DE4344321A1 - Operation of light barrier for use with automatic doors - Google Patents

Abstract

A light barrier system for use with automatic doors uses a two channel infra red transmission path. The low frequency pulses sent along it are multiplexed and for each channel, the received pulses are evaluated in a suitable comparison window. The frequency lies between thirty and sixty kilohertz, and the value of 32.768 kHz is especially recommended. The pulses are sent out in packets with a time width of half a millisecond, and the reception window has a time width of 0.15 ms. Both transmitting and receiving stages have separate power supplies. A suitable transmitter is a LED and a suitable receiver is a phototransistor.

Description

The invention relates to an operating method of a Light barrier module for automatically operating door systems, such as electrically driven sliding doors, elevator doors or the like. with an infrared transmission link. Next to it the invention relates to a suitable for this method Photoelectric barrier module for personal protection at ge above called door systems with at least one infrared transmission distance from a light emitting diode (LED) as Transmitter and a phototransistor as receivers, each of which a driver is assigned.

Automatic door systems are state of the art previously known and are for example in DE-OS 39 40 762 described. They are becoming increasingly important both in indu strategic area as well as in other areas of daily life Life. Essential for the acceptance of such systems are ge suitable controls with appropriate measures for one Personal protection.

Especially for personal protection in electrically powered vehicles Sliding doors, elevator doors or the like are common Light barriers applied, for example with an In infrared transmission line work. They are complete for that modules known.

The known light barrier modules have in principle for proven automatic door systems. Improvement area However, the achievable interference immunity is still poor.  

Occasionally, in particular due to incidence of external light Bad actions are coming.

The object of the invention is therefore an operating method a light barrier module for door systems and the associated one Specify light barrier module with which in particular the Personal protection is improved.

The object is achieved with the features of claims 1. Further procedural measures are specified in the associated dependent procedural claims. A correspondingly constructed light barrier module is the subject of independent claim 6. This light barrier module is further developed in the dependent claims 7 to 12 .

With the invention, a light barrier module is both out visually of the operating procedure as well as regarding the Construction improved. Especially due to the low frequency palpation is the immunity to interference and also the achievable Range of the light barrier significantly increased, the same moderately reduced power consumption. In particular the latter properties were in known light barriers ken modules for door systems still unsatisfactory.

The above advantages are due to the specific structure of the reached light barrier module. In doing so measures implemented in the technology of infrared controls especially in audio and video technology already can be used to transmit different control commands teln. A transfer of such measures, for example pulse modulation on a door system, in which none Control commands must be transmitted, but leads overall to a surprising improvement in the operating behavior of the Photoelectric barrier.

Further details and advantages of the invention emerge from the following description of the figures of the embodiment play. Show it

Fig. 1 is an automatically operated door with a time zweikana light barrier,

Fig. 2 shows the associated block diagram and

Fig. 3a) to h) the related waveforms in operation of the photoelectric switch in FIG. 1 having a circuit configuration according to FIG. 2.

In Fig. 1, 1 denotes an automatically operating door system which has two door leaves 2 and 5 , which are electrically driven by a motor 4 . The door system 1 can, for example, realize a sliding door for an elevator, but also pivoting doors or the like. Via the motor 4 , which can be activated by sensors, the door leaves 2 and 3 open automatically, with predeterminable travel movements being maintained, and automatically close again after certain opening times.

As soon as faults are present, door panels 2 and 3 should remain open. This applies particularly to the entry and exit of people who should not be hindered by the door leaf. This requires so-called personal protection, which is implemented in practice by light barriers. For example, two light barriers are present in the door system 1 at different heights, for which two transmitters 6 a and 6 b and two receivers 8 a and 8 b are aligned with each other in the door wall especially for infrared radiation. When people interrupt the light barrier, who automatically generates the signals to influence the control system.

In general, light barrier modules are multi-channel Infrared transmission paths are available, each one  Realize the light barrier at different heights. In particular in particular, two two-channel modules can be used together operated synchronized.

In Fig. 2, 10 denotes a pulse generator for generating individual pulses with which the operation of two transmitters is to be controlled. The pulse generator 10 is followed by a channel switch 11 , a unit for test shutdown 12 and an LF modulator 13 . The NF modulator 13 is assigned a driver 14 a and 14 b, which each control a light emitting diode 16 a and 16 b. A 12 V supply unit 15 is provided for both light emitting diodes 16 a and 16 b.

Corresponding to the light emitting diodes, photo transistors 18 a and 18 b are arranged, which convert infrared light into electrical signals. The electrical signals go first to a driver unit 20 a or 20 b, which is preceded by a low-pass filter 19 a or 19 b, and then to separate receivers and demodulators 21 a and 21 b. The receivers and demodulators 21 a and 21 b are supplied with 5V by a voltage unit 25 .

From the receiver and demodulator units 21 a and 21 b, the signals each go to comparators 22 a and 22 b, which are equally connected to the outputs of the channel switch 11 . The comparison signals arrive at display units 23 a and 23 b, which together control an output circuit 24 . This may give a control signal to the control circuit, not shown in detail.

From Fig. 2 it can be seen in detail that there are two transmitting and receiving units and the associated control and evaluation logic. The diodes 16 a and 16 b as transmitters and the phototransistors 18 a and 18 b as receivers can be connected to the control and evaluation logic via comparatively long, for example 7 m long, shielded cables 17 , to a compact module in which in particular the transmission signal is generated , the individual amplifications and the evaluations of the received signals are carried out.

