CN201396582Y - Portable illumination device - Google Patents

Abstract

The utility model discloses a portable illumination device, which comprises a power source, a controller and a load circuit. The controller comprises a power input end, and the power input end is electrically connected with the power source through a first switch. The load circuit is electrically connected with a power output end of the controller and can produce a feedback signal. The controlleradjusts the electric power which is supplied to the load circuit through the power output end at least according to the state and the feedback signal of the first switch. The portable illumination device can improve the flexibility of the circuit design and application and can prolong the service life.

Description

Portable lighting device

Technical field

The utility model relates to a kind of lighting device, relates in particular to a kind of portable lighting device.

Background technology

Portable lighting device as the family expenses flashlight, generally adopts incandescent lamp (incandescent lamp) to throw light on.In recent years, (Light Emitting Diode LED) develops into LCD (Liquid Crystal Display, LCD) light source of backlight, home lighting light fixture and street lamp to light emitting diode gradually.Because LED has preferable luminous efficiency and long service life compared to incandescent lamp, use LED also general gradually as the light source of flashlight.

Traditional flashlight needs battery as power supply.Yet in the moment of opening (turn on) flashlight, the surging (surge power) that is applied to lamp will damage lamp, and then reduces the service life of lamp.Modal settling mode is to add a current-limiting resistance (current limiting resistor) between lamp and battery, is applied to the big electric current of lamp to avoid moment.Yet the power consumption that newly-increased resistance is increased in circuit can seriously shorten battery life.

LED when conducting is luminous, have usually one between 3.2 volts (Volts is V) to the forward voltage between 4.0V.A family expenses alkaline battery provides 1.5V voltage usually.Therefore, in existing LED flashlight, a family expenses alkaline battery only provides 1.5V voltage usually, therefore needs 3 alkaline batteries just to be enough to LED is powered.Fig. 1 a is depicted as the schematic diagram of the electronic circuit 100 in the existing flashlight.Electronic circuit 100 uses with the formed battery pack 110 of the alkaline battery of 3 series connection, power supply as electronic circuit 100, this battery pack 110 provides energy to drive a LED 130 by switch 120, and forward voltage and conducting electric current that this LED 130 has 3.2V are 100mA.This electronic circuit 100 is provided with a current-limiting resistance 140 (for example, 13 ohm (0hm)) between LED 130 and battery pack 110.

Under these conditions, the power consumption on the current-limiting resistance 140 is 0.13 watt (Watt W), then consumes 0.32W on the LED130.Hence one can see that, and the power of LED 130 only is 71% of whole power, in other words, the portion of energy that is provided by battery pack 110 is provided current-limiting resistance 140, therefore battery pack 110 need be supplied more multipotency, and to keep the brightness of LED 130, this will cause decrease the service life of battery pack 110.

If LED 130 has the forward voltage of 4.0V when conducting because of processing procedure or other factors, the electric current that 13 ohm of current-limiting resistances 140 that then are positioned at 110 of LED 130 and battery pack will limit the LED 130 that flows through is about 38.5mA, in other words, the brightness of LED 130 at this moment will only be 38.5% of original design planning brightness (that is the electric current of the LED130 that flows through is 100mA).On the other hand, if change this current-limiting resistance 140 into 5 ohm, though can make forward voltage is the brightness (electric current of the LED 130 that promptly flows through is 100mA) that the brightness of the LED 130 of 4.0V reaches original design, but it is lower (for example: LED 3.2V) for other forward voltages, then may produce the overcurrent phenomenon, the electric current of feasible these LED that flow through (for example: 260mA), will have a negative impact to these LED increases.

Please refer to Fig. 1 b, its demonstration uses the available circuit shown in Fig. 1 a to cooperate the experimental data of current-limiting resistance drive currents as the LED of 100mA with two 1.5V alkaline batteries.By experimental data as can be known, using the battery life of available circuit only is 100 minutes.

Further, if the user changes the LED of different capacity specification, then the circuit design of this kind use current-limiting resistance will face the restriction in the practical application.For example, if the user wishes to obtain 10 times power, and be the LED that the LED of 100mA is replaced by 1A with rated current, yet because current-limiting resistance is to design in advance and fixing, so the electric current of the LED that flows through is with constant, so can't meet user's expectation.In addition, because the configuration of battery pack need be considered the mechanism design of flashlight simultaneously, so can't change number of battery cells usually arbitrarily to change the power supply supply.Generally speaking, for using with battery-driven flashlight, this kind current-limiting resistance is not only impracticable but also lack efficient, causes puzzlement for circuit design and application flexibility.

