DE29700991U1 - Flashlight - Google Patents

Description

ES 10163 Gbm

Dr. Dirk Homann
Wormser Str. 16
42119 Wuppertal

Flashlight Description

The innovation concerns a flashlight with battery, operating switch and light source in/on the lamp housing.

With conventional flashlights, the batteries run out after a relatively short period of use due to their light sources, namely incandescent lamps with a low efficiency, and need to be replaced with fresh ones. Flashlights with an extended service life are equipped with larger batteries, which has the disadvantage that this type of flashlight is bulky and difficult to transport.

The innovation is based on the task of creating a flashlight of the type mentioned above that is comparatively small and light.
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The problem is solved with the characterizing features of claim 1, namely in that at least one light-emitting diode serves as the illuminant.

The LED used in the innovation has a lower energy consumption and can therefore compensate for the disadvantages of the

overcome the state of the art and provide a flashlight that is easier to transport.

Since the LED emits monochromatic light, there is the additional advantage that less optical scattering from water droplets enables improved long-distance visibility, for example in fog.

In addition, LEDs have a long service life (typically 10 hours) and are not very sensitive to shock, so that the new flashlight is an extremely reliable light source.

Advantageous embodiments of the innovation can be found in the subclaims.

A preferred embodiment of the innovation is described below with reference to the accompanying drawing, in which:
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Fig. 1 is a front view of a flashlight according to the

Innovation that shows groupings of LEDs,

and

Fig. 2 is a circuit diagram of a control circuit for one of the groups of light-emitting diodes with high beam effect shown in Fig. 1.

0 Fig. 1 shows a total of 1

Flashlight according to the innovation in front view. Behind a watertight circular glass pane 2 there is a circularly contoured carrier plate 3 in which six holes with the same central angle are provided on two concentric circles. There is also a hole in the middle in which a reflector 4 is attached for a light-emitting diode 5 held by the reflector 4. Further

six reflectors 4 with the same LEDs 5 are provided on the outer concentric circle, which together with the central reflector 4 and the central LED 5 form a grouping of seven LEDs 5 with high beam effect.

The reflectors 4 are parabolically shaped and reflect light emerging from the side of the light-emitting diode 5 into a parallel light beam.

When the circularly contoured carrier plate 3 is fitted with the reflectors 4, six gaps are created between adjacent reflectors 4 on two concentric circles. In the gaps on the inner concentric circle there are six holes for accommodating additional light-emitting diodes 6, which form a grouping of six light-emitting diodes 5 with a close-up light effect.

The light-emitting diodes 5, 6 emit yellow light with a wavelength of 590 nm. This color is particularly effective in terms of the spectral sensitivity of the human eye, and these yellow light-emitting diodes currently produce up to 680 lm/W. In addition, the light-emitting diode, which emits monochromatic light with a relatively long wavelength, enables improved long-distance vision because there is less optical scattering from water droplets, for example in fog.

In the following, a circuit diagram of a control circuit for the grouping of light-emitting diodes 5 with high beam effect shown in Fig. 1 is described with reference to Fig. 2.

A reed switch 7 is located next to two other reed switches 8 and 9 inside the flashlight 1. The reed switches 7, 8 and 9 form an operating switch which is operated by a magnet (not shown) in a ring around a

The flashlight shaft is also not shown and is rotatably mounted. The flashlight shaft also serves as a battery compartment for two to five lithium batteries 10.

By the respective closed reed switch 7, 8

or 9, only a very small current flows into a voltage divider made up of resistors 330 &Kgr;&OHgr; + 1.8 &Mgr;&OHgr; (or 150 &Kgr;&OHgr; + 0.9 &Mgr;&OHgr; in the case of the near and far beam effect) to switch a FET (field effect transistor) 11 10. on, which then conducts the "strong" current (of the order of 50 to 150 mA). This low current load with the current only for the voltage divider prevents the reed contacts 7, 8 and

9 safely avoided.
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While the positive battery voltage Θ is always applied to the series-connected LEDs 5 via a coil 12 (50 ßE) and a Schottky diode 13, a current flow can only occur when the FET 11 is conductive. 20

It is now assumed that the FET 11 is conducting, so that a control module 14 also receives a voltage required for its operation. The control module 14 is connected on the output side via an OR gate used for adaptation to the gate connection 16 of another FET 17, the source-drain path of which indirectly connects the negative pole (-) of the lithium battery 10 to the connection point of coil 12 and Schottky diode 13. The control module 14, which can oscillate at a frequency of < 300 kHz, receives a current-indicating signal at its one control connection 18 from a measuring resistor 19 (33 Ω) connected in series with the LEDs 5, which the control module 14 uses for pulse width modulation in order to stabilize the current through the LEDs 5.

The control module 14 also has a pulse sequence control, which is expressed by the fact that the

Control module 14 switches off the pulse generation cyclically when a control range limit (upper current range) is reached.

