DE19538765A1 - Power saving voltage supply circuit e.g. for electric light source at street building site - Google Patents

Abstract

The circuit includes at least a battery (14) and a voltage source with a nominal voltage which is at least about twice the operating voltage of the light source (12). A clock generator (18) drives the light source in such way, that the medium voltage at fully loaded batteries corresponds to the operating voltage of the light source. The voltage source pref. comprises at least two batteries connected in series, whose nominal voltage is respectively about equal to or larger than the operating voltage of the light source. The clock frequency of generator is more than 25 Hz, pref. more than 1 kHz. The clock generator controls a loss-free power switching element arranged in the circuit loop of the light source.

Description

The invention relates to an economy circuit for supplying an electrical Light source, in particular a construction site lamp, with voltage from a Power source with at least one battery.

In construction site lights for securing road construction sites is called light usually a 6 V or preferably a 5 V incandescent lamp is used, the two parallel batteries with a nominal voltage of 6 each V is fed. Zinc-carbon batteries are usually used, de The energy content in the fully charged state is about 6 to 7 ampere hours is. With two batteries and a power consumption of the incandescent lamp by et wa 90 mA theoretically results in a total operating time of approx. 150 hours with steady light or about 300 hours with flashing light. With increasing Mender discharge of the batteries, however, takes the battery voltage and there with also the brightness of the light bulb. If the battery voltage is below drops about 4 V, the brightness drops so steeply that the batteries are replaced Need to become. In fact, therefore, only operating times of approximately 100 or 200 hours.

Since construction site lights are used in large numbers on construction sites, the frequent replacement of the batteries saves considerable costs. The be Limited operating time can also lead to security risks if the La The condition of the batteries does not exceed at relatively short intervals is checked. It also comes from disposing of the used bat teries to a high environmental impact.

The object of the invention is therefore to provide an economy circuit with which the operating time of the batteries can be extended.

This object is specified according to the invention in claim 1 resolved characteristics.

In the economy circuit according to the invention, the batteries are ge in series switches or a battery with a higher nominal voltage is used, so that the voltage applied to the light source is a multiple of the span voltage for which the light source is actually designed. For example  the 6-volt incandescent lamp with a construction site luminaire with two batteries operated at a voltage of 12 volts. As this surge becomes a ra would lead to destruction of the light source, the light source with ho forth clocked frequency, so that the average voltage back to the connector equivalent to 6 volts. The clock frequency should be so high that for the human eye no flickering of the light source is perceptible. she should therefore, unless a smoothing capacitor with high capacitance is provided is at least about 25 Hz.

If the charge of the batteries in the economy circuit according to the invention has decreased significantly that each battery only has a voltage of about 4 V supplies, the light source receives a voltage of 8 V. The light source shines Tet so bright at this voltage that one is sufficient despite the timing medium brightness is reached. Consequently, the operating time of the Batteries can be extended using the economy circuit.

Advantageous refinements and developments of the invention result itself from the subclaims.

The pulse duty factor of the clock signal generated by the clock generator is preferred variable depending on the battery voltage, so that the Bat Series voltage by extending the switch-on periods at the expense the off periods can be compensated. This makes it possible to use two 6 V batteries until the voltage of both batteries increases has decreased to 4 V together. Every single battery can be up to a residual voltage of 2 V can be discharged so that the battery capacity we is used much better. With suitable optimization of the circuit an extension of the operating time by up to 30% is possible.

The batteries commonly used in construction site lights have that Shape of a square column. The minus pole is in the middle of one of the square end faces, while the positive pole in a corner of this forehead area lies. The two batteries are placed upright side by side in the housing of the construction site light inserted. Since the batteries were previously parallel were switched, the voltage was tapped using three parallel Terminal strips, the middle of which are over the negative poles of the two Batteries stretched. The other two terminal strips were conductive  connected to each other and ran parallel on both sides of the minus terminal ste, so that the plus poles of both batteries are contacted in any case regardless of the orientation of the batteries in the Bat were used in series production. The subject of claims 9 and 10 is a structurally simple arrangement of terminal electrodes, with which this too is achieved for the series connection of the batteries.

A preferred embodiment of the invention is described below the drawing explained in more detail.

Show it:

Figure 1 is a simplified circuit diagram of the economy circuit according to the invention.

Fig. 2 waveforms of a clock signal in the circuit of Fig. 1;

FIG. 3 shows two adjacent batteries in the plan view;

Fig. 4 shows an arrangement of electrodes for contacting the bat teries according to FIG. 3; and

Fig. 5 shows the electrodes in spatial association with the batteries.

The economy circuit 10 shown in Fig. 1 is used to supply power to a light bulb 12 with a connected load of 5 V. The voltage is supplied by two batteries or batteries 14 , each having a nominal voltage of 6 V. Since the batteries are connected in series, a total voltage of 12 V is available.

