DE1566733C3 - Light-controlled arrangement for unlocking and monitoring a lock - Google Patents

Description

The invention relates to a light-controlled arrangement for unlocking and monitoring a shutter in which the light emitted by a light source has at least one frequency is clocked and a light receiver is arranged, the means are downstream with which the coincidence the clock frequency. «! in the received signal can be determined and in the event of coincidence the lock is unlocked.

Such assemblies, also called photocells, which operate with visible light, can, / .. example, are not used in a safe or in a building for securing a closure. Direct light barriers, the frequency range of which is in the infrared, do not have this disadvantage. Such constant light barriers can be implemented with GaAs luminescence diodes. However, most of the photo elements that serve as receivers in such a direct light barrier can be outwitted by normal light. A security that roughly corresponds to that of a security lock is therefore not guaranteed even with such a direct light barrier.

An arrangement of the type mentioned above, which, however, only serves to unlock a lock and does not serve to monitor it, is known from GB-PS 972 811, for example. At this known arrangement, the light emitted by the light source is scanned by mechanical means, and mechanical means for determining the coincidence are provided in the receiver. With such By mechanical means, light can only be clocked at relatively low frequencies. There is therefore only a relatively narrow one for the unlocking arrangement Frequency range available, and the arrangement can be tricked, since this only consists of one In a narrow frequency range, the frequency at which the arrangement responds is to be singled out. Also are the mechanical means with which the light is scanned and the coincidence is determined, susceptible to failure, and they can only be produced with a high economic outlay and in no way for different frequencies to build in series production.

For example, in DT-PS 898.564, an interchangeable light cabinet is described in which a photodiode is followed by a receiver that triggers an alarm / when the photodiode is exposed to light at a lower frequency, ie ^; with ^; longer exposure periods, or no light is incident. This light barrier is not suitable for unlocking or monitoring a shutter, as its receiver must not remain unexposed for a long time. In addition, this light barrier can be outwitted at any time with an alternating light of higher frequency than the frequency of the monitoring light source, because it only responds if the exposure periods become longer or if the exposure fails. This device should therefore not be used for higher security requirements.

For example, from US Pat. No. 2,284,289, a light barrier for monitoring is known in which the receiver the received light is further processed in a resonance amplifier. Also this light barrier is only suitable for monitoring, since the receiver does not remain unexposed with it either allowed.

For example, in reference GB-PS 1 017 178, an alternating light barrier is described, which is designed as a reflective light barrier. With this light barrier, the light is emitted by a light emitting diode sent out. By designing it as a reflective light barrier, it is possible to use transmitters and Build receivers close together, connect them electrically to one another and thus make a comparison the frequency sent by the transmitter and the frequency received in the receiver. Such a A structure in which the transmitter and receiver are electrically connected to one another can be used for a Monitoring used light barrier can be used advantageously. In an arrangement in which with Light a lock is to be unlocked, such an arrangement is not possible because the transmitter in the generally should be transportable.

For example, from DT-PS 718 361 a light barrier is known, which in its structure has previously corresponds to the light barriers described, but in which the light beam is clocked at two frequencies.

In the DL-PS 16 684 a combination lock is described that when you enter a wrong Combination of numbers triggers an alarm.

The task is to build an arrangement of the type mentioned at the beginning with increased monitoring security and low susceptibility to failure, whereby the arrangement should be realizable with simple means and suitable for series production.

According to the invention, this object is achieved in that a luminescent diode is used as the light source it is provided that with the means connected downstream of the light receiver also the anticoincidence of the Clock frequencies in the received signal can be determined and an anti-coincidence alarm is triggered and that the light receiver in the input circuit of a broadband Selective amplifier is arranged, which is followed by a narrowband selective amplifier, the output of which is fed to the means for determining the coincidence or anticoincidence,

The arrangement according to the invention serves both for monitoring and for unlocking a lock, since with it the lock is unlocked in the event of a coincidence and an alarm signal is triggered in the event of an anticoincidence. The frequencies with which is clocked the light of erfihdu'ngsgemäßeri [arrangement can be considered a '' key frequencies. " Since luminescent diodes are defined as ¹ clockable, 'the; Range from which these frequencies can be selected, arbitrarily and ". The. ¹ ^ possibility of finding the selected key frequencies at random is to be excluded in practice. therefore very big. '

It is advantageous to 'clock the light emitted by rdeF luminescence diode only' with two 'frequencies / ₀ and J ₁ , where J ₁ <ξ J ₀ Bandwidth includes at least the frequencies J ₀ + / 1 and J ₀ _ J ₁ , the output of this broadband selective amplifier being followed by a demodulator whose output is via a narrowband selective amplifier for the frequency J _{1 to} a first input and directly or via a Smoothing element is fed to a second input of a gate. The narrow-band amplifier for the frequency J ₁ can be a resonance relay. When the signals in the two inputs of the gate coincide with a signal in a first output, the gate unlocks the lock and in the event of an anti-coincidence with a signal in a second output, an alarm signal is triggered. The restriction to two key frequencies gives a simple and thus economical embodiment of the light barrier according to the invention. A transmitter for the luminescent diode which can be felt at a further frequency J ₁ and which oscillates at the frequency J ₀ can be constructed with simple means. The electronic components to be provided on the receiving side for determining the coincidence or anticoincidence can also be implemented with simple means, so that a very high level of monitoring security is guaranteed with an extremely low economic outlay.

