CH680627A5 - Control system for fluorescent lamp - responds to detected movement to operate lamp over successive timed intervals with reduced light output - Google Patents

Abstract

The control system uses a movement sensor (1), activating the lamp (9) upon detected movement, to provide a given light output over a timed duration, at the end of which the lamp (9) is switched to a second, lower light output for a second timed duration, before switching off. The 2 timed durations are provided by respective timing devices (5, 3) respectively having a timing interval (T1) corresponding to the first timed duration and a timing interval (T1+T2) corresponding to the sum of the two timed durations. The light output level of the lamp (9) is 100 per cent over the first timed duraton and 10 per cent over the second timed duration. USE/ADVANTAGE - For security lighting with long working life.

Description

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The present invention relates to a method for controlling at least one fluorescent lamp by means of at least one motion sensor and a control device for carrying out the method for at least one such lamp with at least one motion sensor and at least one adjustable ballast for the lamp.

It is known that the service life of a fluorescent lamp is primarily dependent on the frequency with which it is switched off to zero luminous flux or switched on from zero luminous flux.

For example, the tube lifespan in road tunnels with 24-hour lighting is 30,000 to 40,000 hours, while the lifespan of the same fluorescent tubes with a 10-minute on / off cycle is approximately 2000 hours. This is in contrast to the operation of incandescent lamps, the lifespan of which is largely independent of the circuit, but with an approximately five to eight times lower light output and a shorter lifespan of approx. 1000 hours.

The use of fluorescent lamps is therefore far preferable from an energy point of view, both in terms of their basic service life and in terms of luminous efficacy, compared to the use of incandescent lamps.

This is the case in particular in the control of fluorescent lamps via motion sensors of a known type, such as by infrared motion detectors, for example used in zones in which light is needed for a short time when motion is detected in the zone space and the lighting is therefore frequently switched on and off.

The aim of the present invention is to provide a method or a control of the type mentioned at the outset, which, when using fluorescent lamps with motion sensor control, eliminates the problem of frequent switching on and off.

For this purpose, the method according to the invention is distinguished by the wording of the characterizing part of claim 1.

The control according to the invention, which solves the above-mentioned object, is characterized according to the characterizing part of claim 2.

According to the invention, the one or more fluorescent lamps are therefore switched on upon detection of a movement to emit a first luminous flux value, during a predetermined first period of time, in a subsequent second period of time the luminous flux is reduced. Only then is the lamp switched off. The latter can take place immediately after the aforementioned second time period has elapsed, or further luminous flux reductions can be carried out in further time periods.

This procedure on the one hand drastically reduces the switching frequency to or from the zero luminous flux value and at the same time, by reducing the luminous flux during the second period, the electrical energy required for the lamp frequency-reducing operation is kept to a minimum.

The luminous flux of the lamp is preferably switched from 100% to 10% before the lamp is switched off.

Although it is entirely possible to switch on the second timer after the expiry of the first time period or after the first timer set by the motion sensor, practically controlled by the falling edge of this timer, a simple implementation results from the fact that, according to the wording of claim 3 , both timers can be set by the motion sensor and both can be reset. The term “repeatable” is known to the person skilled in the art, for example of the repeatable, monostable multivibrators.

Following the wording of claim 4, the first timer and the motion sensor are integrated into a motion detector. Infrared motion detectors of this type are available on the market, for example from Züblin AG, Zurich.

Following the wording of claim 5, the circuitry implementation is extremely simple in that the second timing element comprises a tracking relay which connects the at least one fluorescent lamp to the network, preferably by switching the ballast to the network.

The invention is subsequently explained, for example, using figures.

Show it:

1 shows the basic procedure according to the present invention on the basis of a qualitative signal / time representation and a luminous flux / time representation,

2 using a functional block diagram, a control according to the invention in an embodiment variant or a possible implementation of the method according to the invention,

3 signal / time diagram to explain the functioning of the control according to the invention, as shown for example in FIG. 2,

4 shows the circuit diagram of a preferred embodiment variant of the control according to the invention or of a preferred embodiment variant of the method according to the invention.

1 shows a pulse i emitted by a motion sensor when a motion is detected, over the time axis t. A first time period Ti of predeterminable or adjustable length is started by this pulse i. After the time period Ti has elapsed, a second time period Tz, of a predetermined or adjustable length, is started.

During the first time period Tt, the luminous flux is controlled to the value Li, for example 100%, on a fluorescent lamp, during the time period Tz to the value Lz reduced in this regard, for example to 10%. At the end of the second time period Tz, either the luminous flux is turned off

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switches, i.e. the fluorescent lamp is deactivated, or, in accordance with the principle according to the invention, possibly further reduced the luminous flux step by step in further time spans, but this is only useful in rare cases.

This simple principle of the method according to the invention, illustrated with reference to FIG. 1, is now realized, for example, by means of an arrangement as shown in FIG.

A motion sensor 1, preferably an infrared sensor, outputs a pulse i at its output Ai when motion B is detected. The pulse i is connected to a timer 3, which, as shown, operates in accordance with a resettable, monostable multivibrator.

The time duration (Ti + T2) of the pulse emitted on the output side can preferably be set on the timing element 3. If a single pulse i occurs, the pulse of time length (Ti + T2) is triggered at output A3 and then drops again. If a further pulse i occurs during the time during which the output pulse is set, the output pulse at output A3 will again stop during (Ti + I2) from the last-mentioned pulse, i.e. extended accordingly.