The utility model content

The technical problems to be solved in the utility model is to provide a kind of portable lighting device, can improve circuit design and application flexibility, and can prolong the service life of portable lighting device.

For solving the problems of the technologies described above, the portable lighting device that the utility model provides comprises a kind of simple control circuit, and it can overcome prior art problems.Even cell voltage is low to moderate for example 1.0V, the element operation that this controller still can only a few, voltage is increased to is enough to driving LED.Otherwise if the cell voltage that provided is high to for example 6.0V, the element operation that this controller also can only a few is low to moderate the required voltage of driving LED with voltage drop.This control circuit can comprise integrated circuit (IC), power inductance and other electronic components, with formation boost (boost), step-down (buck) or falling-rising press (buck-boost) converter, to provide power to LED.The high conversion efficiency of this step-up/down/type of voltage step-up can prolong the service life of battery, also can reduce number of battery cells, can alleviate the weight of portable lighting device.In addition, the utility model can need not changed under the situation of design, is applied to the LED of different capacity specification, and therefore significantly reduce the restriction of circuit application, and can prolong the service life of LED, thus the service life of prolongation portable lighting device.

According to an embodiment of the present utility model, a kind of portable lighting device is provided, this portable lighting device comprises power supply, controller and load circuit.Controller comprises power input, and this power input electrically connects via first switch and power supply.The power output end of load circuit and controller electrically connects, and can produce feedback signal.Controller according to the state and the feedback signal of first switch, is regulated the electric energy that offers load circuit at least via power output end.

Compared with prior art, portable lighting device of the present utility model utilizes control circuit to regulate the electric energy that offers load circuit, can prolong the service life of battery, also can reduce number of battery cells, can alleviate the weight of portable lighting device.In addition, the utility model can need not changed under the situation of design, is applied to the LED of different capacity specification, and therefore significantly reduce the restriction of circuit application, and can prolong the service life of LED, thus the service life of prolongation portable lighting device.

Below in conjunction with the drawings and specific embodiments the technical solution of the utility model is described in detail, so that characteristic of the present utility model and advantage are more obvious.

Description of drawings

Fig. 1 a is depicted as the circuit diagram of prior art flashlight.

Fig. 1 b is depicted as the experimental data of the service time of the battery that drives a LED in the available circuit of Fig. 1 a.

Figure 2 shows that electronic circuit exemplary circuit schematic diagram according to the portable lighting device of an embodiment of the present utility model.

Figure 3 shows that electronic circuit exemplary circuit schematic diagram according to the portable lighting device of another embodiment of the present utility model.

Fig. 4 a is depicted as the circuit diagram according to the controller in the electronic circuit embodiment illustrated in fig. 3.

Fig. 4 b is the sequential chart according to electronic circuit embodiment illustrated in fig. 3.

Figure 5 shows that exemplary circuit schematic diagram according to the electronic circuit of the portable lighting device of another embodiment of the present utility model.

Figure 6 shows that exemplary circuit schematic diagram according to the electronic circuit of the portable lighting device of an embodiment more of the present utility model.

Figure 7 shows that circuit diagram according to the controller in the electronic circuit embodiment illustrated in fig. 6.

Figure 8 shows that experimental data according to the service time of the battery that drives a LED in the electronic circuit of an embodiment of the present utility model.

The specific embodiment

Below will provide detailed explanation to embodiment of the present utility model.Though the utility model will be set forth in conjunction with the embodiments, being interpreted as this is not to mean the utility model is defined in these embodiment.On the contrary, but the utility model be intended to contain in the utility model spirit and scope that defined by the appended claim item defined various option modification items and be equal to item.

Please refer to Fig. 2, it is the exemplary circuit schematic diagram according to the electronic circuit 200 of the portable lighting device of an embodiment of the utility model.In one embodiment, portable lighting device is a flashlight.Electronic circuit 200 comprises battery supply (VBatt) 210, switch 220, light-emitting component 230, sensing element 240, controller 250 and inductance L 1.In one embodiment, battery supply 210 is one or more alkaline batteries.In one embodiment, light-emitting component 230 is LED.In one embodiment, controller 250 is an integrated circuit (IC).

