 are positioned. The bulb 1 comprises a socket 3 of the type commonly used for filament bulbs, and therefore for example E27 or OJ 10.

Due to the electronic characteristics of LEDs, it is impossible to use a traditional dimmer with an LED bulb. This is as true for traditional analog dimmers as it is for digital dimmers.

In fact, the LED bulbs on the market for domestic applications also incorporate a power supply 4, generally of the switching type, inside the bulb 1, which reduces the mains voltage to a lower value, capable of being suitable for the power supply of any configuration of LED 2; above all, the power supply 4 converts the alternating voltage into direct voltage DC, and performs this voltage and waveform conversion in the most efficient way possible in terms of efficiency η between the input power and the output power. Therefore, the conversion operation of the power supply 4 is performed in order to reduce heat dispersion to a minimum and, among other things, sometimes guaranteeing functionality in the presence of different input voltages, for example both with 110-120V both with 220-240V.

Consequently, by connecting a traditional dimmer in series to the LED bulb, a curve like the one shown in figure 2 is obtained, in which the luminous intensity L, graphically represented in ordinate, remains constant (level Li) for most of the level. dimming or attenuation of luminous intensity D (abscissa axis), to then cause an immediate decay to almost zero, with an abrupt decrease, in which the LED 2 operates flickering and then switches off completely for attenuation values of luminous intensity close to 100%.

Basically, therefore, by using a traditional dimmer for incandescent (filament) or halogen bulbs with an installation upstream of the lamp, an effective effect of gradual reduction of the light intensity is not obtained; on the contrary, the effect is that of a substantially passage from a stable condition of maximum brightness to a condition of substantial switch-off.

The purpose of the present invention is therefore to describe a dimmer for LED bulbs which is free from the drawbacks described above, and also allows to realize a modification kit of LED bulbs powered by AC mains, in order to make it variable light intensity.

A further object of the present invention is to describe an LED bulb equipped with a dimmer for LED bulbs.

According to the present invention, a dimmer for LED bulbs is realized as claimed in the first claim.

According to the present invention, an LED light bulb is also realized as claimed in claim 7.

The invention will now be described with reference to the attached drawings, which illustrate a non-limiting example of embodiment, in which:

Figure 1 illustrates a simplified diagram of an LED bulb;

Figure 2 illustrates a graph of luminous intensity as a function of a degree of attenuation of luminous intensity of an LED bulb, dimmed through a common dimmer;

Figure 3 illustrates the block diagram of a dimmer for LED bulbs according to the present invention;

figures 3a, 3b illustrate two distinct power supply configurations of the dimmer object of the present invention;

Figure 4 illustrates a pair of power supply waveforms of the dimmer of Figure 3;

Figures 5-7 illustrate respective wave forms of a power supply signal for the LEDs of Figure 3; - figure 8 illustrates a graph of luminous intensity as a function of time produced by the LEDs of figure 3 following a variation on a luminous intensity command.

With reference to Figure 2, a dimmer for LED bulbs is indicated as a whole with 10.

The dimmer 10 comprises a period or frequency measurement stage 11, comprising within it an analog to numeric encoder (ADC), fed at the input by a mains voltage source S (which typically and not limitedly in homes is equal to 110-120V, or 220-240V, 50 / 60Hz).

Alternatively, the period or frequency measurement stage 11 can be powered by a traditional dimmer, in turn powered by the source S. In this case the dimmer 10 object of the present invention is therefore powered on one of its inputs, by an output of a common dimmer 300, designed to drive common filament or halogen bulbs, and producing a truncated sinusoid on its output, the truncation of which, as known, varies according to a percentage of desired light intensity attenuation.

The period or frequency measurement stage 11 comprises an output 11lo feeding a first input 12i of a microprocessor 12; the microprocessor 12 also comprises a second input 12c, capable of receiving in use a command for adjusting the light intensity attenuation value D, between a value corresponding to 0 and a maximum value (100%) corresponding to the zeroing of the intensity bright of one or more 20 LEDs of a 100 LED bulb.