For an even simpler design, the light emitted by the luminescent diode can be clocked with only one frequency J _0, dispensing with the highest safety requirements, whereby the photodiode can then be arranged in the input circuit of a broadband selective amplifier, the bandwidth of which is at least the frequencies Js and J ₀ includes, where \ fs \> \ fs - fo \ applies and the output of this broadband selective amplifier via a narrowband selective amplifier for the frequency J _{0 to} a first input and directly or via a further broadband selective amplifier, whose bandwidth at least the frequencies / 5 and J ₀ includes, can be fed to the second input of a gate. In this embodiment; the coincidence or anticoincidence of the frequency / _{0 is} checked in the gate as a signal in both inputs of the gate and, depending on the result, the lock is unlocked or an alarm signal is triggered. Since broadband selective amplifiers are used, the arrangement can easily be converted for a large number of key frequencies J ₀ without any particular additional effort. The economic outlay in the sending and receiving parts is correspondingly low. However, the monitoring security decreases, since the probability of finding the only key frequency J _{0 is} relatively high. For monitoring objects with a correspondingly low value, e.g. B. for garage doors, this simple and cheap device is

tion, however, excellently suited. It is advantageous to choose the clock frequency / ₀ at least approximately 400 kHz. At a frequency of this order of magnitude, there is a favorable ratio between the useful signal and the noise signal of the semiconductor photodiode, which creates favorable transmission ratios. In addition, this frequency range corresponds to the intermediate frequency customary in radio technology. Commercially available electronic components can therefore be used, with which inexpensive production is achieved. The clock frequency f _x to less than ¹ J _1/0 be. A sufficiently large selection can be achieved within this frequency range by means of selective amplifiers and there are also sufficient possibilities for variation for the key frequency f _x .

In the following the invention with two exemplary embodiments, which are shown in FIGS. 1 and 2 shown are described in more detail. Both embodiments differ in the electronic components, with which the coincidence or the anti-coincidence is checked. There are identical parts in both figures provided with the same reference numerals.

F i g. 1 shows a transmitter 1 from which a light emitting diode 2 is fed. The light emitting diode 2 can be a GaAs light emitting diode. The transmitter 1 oscillates at a frequency of approximately 400 kHz and can be clocked at a second frequency f _x. It should be emphasized that the choice of the key frequency Z _{1 is} completely arbitrary and independent of the structure of the transmitter. The light emitted by the luminescent diode 2 is combined with an optics 3 to form a parallel beam and with an optics 4 on a semiconductor photodiode which, for. B. may be a Si photodiode, shown. The semiconductor photodiode 5 is located in the input circuit of a broadband] selective amplifier 6. The bandwidth of the selective amplifier 6 comprises at least the frequencies / ₀ + f _x and / ₀ - f _x . At the output 7 of the selective amplifier 6 is a demodulator 8. The output 9 of the demodulator 8 is via a narrow-band selective amplifier 10 for the frequency f _x , the z. B. can be a resonance relay, fed to the first input 12 of an AND gate. The output 9 of the demodulator 8 is fed to the second input 13 of the gate via a smoothing element 11. The AND gate 14 has two outputs 15 and 16, and in it the coincidence or the anticoincidence of the frequencies in the two inputs 12 and 13 is examined. The assignment between the inputs 12 and 13 and the outputs 15 and 16 of the gate 14 and thus the unlocking of the lock or the triggering of the alarm signal can be seen in Table 1 below.

Table 1

Entrance 12

Entrance 13

Exit 15
(Anti-reflective coating)

Exit 16 (Alaim)

not applicable, since with / ₀ + f _x

always the input 13

appeals to

There is also the possibility of using the light barrier according to the invention only to monitor one To apply closure. Only output 16 and the assignment are then to be provided at gate 14 Table 2 shows between inputs 12 and 13 and output 16.