In one embodiment, the power input VIN of controller 250 is electrically connected to battery supply 210 via switch 220.The power output end OUT of controller 250 is coupled to light-emitting component 230.Sensing element 240 is connected with light-emitting component 230, and senses flow is through the electric current of light-emitting component 230 by this, and produces feedback signal.This feedback signal is transferred into the sense terminals ISENSE of controller 250.Controller 250 also comprises switching output SW, and this switching output SW couples with power input VIN via inductance L 1.

In one embodiment, inductance L 1 is as the energy-storage travelling wave tube of (boost) converter that boosts.When switch 220 closures (Turn ON), the power input VIN of controller 250 is coupled to battery supply 210, receives the power supply that battery supply 210 is supplied, and light-emitting component 230 can receive electric energy via the power output end OUT of controller 250.When switch 220 disconnected (Turn OFF), battery supply 210 was promptly stopped power supply to controller 250 and light-emitting component 230.Controller 250 can be adjusted the electric energy that offers light-emitting component 230 according to the feedback signal that the closure of switch 220 and disconnection and sense terminals ISENSE receive.

Please refer to Fig. 3, it is the exemplary circuit schematic diagram according to the electronic circuit 300 of the portable lighting device of another embodiment of the utility model.Electronic circuit 300 comprises battery supply (VBatt) 210, switch 220, light-emitting component 230, sensing element 240, controller 350, inductance L 1 and capacitor C 1 and C2.The element that has same numeral among Fig. 3 and Fig. 2 has identical or similar function, for simplicity's sake, will repeat no more at this.

In one embodiment, controller 350 is an integrated circuit (IC).In one embodiment, electronic circuit 300 also comprises dc filter capacitor C1, and it is disposed between the power input VIN of battery supply 210 and controller 350.In like manner, in one embodiment, can be between the power output end OUT of light-emitting component 230 and controller 350 configuring direct current filter capacitor C2.

In one embodiment, controller 350 can be regulated the electric energy that offers light-emitting component 230, and then regulate the brightness of light-emitting component 230, and have dimming control function by a dimming control signal DIM who is coupled to switch 220.In one embodiment, when this switch 220 was closure state, this controller 350 was regulated the electric energy that offers light-emitting component 230.

Please also refer to Fig. 4 a, it is the partial circuit schematic diagram of the controller 350 in embodiment illustrated in fig. 3.Controller 350 can comprise low-voltage lock 451, circuits for triggering 452, gate generator 453, reference switch selector 454, adjuster 455, driver 456, reach switch 457,458, so that light-emitting component 230 is carried out brightness adjustment control.Below will cooperate the sequential shown in Fig. 4 b, the brightness adjustment control of an embodiment middle controller 350 will be described.

When switch 220 closures, the electric energy of battery supply 210 is applied to the power input VIN of controller 350.This moment, light-emitting component 230 was supplied to power supply under its rated current.At this moment reference switch selector 454 is provided with low frequency pulsewidth modulation (Low Frequency Pulse Width Modulation; LPWM) signal is the highest reference voltage Vmax, and promptly light-emitting component 230 can reach maximum (100%) brightness.

When switch 220 is disconnected, the electric energy that is battery supply 210 stops to be applied to controller 350, then circuits for triggering 452 can produce the triggering signal with first triggering falling edge, but the voltage drop on power input VIN is low to moderate and is lower than low-voltage locking (under-voltage lock-out, UVL0) in the certain hour before the threshold value (this time memory energy of storing in dc filter capacitor C1 can be kept the supply of energy), if switch 220 is closed again, then triggering signal has the first triggering rising edge, and this triggering signal can enable (enable) gate generator 453 and produce first clock pulse signal.First clock pulse signal offers reference switch selector 454, and in order to selecting the first reference voltage V1, and LPWM is set to V1.In one embodiment, this first reference voltage V1 is the low voltage of the highest reference voltage Vmax, for example, can drive light-emitting component 230 brightness and be 75% voltage.Needs in the visual application of above-mentioned reference voltage and being provided with.