The range of values between 0 and 100% is purely indicative of the dimming capacity and can be achieved with an imposition of variable voltage between a minimum and a maximum value on the second input 12c.

The microprocessor 12 also has an output 12o, which supplies a control input 13i of a PWM modulator 13 of the dimmer 10.

The PWM modulator 13 also has a pair of power inputs 13p which are powered by a power supply 30 of the LED bulb 40; in detail, the power inputs 13p are supplied by a direct voltage output 30o of the power supply 30, which also has a pair of inputs 30i supplied in alternating current by the source S. On the output 30 the voltage is brought to a '' amplitude lower than that of the mains voltage.

Finally, the PWM modulator has an output 13o, electrically connected to the LEDs 20.

Dimmer 10 works as described below.

If the dimmer 10 is powered directly from the mains, as illustrated in Figure 3a, the source S supplies the inputs of the power supply 30 and of the period or frequency measurement stage 11 with a signal having a voltage ideally (i.e. in the absence of disturbances) sinusoidal, as shown in Figure 4 (sinusoidal waveform 201, represented with a dashed line).

If, on the other hand, the dimmer 10 object of the present invention is powered by the source S through a dimmer of the common type, as illustrated in Figure 3b, the signal assumes a truncated sinusoidal waveform, as represented in Figure 4 (sinusoidal waveform truncated 200, represented with a solid line).

The period or frequency meter 11 therefore calculates the length (time interval) of permanence above zero (or equivalently above a positive threshold voltage value) Ton, and possibly also the period T of the sine wave and sends this value in the form numerical to the first input 12i of the microprocessor 12, which therefore "knows" for each instant of time the duration of each half-wave and can also adapt to sinusoids with different network frequencies with respect to the traditional 50 / 60Hz.

The calculation of the time lapse Ton can be followed with a zero Crossing or threshold Crossing detector with identification of a positive rising edge (technique known as positive edge triggering).

The positive threshold voltage value is defined as a function of the fact that the switching power supplies can withstand very low working voltages compared to the nominal power supply voltage For example, a switching power supply 30 for 220V input, is able to operate good even with 30-40V input, average voltage value over period T of the input sinusoid, while carrying out the voltage conversion.

Therefore, even when the dimmer 10 is connected to the source S through a common dimmer 300 as in figure 3b, and provided that the time Ton of the positive sinusoid is sufficient to maintain the average voltage value over the period T in a condition equal to the level Li of Figure 1, the dimmer 10 object of the present invention can still function as a further dimming stage introduced downstream of the common dimmer.

It is clear that in the case in which the dimmer 10 object of the present invention is directly connected to the source S, the period or frequency measurement stage 11 can equivalently measure the time lapse Ton or the period T.

By means of the command for adjusting the dimming value of light intensity D on the input 12c of the microprocessor, a user selects the dimming value of the light intensity or alternatively an on or off command. Consequently, knowing the value of the period Ton of the truncated sinusoid 200 (signal si) downstream of the common dimmer 300 or alternatively the voltage sinusoid generated by the source S and, also, knowing an amount of reduction in light intensity desired by the user, the microprocessor 12 supplies its output 12o with a duty cycle control signal s3 which performs a control of a signal replicating the value of reduction in light intensity desired by the user, if the common dimmer 300 is present; if the common dimmer is not connected between the dimmer 10 object of the present invention and the source S, then the duty cycle control signal s3 represents a control for reducing the light intensity of the LEDs.

The dimmer 10 further comprises radio module 50, electrically connected to the control input 12c of the microprocessor 12; the radio module 50 in turn comprises at least one receiver sub-stage, capable of receiving a signal for variation of light intensity s4 transmitted remotely, for example by a remote control.

The radio module 50 can operate according to any radio technology, but preferably - although not limitedly - ZigBee or IR.

