DE20313782U1 - Torch, especially rod light, has light source circuit connected before light source to convert circuit's input voltage into suitable LED supply voltage above threshold light voltage of LED - Google Patents

Abstract

The torch has a compartment (10) for energy carriers and at least one light emitting diode (20) as a light source. A light source circuit (28) is connected before the light source to convert the circuit's input voltage into a suitable LED supply voltage above the threshold light voltage of the LED. The light source circuit contains a d.c.-d.c. converter that converts the input voltage into an a.c. voltage, transforms this into a higher frequency a.c. voltage and converts this into a rectified LED supply voltage. An independent claim is also included for the following: (a) a light source circuit for an inventive device.

Description

S:\IB5DUP\DUPANM\200309\4 6060007-2 0031678.doc

Applicant:

Witte + Sutor GmbH

Steinberger Strasse 2

71540 Murrhardt

46060007 04.09.2003

ABU/LBE

Title: Flashlight, in particular flashlight and light circuit therefor

Description

The invention relates to a flashlight, in particular a rod light, with a compartment for energy sources and with at least one light-emitting diode as a light source. Such flashlights are known in many different ways. Batteries (galvanic primary cells) or accumulators (galvanic secondary cells) are particularly suitable as energy sources. In order to light up light-emitting diodes (LEDs) suitable for flashlights, a comparatively high threshold voltage of approximately 3 to 4 V is required. Known battery or rechargeable battery elements have a nominal voltage of 1.2 V to 1.5 V.

Operators of a flashlight with LEDs therefore require at least two known battery elements, for example two mono batteries. When using accumulators, a corresponding number of battery elements are required to achieve the corresponding threshold light voltage.

For direct battery or accumulator operation, where the LED is connected directly to the battery or accumulator, at least three or more battery or accumulator cells are required. Lights with fewer battery or accumulator cells do not light up or do not light up optimally due to the LED supply voltage being too low, which is below the threshold voltage of the LED.

The present invention is based on the object of providing a flashlight with light-emitting diodes as lighting means, which is comparatively small and which can be operated with energy sources whose nominal voltage is below the threshold voltage of the corresponding light-emitting diodes.

This task is solved with a flashlight of the type described above in that a lighting circuit is connected upstream of the lighting device, which converts the circuit input voltage, i.e. the discharge voltage of the energy carriers, into a suitable LED supply voltage that is above the threshold lighting voltage of the light-emitting diode.

The provision of such a suitable lighting circuit serves to

The circuit input voltage, i.e. the discharge voltage of the energy sources, is to be "increased" in such a way that an LED supply voltage is provided that is above the threshold lighting voltage. According to the invention, the circuit input voltage can be in the range from 1.5 to 10 V; the converted LED supply voltage is advantageously in the range from 4.5 to 12 V. Lights according to the invention therefore require fewer batteries or accumulators than known LED flashlights.

The lighting circuit advantageously has a DC-DC converter which converts the circuit input voltage into an alternating voltage, transforms the alternating voltage into a higher frequency alternating voltage and converts the transformed alternating voltage into the rectified LED supply voltage. By providing such a DC-DC converter, an input direct voltage can be converted into a higher voltage output direct voltage.

Advantageously, the lighting circuit is designed in such a way that a largely constant LED supply current is provided as the discharge voltage decreases. This means that the light-emitting diode has a constant luminosity due to the largely constant LED supply current. In particular with LEDs

The luminous intensity is strongly dependent on the current flowing through the LEDs.

The lighting circuit is also advantageously designed in such a way that when a threshold discharge voltage is reached, the discharge voltage is kept at least largely constant at the level of a base voltage while the LED supply current then decreases. This has the advantage that the energy provided by the energy sources can be used optimally. The LED supply current is initially kept constant as long as this supply current can be made available. If the decreasing discharge voltage reaches a threshold discharge voltage, then it is no longer the LED supply current that is kept largely constant, but the discharge voltage, i.e. the circuit input voltage. If the discharge voltage is kept constant, a residual current flows through the LEDs, which causes the LEDs to glow for a comparatively long time. This signals to the operator of the flashlight that the energy sources will soon be empty; he is prompted to replace the energy sources. Another advantage is that when rechargeable batteries are used as energy sources, a deep discharge that damages the batteries does not occur. The base voltage is advantageously within the range of a permissible discharge voltage of the batteries. This increases the service life of the batteries.

The base voltage can be in the range of the threshold discharge voltage. In order to maintain a certain residual current for the afterglow of the LED, the base voltage can also be below the threshold discharge voltage.

Another particularly preferred embodiment of the invention provides that the flashlight has switching means ■ for switching between rechargeable battery operation and battery operation, wherein in rechargeable battery operation the lighting circuit works in such a way that when a threshold discharge voltage is reached, the discharge voltage is kept at least largely constant at the level of a base voltage while the LED supply current then decreases. The supply current can, as already mentioned, be equal to or less than the threshold discharge voltage. In battery operation, however, a deep discharge of the energy sources below the threshold discharge voltage can take place. This ensures that a deep discharge that damages the battery cells cannot take place when operating with rechargeable cells. On the other hand, when operating with battery cells, the lighting time of the LEDs is maximized because a deep discharge of the battery cells can take place.