In one embodiment, switch 220 can be disconnected again, then circuits for triggering 452 can produce the triggering signal with second triggering falling edge, but the voltage on power input VIN is brought down below in the certain hour before the low-voltage locking threshold value, if switch 220 is closed again, then this triggering signal has the second triggering rising edge, and this triggering signal can enable gate generator 453 once again and make it to produce the second clock pulse signal.This second clock pulse signal offers reference switch selector 454, and in order to selecting the second reference voltage V2, and LPWM is set to V2.In one embodiment, this second reference voltage V2 is than the low voltage of the first reference voltage V1, for example, can drive light-emitting component 230 brightness and be 50% voltage.In another embodiment, the second reference voltage V2 is for high but be lower than the voltage of the highest reference voltage Vmax than the first reference voltage V1, for example, can drive light-emitting component 230 brightness and be 80% voltage.

These operations can repeat.The first reference voltage V1, the second reference voltage V2 ... Deng the needs setting in the visual application of reference voltage, and various variations can be arranged.For example, the voltage level of reference voltage can be reduced in regular turn by height, for example, 100%, 75%, 50%, 25%, also can increase in regular turn, for example: 25%, 50%, 75%, 100% by low.In one embodiment, the change of reference voltage can make the brightness of light-emitting component 230 change according to fixed proportion, and for example 25%, 50%, 75% and 100% etc.In another embodiment, the change of reference voltage also can make the brightness of light-emitting component 230 become the variation of disproportional, and for example 20%, 30%, 80% and 100%.In yet another embodiment, reference voltage can be configured such that the brightness of light-emitting component is changed to the distress signal of 100%, 50%, 100% expression SOS.

In one embodiment, adjuster 455 can be according to the feedback signal of expression light-emitting component 230 electric energy of reference voltage and 240 sensings of sensing element, the output of regulating power output end OUT is with the flow through size of current of light-emitting component 230 of control, to reach the function of regulating light-emitting component 230 brightness.In a preferred embodiment, sensing element 240 is a resistance.In one embodiment, sensing element 240 is the combination of a resistance and an electric capacity (not shown).

In one embodiment, the output of adjuster 455 can be earlier via driver 456 amplifying signal intensity.In one embodiment, the output of driver 456 is coupled to switch 457, with the power output end OUT that provides on the battery supply 210 or after the adjusting of the electric energy on the dc filter capacitor C1 to controller 350.In one embodiment, adjuster 455 is pulsewidth modulation (pulse width modulation, PWM) circuit.In another embodiment, adjuster 455 is pulse frequency modulated (pulse frequency modulation, PFM) circuit.

In one embodiment, switch 457,458 and capacitor C 2, inductance L 1 forms (boost) converter that boosts, and the voltage on the power output end OUT can be increased to the voltage that is enough to drive light-emitting component 230.In one embodiment, switch output (SW) and couple with power input VIN, couple, be coupled to power output end OUT, and power output end and dc filter capacitor C2 couple via switch 458 via switch 457 and ground end (ground) via inductance L 1.Therefore, even the voltage that battery supply 210 provided only is 1V, but improve the voltage of power output end OUT via this boost converter, controller 350 still can drive light-emitting component 230, and the electric energy of adjusting light-emitting component 230, and then the service life of the battery supply 210 of an embodiment of prolongation the utility model.

In one embodiment, switch 457 and switch 458 be mos field effect transistor (Metal Oxide Semiconductor Field Effect Transistor, MOSFET).In one embodiment, switch 458 is complementary with switch 457 actions.In one embodiment, switch 457 is N passage (channel) mos field effect transistor.In one embodiment, switch 458 is P passage (channel) mos field effect transistor.In another embodiment, switch 458 is a diode (diode).

When 220 lasting disconnection a period of times of switch, the voltage on power input VIN is lower than predetermined value, and during as low-voltage locking threshold value (UVLO), then low-voltage lock 451 will produce replacement (reset) signal.This reset signal gate generator 453 of can resetting causes light-emitting component 230 to end.Light-emitting component 230 will remain cut-off state, till switch 220 is closed once again.