A clock generator 18 is supplied with the operating voltage of 12 V by closing a switch 16 in the battery circuit. This clock generator supplies as an output signal a clock signal P in the form of a rectangular pulse train, as represented by the solid curve 20 in FIG. 2. The voltage level U0 of the square-wave pulses is equal to the supply voltage actually supplied by the batteries 14 , and the pulse width W is variable as a function of a signal I supplied to the clock generator 18 . The frequency of the clock signal P is on the order of a few kHz.

Via a voltage divider formed by resistors R1 and R2, the clock signal P is fed to the gate of a field effect transistor T1, the source and drain of which are connected to the circuit of the incandescent lamp 12 . Consequently, the incandescent lamp 12 is clocked at the frequency and the pulse width W of the clock signal P. Since the voltage level U0 is equal to the supply voltage, the incandescent lamp 12 receives a voltage on average over time, which is proportional to the mean value of the clock signal. With a duty cycle of 0.5, the average voltage of the incandescent lamp is approximately 6 V.

Via a resistor R3, the clock signal P is fed to a capacitor C1, which is discharged via resistors R4 and R5 with a fixed tent constant, so that the voltage at the anode of the capacitor C1 corresponds to the average value of the clock signal P. This average is again divided by the resistors R4 and R5 and fed to the non-inverting input of a differential amplifier 22 . At the inverting input of the differential amplifier 22 there is a fixed reference voltage which is generated, for example, with the aid of a resistor R6 and a Zener diode Z. The output signal of the differential amplifier 22 is the signal I, which determines the pulse width W of the clock signal P, in such a way that the pulse width increases as the level of the signal I decreases. The average voltage of the clock signal P is regulated in this way in a closed control circuit to the reference voltage. Consequently, the mean value of the voltage applied to the incandescent lamp 12 is also kept approximately at a constant value.

When the batteries 14 are partially discharged and consequently the supply voltage decreases, the voltage level of the clock signal P changes, as indicated by the dashed curve 24 in FIG. 2. However, this decrease in the voltage level is compensated for by a corresponding increase in the pulse width W, so that the mean voltage u _{m of} the clock signal and thus also the mean voltage of the incandescent lamp remain approximately constant. The decrease in the battery voltage therefore does not initially lead to a corresponding reduction in the brightness of the incandescent lamp 12 . Only when the supply voltage drops below about 5 V (which is a little less than half the original value) does the brightness of the incandescent lamp begin to decrease more because then the pulse width W is equal to the period of the clock signal P, so that the pulses become one constant signal merge and a further decrease in the voltage level can no longer be compensated.

Each of the batteries 14 can thus be discharged to a voltage of approximately 2.5 V without this leading to a noticeable decrease in the brightness of the incandescent lamp 12 . Since a certain decrease in the brightness of the incandescent lamp can be tolerated, the batteries 14 only become unusable when their voltage has decreased to approximately 1.8 V.

The functional principle described above is based on the assumption that the brightness of the incandescent lamp is linearly dependent on the mean voltage in the first approximation. In fact, however, the brightness depends roughly square on the mean voltage, because the power of the incandescent lamp corresponds to the product of voltage and current and the mean current is in turn proportional to the mean voltage. This non-linearity and any non-linearities of the clock generator 18 with respect to the signal I are compensated in the exemplary embodiment described in that the non-inverting input of the differential amplifier 22 is connected via a resistor R7 to the plus terminal of the batteries. The signal at the non-inverting input of the differential amplifier, ie the voltage drop across the resistor R5, is thus additively composed of a component which is proportional to the mean value of the clock signal P and a component which is directly proportional to the supply voltage. When the supply voltage decreases, the decrease in the voltage level U0 of the clock signal P is overcompensated to a certain extent. The pulse width W is increased so much that with a decrease in the supply voltage, the mean voltage u _m and thus also the mean voltage supply to the incandescent lamp 12 increases somewhat, by just enough that the average power of the incandescent lamp is kept approximately constant becomes.

A major advantage of the circuit described is that the average power of the incandescent lamp, i.e. the product of medium voltage  and average current, can be kept constant without the medium current directly with the help of a current in the lamp circuit Measuring resistance must be measured. Is in the lamp circuit only the low power field effect transistor T1, so that power losses be reduced to a minimum.

In the following, an arrangement will be described with reference to FIGS. 3 to 4, the light regardless of the installation position of the batteries 14 in a construction site ensures that the batteries are connected to each other in series.

Fig. 3 shows the outline of a battery compartment 26 of a building site lamp with the two adjacently arranged batteries 14. The negative pole 28 of the batteries 14 is located in the middle of the square plan of the battery block, and the positive pole 30 is located in a corner of this square plan.