The two channels of the transmission stage alternately transmit pulse packets of approximately 0.5 ms duration with the frequency of the LF modulator 13 , for example 32, 768 kHz. The evaluation logic compares each demodulated receive pulse of a channel with its own unmodulated, shortened transmit pulse. In a way, a comparison window is formed. In the event of a missing or garbled reception pulse, the display device 23 a or 23 b signals the fault in the infrared path. The common output then carries voltage potential. Furthermore, a relay, not shown, can pull in, which works on a potential-free contact.

In test mode, one or both transmitters 16 a and 16 b can be switched off via a test input. The receivers 18 a and 18 b then react according to an interruption, the relay being hidden for this case.

In the circuit described in FIG. 2 it is advantageous that 21 a or 21 b IC's from the consumer electronics can be used for the receivers and demodulators. In particular, the use of the relay driver IC's also for controlling the infrared emitting diodes enables considerable savings on components.

In the partial fig. 3a) to h) of Fig. 3, the Signalver courses in the module of FIG. 2 are illustrated in detail. 31 a and 31 b each mean the transmission signal of the first or second channel, each of which has a length tp ≈ 0.5 ms. The signals are sampled according to FIG. 2 with the frequency of 32.768 kHz, for example, which is derived from a quartz crystal. Other frequencies in the kilohertz range are also possible. If necessary, the keying frequency can also be derived from an external processor.

With a corresponding time delay t _d , after demodulation of the transmission frequency at the two outputs of the receivers 21 a and 21 b, an output signal 32 a and 32 b is obtained. These signals are then recorded in a comparison window 33 a or 33 b assigned to the channel. This enables unambiguous identification only of transmission signals.

In addition to the transmission pulse duration t _p , the pulse pause t _r between the individual transmission pulses, which is, for example, nine times t _p, is specified in each channel. The delay time of the received signal to the transmitted signal is denoted by t _d . Since the pulse pause t _{r is} considerably longer than the transmission pulse duration of two channels, in principle more than two channels can also be operated. It has proven suitable to activate a further light _{barrier module} via a synchronization _pulse t _sync , which is constructed according to FIG. 2 and operates according to FIGS . 3a) to f). If necessary, the two-channel test module can also be operated in one channel.

In the arrangement described, the most varied of measures are advantageously combined with one another. The transmission of the NF-keyed pulses in time multiplex results in a particularly low power consumption. Specially the low-pass filter between the line driver and the phototran sistors 18 a and 18 b improves the dynamics of the received signal, since the high-frequency noise is suppressed and only the low-frequency received signal is amplified. Furthermore, the interference immunity is increased by the evaluation via the regulated, selective receiving amplifier and the comparison window. By slowing and rounding the switching edges of the transmission signal, crosstalk between the channels is largely prevented. Overall, this results in a particularly advantageous use of the light barrier module for personal protection in the case of automatically operating door systems.

Claims (12)

1. Operating method of a light barrier module for automatically operating door systems, such as electrically driven sliding doors, elevator doors or the like, with an infrared transmission link with the following features:
- To improve interference immunity when protecting the door system, each transmission pulse is keyed at low frequency,
- The receive pulses are evaluated in a comparison window, which is shifted and shortened compared to the send pulse. 2. The method according to claim 1, characterized by the application with an at least two-channel transmission transmission path, whereby the low-frequency keyed Transmit pulses sent in time division multiplex and for each channel received pulses in a separate comparison window be evaluated. 3. The method according to claim 1, characterized records that the NF keying in the kilohertz range 30 and 60 kHz, for example at 32.768 kHz. 4. The method of claim 1 or claim 3, because characterized in that transmit pulses packets with a duration of approx. 0.5 ms and the reception window with a duration of approx. 0.15 ms. 5. The method according to claim 1, with transmission and reception stages for the transmission line, thereby characterized records that the transmission and reception stages with ge separate power supply. 6. Light barrier module for personal protection in automatically operating door systems, such as electrically powered sliding doors, elevator doors or the like, with at least one infrared transmission path from a light-emitting diode (LED) as a transmitter and a phototransistor as a receiver, each of which is assigned a line driver, characterized in that that to operate the transmission path with low-frequency-keyed transmission pulses, at least the phototransistor ( 18 a, 18 b) as a receiver is assigned a receiver unit ( 21 a, 21 b) with a demodulator for processing a low-frequency modulated received signal. 7. light barrier module according to claim 6, characterized by at least two parallel light transmission paths, each with a transmitter ( 16 a, 16 b) and receiver ( 18 a, 18 b), the transmitters ( 16 a, 16 b) having a channel switch ( 11 ) is assigned for a time-division multiplex operation 8. light barrier module according to claim 6 or claim 7, characterized in that a common NF modulator ( 13 ) is connected before the driver stages ( 14 a, 14 b) for the transmitter ( 16 , 17 ). 9. Light barrier module according to claim 8, characterized in that the LF modulator ( 13 ) is operated by a quartz crystal. 10. Light barrier module according to claim 15, characterized in that the LF modulator ( 13 ) can be controlled by the clock of an external processor. 11. Light barrier module according to claim 5, characterized in that between the phototransistor ( 18 a, 18 b) and the receiver unit ( 21 a, 21 b) a line driver ( 20 a, 20 b) with an upstream low-pass filter ( 19 a, 19 b) is arranged. 12. Light barrier module according to claim 5, wherein the diodes with associated drivers form a transmission stage and the phototransistors with associated line drivers and downstream demodulators form a reception stage, characterized in that the transmission stage (A) and the reception stage (B) each have their own units ( 15 , 25 ) are assigned to the power supply.