Please refer to Fig. 5, it is the exemplary circuit schematic diagram according to the electronic circuit 500 of the another embodiment of the utility model.Electronic circuit 500 comprises battery supply (VBatt) 510, switch 220, light-emitting component 230, sensing element 240, controller 550 and inductance L 2.In one embodiment, battery supply 510 is one or more alkaline batteries.In one embodiment, light-emitting component 230 is LED.In one embodiment, controller 550 is integrated circuit (IC).Fig. 5 has identical or similar function with Fig. 2 label components identical, for simplicity's sake, will repeat no more at this.

In one embodiment, inductance L 2 is as the energy-storage travelling wave tube of a step-down (buck) converter.When switch 220 closures, the power input VIN of controller 550 is coupled to battery supply 510, receives the power supply that battery supply 510 is supplied, and light-emitting component 230 can receive electric energy via the power output end OUT of controller 550.When switch 220 disconnected, battery supply 510 was promptly stopped power supply to controller 550 and light-emitting component 230.Controller 550 is regulated the electric energy that offers light-emitting component 230 according to closure and the off-state and the received feedback signal of sense terminals ISENSE of switch 220.

Please refer to Fig. 6, it is according to the utility model exemplary circuit schematic diagram of the electronic circuit 600 of an embodiment again.Electronic circuit 600 comprises battery supply (VBatt) 510, switch 220, light-emitting component 230, sensing element 240, controller 650, inductance L 2 and capacitor C 1 and C2.The label components identical has identical or similar function among Fig. 6 and Fig. 5, for simplicity's sake, will repeat no more at this.

Please also refer to Fig. 7, it is the partial circuit schematic diagram of middle controller 650 embodiment illustrated in fig. 6.Fig. 7 will describe in conjunction with Fig. 6.Controller 650 can comprise low-voltage lock 451, circuits for triggering 452, gate generator 453, reference switch selector 454, adjuster 455, driver 456 and switch 757,758, so that light-emitting component 230 is carried out brightness adjustment control.The label components identical has identical or similar function among Fig. 7 and Fig. 4 a, for simplicity's sake, will repeat no more at this.Sequential shown in the brightness adjustment control of controller 650 and Fig. 4 b is similar, will repeat no more at this.

In one embodiment, switch 757,758 and capacitor C 2, inductance L 2 form a step-down (buck) converter, the voltage drop on the power output end OUT can be low to moderate the voltage that is enough to drive light-emitting component 230.In one embodiment, switch output (SW) and couple, couple with power input VIN, and the switching output is coupled to ground via inductance L 2 and dc filter capacitor C2 via a switch 758 and a ground end (ground) via switch 757.Power output end OUT is coupled between inductance L 2 and the capacitor C 2.Therefore, even being higher than, the voltage that battery supply 510 is provided (for example drives the required voltage of light-emitting component 230,6V), but via the voltage on the step-down controller reduction power output end OUT, the still exportable low voltage of these light-emitting component 230 specifications that meets of controller 650 is to drive light-emitting component 230, and regulate the electric energy of light-emitting component 230, saving the electric energy that battery supply 510 is provided, and then prolong the service life of battery supply 510.

In one embodiment, switch 757 and switch 758 be mos field effect transistor (Metal Oxide Semiconductor Field Effect Transistor, MOSFET).In one embodiment, switch 758 is complementary with switch 757 actions.In one embodiment, switch 757 is N passage (channel) mos field effect transistor, and switch 758 is a P channel mos field-effect transistor.In another embodiment, switch 758 is a diode (diode).

Please refer to Fig. 8, its demonstration utilizes two 1.5V alkaline batteries of the utility model electronic circuit to drive the experimental result of the LED of 100mA.Curve shows the electric current of the LED that flows through among the figure.Comparison diagram 8 and prior art Fig. 1 b are as can be known, keep at LED under the situation of identical electric current (being that luminosity is identical), using the battery life of prior art only is 100 minutes (shown in Fig. 1 b), and Fig. 8 shows and uses electronic circuit of the present utility model then can significantly prolong battery service time to 205 minute.With reference to this experimental result, can know that understanding reaching under the situation of same brightness, use the utility model not only can save number of batteries, but also extending battery life.