The circuit input voltage may vary slightly depending on the battery or accumulator type used. The lamp circuit preferably provides a constant LED output independent of the circuit input voltage.

6
supply current.

The switching devices can be operated manually or switch automatically. Examples of manually operated switching devices include switch plugs or switches, for example in the form of toggle, rotary or push-button switches. Automatic switching can occur, for example, depending on the discharge characteristics of the energy sources. The lighting device circuit compares, for example, the temporal progression of the discharge voltage with stored discharge voltages. If the recorded discharge corresponds to a battery characteristic curve, then these are battery cells. If the monitored discharge corresponds to a characteristic curve of rechargeable cells, then there are rechargeable cells in the flashlight's storage compartment.

Automatic switching can also occur, for example, depending on the external design of the energy source. For this purpose, the flashlight can, for example, have sensors that scan the energy source. Based on characteristic features of the energy source, it can then be determined whether it is battery cells or rechargeable cells.

The object mentioned at the outset is also achieved by a lighting circuit for a flashlight according to the invention.

Further details and advantageous embodiments of the invention can be found in the following description, in which the invention is described and explained in more detail with reference to the embodiments shown in the drawing.

Show it:

Figure 1 shows a flashlight according to the invention in longitudinal section;

Figure 2 is a schematic representation of a

Lamp circuit of the flashlight according to Figure 1; and

Figure 3 shows the circuit input voltage and the LED supply current of the flashlight according to Figure 1, plotted over time.

Figure 1 shows a flashlight 10 according to the invention in the form of a rod light. The rod light 10 comprises a compartment 12 for energy sources 14, which in the exemplary embodiment are designed as two dry batteries 18. Instead of dry batteries, corresponding accumulators can be used. Likewise, according to the invention, only one battery/accumulator or three or more batteries/accumulators can be provided.

The rod light 10 comprises lighting means 20 in the form of light-emitting diodes. The light-emitting diodes 20 are arranged in a shielded lighting space 22 which is covered by an optic 24. The light-emitting diodes 20 are arranged on a circuit board 26 on which further electrical/electronic components are provided. In particular, a lighting circuit 28 is located on the circuit board 26, which converts the circuit input voltage, which is equal to the discharge voltage of the energy sources 16, into an LED supply voltage which is above the threshold lighting voltage of the light-emitting diodes 20. In order to light up, light-emitting diodes require a certain threshold lighting voltage above which the light-emitting diodes light up with sufficient brightness. The lighting circuit 28, which in particular comprises a DC-DC converter, converts the applied direct current discharge voltage of the energy sources 16 into an alternating voltage. The alternating voltage is then transformed into a higher frequency alternating voltage, which in turn is converted into a rectified LED supply voltage. The LED supply voltage is above the threshold voltage and in particular above the circuit input voltage.

The lighting circuit 28 therefore ensures that light-emitting diodes, whose supply voltage is normally in the range of 3.5 - 4.5 V, can be operated with just two dry batteries, which together have a discharge voltage of just 3 V. The total of four

LEDs 20 are connected in series and are supplied with a largely constant supply current of approximately 32 to 33 mA. The series connection of the LEDs 20 ensures that the LEDs 20 are supplied with the same current, i.e. they have largely the same brightness. The discharge voltage of the energy sources, or the circuit input voltage, is approximately 3 V for two dry batteries; for two corresponding accumulators, the input voltage is approximately 2.4 V. An LED supply voltage of up to over 10 V is provided via the lighting circuit 28.

Figure 2 shows a schematic representation of the energy sources 16, which are connected upstream of the lighting circuit 28, and the light-emitting diodes 20, which are connected downstream of the lighting circuit 28. The discharge voltage of the energy sources 16, which is equal to the circuit input voltage, is designated by Ue. The LED supply voltage is designated by Uled, the associated LED supply current by Iled. The circuit input current is designated by Ie. In the flashlight shown, U _E is less than the threshold lighting voltage Uschweii and U _L ed is greater than Uschweii. The lighting circuit 28 consequently converts the circuit input voltage U _E into an LED supply voltage Uled, which is above the threshold lighting voltage Uschweii.

Figure 3 shows the circuit input voltage U _E and the LED supply current Iled plotted against time. As the

As can be seen from the diagram shown, the lighting circuit 28 is designed such that up to a time ti a largely constant LED supply current Iled of approximately 32 - 33 mA is made available for the light-emitting diodes. Due to the discharging energy sources, the circuit input voltage U _E decreases up to the time ti. If the circuit input voltage Ue, which is equal to the discharge voltage of the energy sources, reaches a threshold discharge voltage U _S e, the discharge voltage U _E is reduced to the level of a base voltage U _G. The circuit input voltage U _E is kept constant at the value of the base voltage U _G in the period greater than ti. The base voltage U _G is, according to Figure 3, smaller than the threshold discharge voltage Use. According to the invention, however, it can be provided that the base voltage Ug can also be equal to the threshold discharge voltage Use.