Fig. 4 shows an arrangement of electrodes 32 , 34 and 36 , which are fastened in the manner shown in the ceiling of the battery compartment 26 so that they produce the electrical contact with the positive and negative poles of the two batteries 14 . The electrode 32 has the shape of a small plate, which lies above the negative pole 28 of one of the two batteries, and is connected to the ground pole of the economy circuit according to FIG. 1. The electrode 34 serves as a bridge for the series connection of the two batteries 14 and has the shape of a fork with a U-shaped part 38 which surrounds the electrode 32 and a stem 40 . The electrode 34 thus contacts the positive pole 30 of the left battery and the negative pole 28 of the right battery. The third Elektro de 36 has a U-shaped plan, which corresponds to the U-shaped part 38 of the electrode 34 . The electrode 36 is electrically connected to the switch 16 of FIG. 1, engages around the stem 40 of the electrode 34 and contacts the positive pole 30 of the right battery.

Fig. 5 illustrates the spatial assignment of the electrodes 32 , 34 and 36 to the batteries 14 , the right battery being shown here in a rotated installation position. The positions of the plus poles are indicated for all possible installation positions of the two batteries 14 by thin dashed lines. It can be seen that the batteries are correctly contacted in every installation position. For the series connection of the two batteries, only three electrodes, each made in one piece, are required, which can be easily manufactured and assembled.

If three or more batteries are to be connected in series, this can be achieved in that a plurality of fork-shaped electrodes 34 are chained together in such a way that the U-shaped part 38 of one electrode engages around the stem 40 of the other electrode.

Claims (11)

1. Economy circuit for supplying an electrical light source ( 12 ), in particular a special construction site lamp, with voltage from a voltage source with at least one battery ( 14 ), characterized in that the nominal voltage of the voltage source is at least approximately equal to twice the connected load of the light source and that a clock generator ( 18 ) the light source ( 12 ) clocks in such a way that the average voltage corresponds to the connected load, at least when the batteries are fully charged. 2. Economy circuit according to claim 1, characterized in that the voltage source has at least two series batteries ( 14 ), the nominal voltage of which is approximately equal to the connected value of the light source ( 12 ) or greater. 3. Economy circuit according to claim 1 or 2, characterized in that the clock frequency of the clock generator ( 18 ) is more than 25 Hz, preferably more than 1 kHz. 4. Economy circuit according to one of claims 1 to 3, characterized in that the clock generator ( 18 ) controls a low-loss power switching element (T1) connected in the circuit of the light source ( 12 ). 5. Economy circuit according to claim 4, characterized in that the Power switching element (T1) is a field effect transistor. 6. Economy circuit according to one of the preceding claims, characterized in that the pulse width (W) of the clock signal (P) generated by the clock generator ( 18 ) can be changed as a function of the supply voltage actually supplied by the voltage source. 7. Economy circuit according to claim 6, characterized in that a dif ference amplifier ( 22 ) compares a signal which represents the supply voltage and / or the voltage supplied to the light source on average over time with a fixed reference signal and the clock generator ( 18 ) with egg nem signal (I) dependent on the comparison result. 8. Economy circuit according to claim 7, characterized in that the voltage level (U₀) of the clock signal is proportional to the supply voltage supplied by the voltage source and that the output of the clock generator ( 18 ) with a mean circuit (C1, R3, R4, R5) is connected, which supplies a signal corresponding to the mean value of the clock signal (P) and which is fed to the differential amplifier ( 22 ). 9. Economy circuit according to claim 7 or 8, characterized in that the differential amplifier ( 22 ) receives a signal which is directly dependent on the supply voltage of the voltage source. 10. Economy circuit according to one of the preceding claims, for use with batteries ( 14 ), each having the shape of a square column and standing upright side by side in a battery compartment ( 26 ) and each having a battery pole ( 28 ) in the middle of the square base Crack and a further battery pole ( 30 ) in a corner of the square plan, characterized in that the economy circuit ( 10 ) for the electrical connection to the batteries ( 14 ) a plurality of electrodes ( 32 , 34 , 36 ) installed in the battery compartment ( 26 ) has, a first ( 32 ) over the center of one of the batteries ( 14 ), at least a second ( 34 ) egg NEN the first electrode ( 32 ) surrounding part ( 38 ) and a projecting towards the center of the adjacent battery ( 14 ) Has handle ( 40 ) and a third electrode ( 36 ) engages around the handle ( 40 ) in a U-shape. 11. Electrode arrangement with several in a battery compartment ( 26 ) installed electrodes ( 32 , 34 , 36 ) for voltage tapping of several batteries ( 14 ), each of which has the shape of a square column and is arranged upright next to each other in the battery compartment ( 26 ) and each have a battery pole ( 28 ) in the center of the square plan and a further battery pole ( 30 ) in a corner of the square plan, characterized in that a first electrode ( 32 ) over the center of one of the batteries ( 14 ) lies, at least one second electrode ( 34 ) has a part ( 38 ) surrounding the first electrode ( 32 ) and a stem ( 40 ) projecting towards the center of the adjacent battery ( 14 ) and a third electrode ( 36 ) has the stem ( 40 ) U -shaped.