The pulse i is further fed to the set input S5 of a second, resettable timer 5, again operating according to a resettable, monostable multivibrator. The associated time constant Ti, again preferably adjustable, is shorter than the time constant (Ti + T2) of the timing element 3.

The output pulse at the output A5 switches the output pulses from A3 to control inputs of an electronic, controllable HF ballast 7 of known type, as shown schematically, either to a stage E100 or to a stage E10, and accordingly the fluorescent lamp 9 is switched on by the ballast 7 controlled to emit, for example, 100% luminous flux or 10% luminous flux.

3 shows, for example, the sequence of output pulses at the output A3, at the output A5 or the luminous flux L of the fluorescent lamp 9, depending on a sequence of pulses i, for example, selected at the output Ai of FIG. 2.

4 shows a preferred form of realization of a control according to the invention. At the control inputs S7 of an electronic, controllable HF ballast, as it is sold, for example, by Philips under the name BHFD12, the switching path rn of a relay 11 lies above an RC element. The relay 11 lies between ground N and a connection 13, the latter of which is located above an infrared motion detector 15 to be described on the network Li.

An operating switch 17 is connected in parallel above the motion detector 15. The control input S17 of a tracking relay 17 with switching path ri7 is connected between the connection 13 and the mains connection Li and operates with a preferably adjustable delay time (Ti + T2).

On the output side of the adjustable ballast

tes 7, as shown schematically, one or more fluorescent lamps 9 are switched.

The motion detector 15, which works as an infrared base, is a detector which, integrated in the detector, on the one hand comprises an infrared sensor, possibly a differentiating element connected thereto, in such a way that a movement detected by the sensor is in the form an impulse is output.

In addition, a monostable circuit is integrated in the detector 15, with the resettable time constant Ti, so that the switching path r 1 of the detector 15 is switched through when movement is detected during the adjustable and resettable time period Ti. This circuit works as follows:

When the operating switch 17 is open, when a movement is detected, the switching path ns is closed, whereby the relay 11 opens, the RC circuit charges, whereby the ballast 7 controls the lamp 9 for 100% luminous flux. To make this possible at all, the ballast 7 is simultaneously activated by activating the relay 17 and closing its switching path ri7 via line 19. The one or more fluorescent lamps 9 thus light up with 100% luminous flux.

When the time period Ti set on the motion detector 15 has elapsed, its switching path ris opens, whereby relay 11 is de-energized and its switching path rn closes. The RC element is discharged, the control input S7 of the ballast 7 is short-circuited, with which the lamp 9 is controlled for a reduced luminous flux, as mentioned, for example 10%.

Thus, the fluorescent lamp 9 continues to burn, but with a luminous flux reduced to 10%. Since the time period (Ti + T2) of the relay 17 has not yet expired, its switching path ri7 remains closed and maintains the electrical supply to the ballast 7. When the time period (Ti + T2) has elapsed, the switching path ri7 opens, with the ballast 7 becoming de-energized and consequently putting the fluorescent lamp 9 out of operation.

If a new time span of length Ti is started via detector 15 when relay 11 is activated or deactivated, the time span (Ti + T2) at relay 17 is also restarted at the same time. The last movement detected in time is therefore decisive for the control sequence.

The switching frequency is thus significantly reduced to 0% luminous flux or from 0% to 100% luminous flux on the fluorescent lamp 9, whereby, after Ti since the last movement detection, the luminous flux is significantly reduced and thus the electrical energy consumed by the fluorescent lamp 9.

Claims (6)

Claims 1. A method for controlling at least one fluorescent lamp by means of at least one motion sensor, characterized in that, when a motion is detected by means of the sensor, the lamp is used to emit a luminous flux 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 3rd 5 CH 680 627 A5 a first, predetermined value is activated during a first, predeterminable period of time, after the end of the first period of time, during a second, to emit a luminous flux with a second predeterminable value less than the first, - After the second time period, the lamp is switched off, immediately or after further reduction of the luminous flux during further time periods. 2. Control device for performing the method according to claim 1 for at least one fluorescent lamp with at least one motion sensor and at least one adjustable ballast (7) for the lamp (9), characterized in that the motion sensor (1, 15) on the output side to the set input a resettable, first timer (5, 15) acts, a second timer (3, 17) is provided, which remains set for a predeterminable time period (T2) after the first timer (5.15) has dropped out of the set state the outputs of the two timing elements (5, 3, 15, 17) control the activation of the lamp (9) in an OR action combination, the output of the first timing element (5, 15) to a control input (E, S7) of the ballast (7) acts and, in the set state, controls the ballast in such a way that the lamp emits a luminous flux with a first value (Li), has dropped so that the lamp (9) has a luminous flux with a second, lower value ( L2) outputs. 3. Control device according to claim 2, characterized in that both timing elements can be set by the motion sensor and both can be reset. 4. Control device according to one of claims 2 or 3, characterized in that the first Zeitgiied and the motion sensor are integrated in a motion detector (15). 5. Control device according to one of claims 2 to 4, characterized in that the second timer comprises a tracking relay (17) which connects the at least one fluorescent lamp to the network, preferably by switching the ballast (7) to the network. 6. Control device according to claims 2 to 5, characterized in that the motion sensor (15) is an IR sensor. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 4th