Through the radio module 50 it is also possible to transmit to a user a plurality of usage data including - in a non-limiting manner - the number of hours of operation of the LED lamp or the instantaneous or average power consumed.

The PWM modulator 13, as known, as a function of a duty cycle control signal s3 fed to one of its control input 13i, generates at its output a square wave form with period Ti, which as illustrated in the figure and having a value of maximum voltage Vmax and a minimum voltage value Vmin; the period Ti can be divided into a time T2 in which the voltage on the output 13o is constantly equal to the maximum voltage value Vmax and a time T3 in which the output voltage 13o is constantly equal to the minimum voltage value Vmin. The sum of T3 and T2 generates the entire duration of the period Tl.

The LED diode itself is perfectly dimmable using a PWM technique (pulse width modulation), which guarantees high efficiency and simplicity in the design of the modulators.

In particular, Figure 5 illustrates an embodiment of the voltage present on the output 13o corresponding to a value D equal to 50%; consequently the time T2 is substantially equal to half of the period Tl of the square wave.

By increasing the D value over 50%, the time T2 decreases; Figure 6 illustrates an embodiment in which the voltage present on the output 13o corresponds to a value of D> 50%; consequently the time T2 is greater than half the period Tl of the square wave. The luminous intensity emitted by the LED 20 will consequently be lower than in the case of figure 5.

On the other hand, by decreasing the value D below 50%, the time T2 increases; Figure 6 illustrates an embodiment in which the voltage present on the output 13o corresponds to a value of D <50%; consequently the time T2 is shorter than half the period Tl of the square wave. The luminous intensity emitted by the LED 20 is therefore lower than that of the case of figure 5.

Finally, Figure 8 shows the graph of the luminous intensity I of the LED 20 as a function of time in correspondence with D = 50% (and therefore T2 = 0.5T1), in the section identified by the letter a. The luminous intensity is constant as long as a user does not impose a variation of D to a value greater than 50%, section b, in which the luminous intensity is reduced compared to before and then stabilizes on a constant value. The trend of the decrease in brightness from section a to section b depends on the reaction speed to the command of the assembly formed by the microprocessor 12 and PWM modulator 13.

Finally, in section c an increase in luminous intensity is observed when a user imposes a variation in D to a value <50%.

The dimmer 10 can be sold either as an installation kit on an existing LED bulb, or included in a complete LED bulb 40, which will therefore include, inside its body and therefore integrated in it, in addition to the dimmer 10, also power supply 30 and LED modules 20.

Clearly, the complete LED bulb 40 has a body equipped with an attachment able to be joined with the traditional household bulb holders, so as to be perfectly replaceable with them.

The advantages of the dimmer for LED bulbs are known in the light of the above description. In particular, it allows you to adjust the luminous intensity of an LED bulb as it can be integrated into its body. In this way, even the LED bulbs on the market can be characterized by a variability of light intensity, a characteristic otherwise precluded to common LED bulbs which can be screwed into a bulb holder for domestic applications.

The dimmer object of the present invention, therefore, allows to emulate the truncated sinusoidal half-wave 200 produced by the traditional common dimmers 300 powering the traditional filament or halogen bulbs, thus powering the LEDs through a PWM technique.

Therefore, the dimmer object of the present invention, when inserted in an LED bulb, works transparently.

Through the dimmer object of the present invention it is also possible to determine the level of luminous intensity remotely, without necessarily having to access near the bulb.

Through the dimmer object of the present invention it is therefore possible to provide a modification kit for a common complete LED bulb, with connection for alternating mains voltage, for example E27, modifying it and allowing the adaptation of the dimmer also to LED lamps equipped with internal power supply.

Some variants, modifications and additions that are obvious for a person skilled in the art can be applied to the device described up to now, without thereby departing from the scope of protection provided by the appended claims. More in detail, the period or frequency meter 11 can be replaced by a frequency meter suitable for measuring the frequency of the mains voltage.