The source terminal of the further FET 17 is connected to the negative pole (-) of the lithium battery 10 via a current measuring resistor (0.1 Ω), and the control module 14 monitors the voltage drop with its control terminal 19 so that the current flow through the further FET 17 can be limited.

The coil inductance serves to store energy during the switching processes that the control module 14 transmits to the other FET 16. The voltage induced by the coil 12 when the current is switched off (blocking the FET 17) can exceed the battery voltage, so that there is a high degree of independence from the battery voltage, with the advantage that the battery charge can be used almost completely, whereby the LEDs 5 are controlled with their nominal current even when the battery voltage has dropped and shine at a constant brightness.

It should be mentioned that when using several batteries, they are connected in series to ensure a longer service life of the flashlight 1. As the supply voltage increases, the battery current drops due to the constant power requirement. For example, with a 5 V battery, 150 mA will flow, and with a 15 V battery, the battery current drops to 50 mA.

The control module 14 obtains its operating voltage of approximately 14.5 V from the cascaded voltages of six of the seven light-emitting diodes 5. Due to the small dynamic internal resistances typical for light-emitting diodes, the operating voltage generated in this way for the control module 14 is always stable.

The circuit also has a red LED 20, which can be activated when the battery voltage falls below a value that can be determined by the division ratio of a voltage divider 21. The red LED shines backwards. This can be used to indicate that a battery change is imminent.

The control circuit shown in Fig. 1 is provided twice in the flashlight 1. While the control circuit for the grouping of LEDs 5 with a high beam effect has been described previously, the second control circuit is used for the grouping of six LEDs 6 with a close-up light effect. Since in the second control circuit only the number of LEDs to be controlled (six instead of seven) is different, the control circuit will not be described again.

From the above it is clear that the close-beam and long-beam areas can be adjusted electronically. This has the advantage that the usual mechanical focusing by turning the reflector along a screw-shaped slot and the associated wear can be eliminated.

The new flashlight 1 can be made waterproof without great effort. This is made possible in particular by the magnetic operating switch 7 to 10, whose magnet which determines the switching position is rotatably mounted in a ring around the flashlight shaft, as already described.

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List of reference symbols

1 flashlight

2 waterproof circular glass panes

3 circular contoured carrier plate

4 Reflector

5 LED with high beam effect

6 LED with close-up light effect

7 Reed switch for high beam effect

8 reed switches for close-up lighting

9 reed switches for near and long beam effect

10 lithium batteries

11 FET

12 Coil

13 Schottky diode

14 Control module

15 OR gate

16 Gate connection

17 additional FET

18 Control connection for current stabilization

19 Control connection for current limitation

20 red LEDs

21 Voltage divider

Claims (1)

ES 10163 Gbm Dr. Dirk Homann
Wormser Str. 16
42119 Wuppertal Flashlight Protection claims 1. Flashlight, with battery, operating switch and Illuminant in/on the luminaire housing, characterized in that at least one light-emitting diode (5, 6) serves as illuminant. 2. Flashlight according to claim 1 with high beam effect, characterized in that a reflector (4) is provided for the light-emitting diode (5, 6). 3. Flashlight according to claim 2, with adjustable close and long beam effect, characterized in that for the close-up light effect at least one light-emitting diode (6) is provided in a first circuit, that for the At least one light-emitting diode (5) is provided in a second circuit for the high beam effect and that the two circuits can be closed individually and/or together by the operating switch (7, 8, 9, 11). Flashlight according to one of the preceding claims, characterized in that the power supply from the battery (10) takes place via a current-controlled chopper circuit (12 to 19) which uses an inductance (12) as an energy store. 5. Flashlight according to claim 4, characterized in that for current control the duty cycle of the chopper circuit (12 to 19) is variable. 6. Flashlight according to claim 4 or 5, characterized in that for current control a pulse generation blocking device is used which blocks the pulse generation when a predetermined maximum current value is exceeded and which cancels the blocking device for pulse generation when the current value falls below a predetermined minimum current value. Device (14 to 19) for pulse sequence control is provided. 7. Flashlight according to one of the preceding claims, characterized in that the operating switch (7, 8, 9, 11) has at least one reed contact (7, 8, 9), the switching position of which can be changed by a magnet movably provided on the lamp housing. 8. Flashlight according to claim 7, characterized in that the reed contact (7, 8, 9) is connected to a control terminal of a operating current switching semiconductor switch (11). 9. Flashlight according to one of claims 2 to 8, whose reflector is rotationally symmetrical, characterized in that six Light-emitting diodes (5) provided with a reflector (4) are grouped in a circle around a centrally arranged light-emitting diode (5) provided with the reflector (4). 10, Flashlight according to claim 9, characterized in that six reflectorless light-emitting diodes (6) with close-up light effect are grouped on a circle in the areas not occupied by the reflectors (4). 11. Flashlight according to one of the preceding claims, characterized by yellow light-emitting diodes (5, 6) 20 * * *