Because the circuit input voltage or the discharge voltage Ue is kept constant, the LED supply current Iled decreases in the period t > ti. Even if the LEDs are supplied with a voltage that is below the threshold voltage Uschweii of the LEDs, the LEDs 20 continue to glow for a comparatively long time. This has the advantage that the operator of the flashlight is made aware that the energy sources are running low without an abrupt failure of the flashlight occurring.

Advantageously, the base voltage Ug is dimensioned such that when the flashlight 10 is operated with battery power, the battery cells are discharged to their permissible discharge voltage, so that a deep discharge that could damage the battery cells is avoided. The service life of the battery cells is thereby significantly extended.

As is clear from Figure 3, the lighting circuit according to the invention can be characterized in that first the LED supply current Iled is kept constant, and then at a time ti the circuit input voltage, or the discharge voltage of the energy carriers Ue, is kept constant.

According to the invention, the lighting circuit 28 can be designed such that the time ti is designed as a time window.

In order to ensure optimum operation of the flashlight, the flashlight 10 is provided with switching means in the form of a switch 30, with which the flashlight 10 can be switched between rechargeable battery operation and battery operation. The switch 30 is arranged on the circuit board 26 in the flashlight 10 according to the invention shown in Figure 1. The switch 30 can be arranged in such a way that it can be operated from the outside of the flashlight 10. On the other hand, it is conceivable that the switch 30 is only accessible or operable when the energy sources 16 are exchanged. Furthermore,

According to the invention, the switch 30 can be provided to switch over automatically when battery cells are used instead of rechargeable cells, or vice versa. Automatic switching can be dependent, for example, on the discharge characteristics of the energy sources 16. Due to the different discharge behavior of rechargeable cells and battery cells, it is conceivable that the lighting circuit can draw conclusions after just a few seconds or after a few minutes as to whether the flashlight is operated with battery cells or with rechargeable cells. Switching can also be dependent on the external design of the energy sources.

In battery operation, the battery cells are discharged according to the diagram shown in Figure 3. In battery operation, however, the energy sources are deeply discharged below the threshold discharge voltage Use. The energy sources can therefore be completely discharged in battery operation, which maximizes the lighting time of the flashlight 10. The circuit can be designed in such a way that a largely constant base voltage Ug is not maintained in battery operation. Instead, a largely constant LED supply current Iled is provided for as long as possible. The point in time ti at which the energy sources are too weak to provide the supply current Iled generally occurs at a later point in time in battery operation than in battery operation.

All features presented in the description, the following claims and the drawing can be essential to the invention both individually and in any combination with one another.

Claims (8)

1. Flashlight ( 10 ), in particular a rod light, with a receiving compartment ( 12 ) for energy sources ( 14 ) and with at least one light-emitting diode ( 20 ) as a lighting means, characterized in that a lighting means circuit ( 28 ) is connected upstream of the lighting means ( 20 ), which converts the circuit input voltage (U _E ) into a suitable LED supply voltage (U _LED ) which is above the threshold lighting voltage (U _Threshold ) of the light-emitting diode ( 20 ). 2. Flashlight ( 10 ) according to one of claims 1, characterized in that the lighting circuit ( 28 ) comprises a DC-DC converter which converts the circuit input voltage (U _E ) into an alternating voltage, transforms the alternating voltage into a higher frequency alternating voltage, and converts the transformed alternating voltage into the rectified LED supply voltage (U _LED ). 3. Flashlight ( 10 ), in particular a rod light, with a receiving compartment ( 12 ) for energy sources ( 14 ) and with at least one light-emitting diode ( 20 ) as a lighting means, in particular according to one of claims 1 or 2, characterized in that the lighting means ( 20 ) is preceded by a lighting means circuit ( 28 ) which is designed such that a largely constant LED supply current (I _LED ) is provided with decreasing discharge voltage (U _E ). 4. Flashlight ( 10 ) according to one of claims 1, 2 or 3, characterized in that the lighting circuit ( 28 ) is designed such that when a threshold discharge voltage (U _SE ) is reached, the discharge voltage (U _E ) is kept at least largely constant at the level of a basic voltage (U _G ) with the LED supply current (I _LED ) then decreasing. 5. Flashlight ( 10 ) according to one of the preceding claims, characterized in that the basic voltage (U _G ) is equal to or less than the threshold discharge voltage (U _SE ). 6. Flashlight ( 10 ) according to one of the preceding claims, with a receiving compartment ( 12 ) for energy sources in the form of battery cells or rechargeable cells, characterized in that switching means ( 30 ) are provided for switching between rechargeable battery operation and battery operation, wherein in rechargeable battery operation the lighting circuit ( 28 ) operates according to the features of claims 4 or 5 and in battery operation a deep discharge of the energy sources below the threshold discharge voltage (U _SE ) takes place. 7. Flashlight ( 10 ) according to claim 6, characterized in that the switching means ( 30 ) can be operated manually or switch automatically. 8. Illuminant circuit ( 28 ) suitable for a flashlight ( 10 ) according to one of the preceding claims.