Claims (1)

CLAIMS 1) Dimmer (10) for LED bulb, comprising: - a PWM modulator (13) having an output (13o); said output (13o) being capable of being electrically directly connected in use with one or more LEDs (20) of an LED bulb; - a control input (12c) of a light intensity attenuation level capable of being varied by a user; And - a periodimetric / frequency measurement stage (II), designed to measure a time interval (Ton; T) or frequency (f) on an alternating voltage supply signal (si); said PWM modulator (13) supplying said one or more LEDs (20) with a signal (s3) having a variable duty cycle according to said attenuation level and said time interval (Ton; T) or frequency (f) · 2) Dimmer according to claim 1, configured to be interconnected in use between said LEDs (20) of said LED bulb and a power supply stage (30) of said LED bulb. 3) Dimmer according to claim 1, further comprising a microprocessor (12); said microprocessor having a first input powered by said control input (12c) and a second input (12i) supplied with a measurement signal of a time interval (Ton; T) of said power supply signal (si) in alternating voltage . 4) Dimmer according to claim 3, wherein said microprocessor 12 comprises an output 12o feeding an input 13i of said PWM modulator with a duty cycle control signal s2. 5) Dimmer according to any one of the preceding claims, comprising a radio module (50), electrically connected with said control input (12c); said radio module (50) comprising at least one receiver sub-stage capable of receiving a signal for variation of light intensity (s4) transmitted remotely. 6) Dimmer according to claim 1, specifically designed to be electrically powered by an output of a common dimmer (300), in which said power signal (si) comprises a truncated sinusoid (200) and in which said range of time (Ton) is a permanence interval of the said truncated sinusoid (200) above zero or above a threshold voltage value. 7) LED bulb, comprising a body in turn comprising a power supply module (30) and one or more LEDs (20) powered by said power supply module (30); the said power supply module (30) being powered with an alternating voltage signal (si) coming directly from the mains or from an output of a common dimmer (300) and feeding one of its outputs (30o) at a lower voltage than said voltage alternating network; said LED bulb being characterized in that it comprises a dimmer (10) integrated in said body; the said dimmer (10) is capable of adjusting the luminous intensity emitted by the said one or more LEDs (20) on the basis of an adjustment command of the luminous intensity attenuation value (D) variably determined by a user; said dimmer (10) being interposed between said output (30o) of said power supply module (30) and said one or more LEDs (20). 8) LED bulb according to claim 7, wherein said dimmer (10) comprises a PWM modulator (13) having an output (13o); said output (13o) being directly connected to said one or more LEDs (20) and supplying said one or more LEDs (20) with a signal (s3) having a duty cycle which varies according to said light intensity attenuation value ( D) and of a time interval (Ton; T) or frequency (f) of the said supply signal (si). 9) LED bulb according to claim 8, wherein said dimmer (10) further comprises a periodimetric / f requenzimetric measuring stage (11), configured to measure a time interval (Ton; T) or frequency (f) of the said power signal (si). 10) LED bulb according to claim 9, wherein said dimmer (10) further comprises a microprocessor (12); said microprocessor having a first control input (12c) and a second input (12i) supplied with a measurement signal of a time interval (Ton; T) of said power supply signal (si). 11) LED bulb according to claim 10, wherein said first control input (12c) is present said light intensity attenuation value (D) variably determined by a user. 12) LED bulb according to claim 7, wherein said microprocessor (12) comprises an output (12o) feeding an input (13i) of said PWM modulator with a duty cycle control signal (s2). 13) LED bulb according to claim 7, further comprising a radio module (50), electrically connected with said control input (12c); said radio module (50) comprising at least one receiver sub-stage capable of receiving a signal for variation of light intensity (s4) transmitted remotely. 14) LED bulb according to claim 7, wherein said power signal (si) comprises a truncated sinusoid (200) coming from said common dimmer (300) and in which said time interval (Ton) is an interval of permanence of said truncated sinusoid (200) above zero or above a threshold voltage value.