One of ordinary skill in the art will appreciate that herein " battery " or " battery pack " are not limited to dry cell, it can comprise rechargeable battery or the like." battery " also is not limited to the contained alkaline battery of embodiment, and it can comprise lithium battery etc.Though embodiment of the present utility model only shows a light-emitting component, is understandable that, the utility model does not limit the quantity of light-emitting component, but can adopt the light-emitting component of any amount.Be to be embodiment for ease of explanation, but the utility model can replace with LED other similar light-emitting components not as limit with " light emitting diode (LED) " herein.Be illustrated though the utility model is example with the flashlight, be not limited to family expenses or compact flashlights, it also comprises the portable lighting device of different size, different purposes.Such as but not limited to: climb the mountain, prospect used head lamp, or the car light of bicycle or the like.

Above the specific embodiment and accompanying drawing only are the embodiment commonly used of the utility model.Obviously, under the prerequisite that does not break away from the utility model spirit that the appended claim book defined and protection domain, can have and variously augment, revise and replace.Therefore, only be illustrative rather than definitive thereof at the embodiment of this disclosure, the scope of the utility model is defined by appended claim and legal equivalents thereof, and is not limited thereto preceding description.

Claims (20)

1. a portable lighting device is characterized in that, comprising:

Power supply;

Controller, it comprises power input, and this power input electrically connects via first switch and described power supply; And

Load circuit, the power output end of itself and described controller electrically connects, and can produce feedback signal, described controller according to the state and the described feedback signal of described first switch, is regulated the electric energy that offers described load circuit at least via described power output end.

2. portable lighting device according to claim 1 is characterized in that, when the described state of described first switch was closure, described controller was regulated the electric energy that offers described load circuit.

3. portable lighting device according to claim 1 is characterized in that described load circuit comprises at least one light-emitting component.

4. portable lighting device according to claim 3 is characterized in that, described at least one light-emitting component is a light emitting diode.

5. portable lighting device according to claim 3 is characterized in that described load circuit comprises sensing element, the running parameter of described at least one light-emitting component of its sensing, and produce described feedback signal according to this running parameter.

6. portable lighting device according to claim 5 is characterized in that, described sensing element comprises a resistance at least.

7. portable lighting device according to claim 1 is characterized in that, also comprises first electric capacity that electrically connects with described power input.

8. portable lighting device according to claim 1 is characterized in that, also comprises second electric capacity that electrically connects with described power output end.

9. portable lighting device according to claim 1 is characterized in that described controller comprises the switching output, and this switches output and electrically connects via inductance element and described power input.

10. portable lighting device according to claim 1 is characterized in that described power supply comprises battery pack.

11. portable lighting device according to claim 10 is characterized in that, described battery pack comprises at least one dry cell.

12. portable lighting device according to claim 10 is characterized in that, described battery pack comprises at least one rechargeable battery.

13. portable lighting device according to claim 10 is characterized in that, described battery pack comprises alkaline battery.

14. portable lighting device according to claim 10 is characterized in that, described battery pack comprises lithium battery.

15. portable lighting device according to claim 1 is characterized in that, described controller is an integrated circuit.

16. portable lighting device according to claim 1 is characterized in that, described controller comprises:

The low-voltage lock, itself and described power input electrically connect, and the voltage and the predetermined value of described power input relatively produced the low-voltage locking signal;

Circuits for triggering, itself and described power input electrically connect, and produce triggering signal;

Gate generator, it receives described low-voltage locking signal and described triggering signal, and produces clock pulse signal;

The reference switch selector, it receives described clock pulse signal and selects a reference voltage signal according to described clock pulse signal from a plurality of reference voltage signals; And adjuster, it produces conditioning signal according to selected reference voltage signal and described feedback signal, offers the electric energy of described load circuit in order to adjusting.

17. portable lighting device according to claim 16 is characterized in that, described adjuster comprises pulse-width modulation circuit or pulse frequency modulation circuit.

18. portable lighting device according to claim 16 is characterized in that, described controller comprises driver, in order to receive described conditioning signal, offers the electric energy of described load circuit with adjusting.

19. portable lighting device according to claim 16 is characterized in that, when the described state of described first switch for disconnecting, and the described voltage of described power input is when being lower than described predetermined value, described gate generator is reset.

20. portable lighting device according to claim 1 is characterized in that, also comprises power circuit, to regulate the voltage of described power output end.

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