Table 2

Entrance 12 Entrance 13 Exit 16
(Alarm) χ + 1 + 1 not applicable

In the execution according to FIG. 2, the light emitted by the light emitting diode is only _{clocked with a frequency / 0} at which the transmitter 1 oscillates. In addition, this version differs from that according to FIG. 1 in the electronic components that are connected downstream of the photodiode 5. The photodiode 5 is located in the input circuit of a broadband selective amplifier 17, the bandwidth of which comprises at least the frequencies fs and / ", where \ fs \> \ fs— / ₀ | is applicable. The output 7 of the selective amplifier 17 is via a narrowband selective amplifier 19 for the frequency / _{0 to} the first input 12 of the gate 14 and via a further broadband selective amplifier 18, the bandwidth of which again includes at least the frequencies fs and / ₀ , to the second input 13 of the Gate 14 supplied. In gate 14, the coincidence or anticoincidence of the key frequency / _{0 is} checked in both inputs 12 and 13 and the lock is unlocked or an alarm signal is triggered via outputs 15 or 16. The assignment of the inputs 12 and 13 and the outputs 15 and 16 of the gate 14 is analogous to Tables 1 and 2. Accordingly, the output 16 will respond at every irradiated frequency that is between the frequencies fs and / ₀ for which the bandwidth of the Selective amplifier is designed. It has already been mentioned that this embodiment, compared to the one shown in FIG. 1 offers less surveillance security. However, because of the significantly lower electronic complexity, cheaper production and thus use on objects for which complex protection would not be justified is possible.

It should also be emphasized that the key frequency / ₀ or / ₀ and Z ₁ can be changed by changing or replacing the narrowband selective amplifiers 10 and 19. Such a change can therefore be carried out without changing the overall structure of the arrangement. A large number of safety devices can therefore be produced, and accidental opening of a lock by means of a "key" for another light barrier arrangement is practically impossible. The invention can also be implemented with more than two key frequencies according to the stated execution principles. To check the coincidence or the anticoincidence, only the electronic components need to be expanded accordingly.

1 sheet of drawings

Claims (9)

Patent claims: 1. Light-controlled arrangement for unlocking and monitoring a lock, in which the light emitted by a light source is clocked with at least one frequency and a light receiver is arranged, the means are connected downstream with which the coincidence the clock frequencies in the received signal can be determined and at the coincidence of the Lock is unlocked, characterized that a luminescent diode (2) is provided as the light source, that with the light receiver (5) downstream center (14) also the anticoincidence of the clock frequency in the received Signal can be determined and an anti-coincidence alarm is triggered and that the light receiver (5) in the input circuit of a broadband Selective amplifier (6, 17) is arranged, to which a narrow-band selective amplifier (10, 19) is downstream, the output of which is the means (1.4) for determining the concidence or anticoincidence is fed. 2. Arrangement according to claim 1, characterized in that the light emitted by the luminescent diode (2) is clocked _{with two frequencies / 0} are J ₁ , where J ₁ <ξ / "holds that the bandwidth of the broadband selective amplifier (6) at least the frequencies f, _s + J ₁ and / ₀ - J ₁ , that the broadband selective amplifier is followed by a demodulator (8) whose output (9) via the narrowband selective amplifier (50) for the frequency f- _{L has} a first input ( 12) are fed directly to a second input (13) of a gate (14). 3. Arrangement according to claim 1, characterized in that the light emitted by the luminescent diode (2) _{is clocked with two frequencies / 0} - and j \ , where /, <ξ / "good that the bandwidth of the broadband selective amplifier (6) comprises at least the frequencies / "+ J ₁ and /" - J ₁ , and that the broadband selective amplifier (6) is followed by a demodulator (8) whose output (9) via the narrowband selective amplifier (10) for the frequency J _x one first input (12) and via a smoothing element (11.) to a second input (13) of a gate (14). 4. Arrangement according to claim 2 or 3, characterized in that the narrow-band selective amplifier (10) for the frequency J _{1 is} a resonance relay. 5. Arrangement according to claim 1, characterized in that the light emitted by the light emitting diode (2) _{is clocked with only one frequency / 0} , that the bandwidth of the selective amplifier (17) comprises at least the frequencies fs and / ₀ , where | / s |> | / s - f _n \ applies and that the output (7) of the broadband selective amplifier (17) via the narrowband selective amplifier (19) for the frequency / _{0 to} a first input (12) and directly to a second input (13) Gate (14) is supplied. 6. Arrangement according to claim 1, characterized in that the light emitted by the luminescent diode (2) _{is clocked with only one frequency / 0} , that the bandwidth of the broadband selective amplifier (17) at least the frequencies. fs and / ₀ , where \ f _s \ > \ f _s - / ₀ | and that the output (7) of the broadband selective amplifier (17) via the narrowband selective amplifier (19) for the frequency / "a first input (12) and via a further broadband selective amplifier (18) whose bandwidth is at least the frequencies fs and / ₀ comprises, is fed to a second input (13) of a gate (14). 7. Arrangement according to one of claims 3 to 6, characterized in that the gate at Coincidence of the signals in the two inputs (12 and 13) of the gate (14) with a signal in a first output (15) of the gate, the lock is unlocked and that in case of anticoincidence an alarm signal is triggered with a signal in a second output (16). 8. Light barrier according to one of claims 1 to 7, characterized in that the clock frequency / _{0 is} at least approximately 400 kHz. 9. Arrangement according to one of claims 2 to 4, characterized in that the clock frequency j \ is less than ¹ Z ₄ / ".