JP2681294B2 - Lamp disconnection detection device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a device for detecting a broken core when any one of a large number of lamps connected in series is broken, and particularly to a runway in an airfield or the like. The present invention relates to a lamp disconnection detection device used for a guide light.

BACKGROUND ART In a device such as an induction light in which a large number of lamps are connected along a long path, it is necessary to know when the lamps are disconnected and malfunction, but an induction light in which each lamp is simply connected in series. In such a case, if one of the lamps is disconnected, the current does not flow in the entire circuit, and it can be understood that disconnection occurs in the lamp circuit by detecting this, but this will cause one lamp to disconnect. It is inconvenient because all other lamps will be extinguished if centered.

As a modification of this point, a switch for short-circuiting the terminals of the lamp is provided as shown in FIG. 6, and if the lamp is disconnected, the terminals are short-circuited so that other lamps are not affected. Those that have been done are already known.

However, even with this conventional lamp circuit, when one of the lamps is disconnected, it is not immediately known from a distance, and there is a problem that the disconnection of the lamp cannot be centrally monitored at one place. It was

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and provides a lamp burnout detection apparatus capable of performing remote and immediate and reliable centralized monitoring of which lamp burned out. It is intended.

DISCLOSURE OF THE INVENTION The above object is to provide a transformer for extracting inductive power based on a lamp lighting current, an AC signal generator driven by an output voltage of the transformer, and an output signal of the AC signal generator for a lamp lighting current transmission line. And a detection circuit connected to the lamp lighting current transmission line and configured to include a filter for detecting the output signal superimposed on the lamp lighting current transmission line. Achieved by

As a means for detecting the lamp current, a core is arranged on the lamp lighting wire, the lamp lighting wire is wound around the core as a first winding, and electric power (inductive power) transmitted through the first winding and the core. Is detected (extracted) by the second winding as a transformer, and the signal generator uses the output voltage of the second winding as a power source and generates different frequency signals corresponding to each lamp connected in series. This oscillator is superimposed on the lamp lighting line via the third winding and is transmitted (returned) as an output signal.

By doing this, all return signals of the frequency corresponding to each lamp flow to the circuit under normal conditions, and when the lamp is disconnected, it is detected that there is no return signal corresponding to this lamp and the lamp disconnection occurs. The wick can be detected. Further, it is possible to easily detect the disconnection of the lamp by detecting such a signal by sending back such a signal only when the core is disconnected.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a circuit diagram showing an embodiment of a lamp burnout detecting device of the present invention, FIG. 2 is a circuit diagram in which a number of lamps are connected in series, and FIG. FIG. 4 is a diagram showing a case where terminals are short-circuited and welded due to core breakage of the filament. FIG. 4 is a circuit diagram showing another embodiment of the lamp core breakage detection device. FIG. 5 is a modified circuit diagram of FIG. FIG. 6 is a diagram showing a conventional lamp circuit.

BEST MODE FOR CARRYING OUT THE INVENTION FIG. 1 and FIG. 2 are views showing an embodiment of a lamp burnout detecting device according to the present invention. As shown in FIG. A large number of lamps (L1 to Ln) are connected in series along and are lit by a power source (E). A commercial frequency is used for the power source (E). The lamp current transmission line is provided with a detection circuit including a plurality of filters at a central control point.

Fig. 1 shows one of the lamps in Fig. 2 (Lamp: L
1) shows a detailed configuration of the filament (1
A short circuit (11) is formed in parallel to short-circuit both terminals of the filament (10) so that the operation of the other lamps (L2 to Ln) will not be affected even when the (0) is disconnected. ing.
This short circuit (11) itself is a known circuit in the prior art, has a short circuit switch (SW1), and has a filament (10).
When the core is disconnected, the short-circuit switch (SW1) operates, and the short-circuit (11) is closed to bypass the current.

There is a lighting line (P1) between the connection point (A) of the short circuit (11) connection points (A) and (B) and one terminal of the filament (10) (lighting line: P1). Wound core (1
2) has been inserted. This core (12) has a lighting line (P1)
A first winding (N1), a second winding (N2) for extracting electric power from the first winding (N1) through the core (12), and a predetermined frequency (f1) for the lamp (L1). ) Has a third winding (N3) for superimposing and transmitting the signal (S1) via the first winding (N1) for associating the signal of (3).

The second winding (N2) has a function as a means for detecting the lamp current flowing in the lighting line (P1) for lighting the lamp (L1). That is, a signal generator (13) driven by the output power is connected to the output terminal (power supply) of the second winding (N2) as a transformer (detection means) that extracts induced power based on the lamp lighting current. Has been done. This signal generator (13) uses the output voltage of the second winding (N2) as a power source (f1)
It is composed of an oscillator that generates a frequency signal.

The output side of the signal generator (13) has a third winding (N3), and the third winding (N3) is wound around the core (12), The output signal of is superimposed on the lamp lighting line (P1) via the core (12) and transmitted (returned). Therefore, the lamp (L1) is always (when lit)
It lights up with a signal of frequency (f1).
Note that (Lp) is an inductor that is inserted to block the return signal from the third winding (N3) from being input to the signal generator (13) and to pass only the frequency component of the lighting current. .

Other lamps (L2
To Ln), the lamp (L2) has the frequency (f2), the lamp (L3) has the frequency (f3), and the lamp (Ln) has the frequency (fn) as shown in FIG. Is added (correspondingly output), and the frequency signals from (f1) to (fn) flow in the circuit in a superimposed state.

On the other hand, as shown in FIG. 2, by providing a filter (F1 to Fn) in the lamp lighting circuit, the lamp (L1 to Ln)
The return frequency (f1 to fn) which is the return signal corresponding to (n) can be individually extracted, and centralized monitoring can be performed on the central side.
That is, for example, if the filament (10) of the lamp (L1) is broken, current will flow through the short circuit (11) due to the closing operation of the short circuit switch (SW1), but this will not affect other lamps, etc. , No current flows to the lamp (L1) side, so the signal (f1) is not output from the signal generator (13), so there is no frequency component of (f1) in the lamp circuit and the filter (F1) Therefore, it is possible to know that the lamp (L1) has failed because it cannot detect this. The same applies to disconnection of other lamps.

Although not shown, the core disconnection of the lamp can be similarly detected when the core (12) is inserted on the core short-circuit line (P2) side. In this configuration, induced power is obtained from the second winding (N2) via the core based on the current flowing through the short-circuit line (P2) only when the lamp is burned out, and this output power drives the signal generator to output the output signal. Superimpose on the lamp lighting line (P1) via the core to transmit (return). In other words, if the lamp is not broken, the return signal does not flow to the lamp lighting circuit, and the return signal of the frequency corresponding to the lamp flows only when the lamp is broken.
You can tell which lamp has failed by receiving it at ~ Fn).

FIGS. 3 and 4 explain another embodiment, and FIG. 3 shows a case where the filament (10) of the lamp is broken.
In particular, it shows the case where the end of the broken filament (10) is welded to the other terminal side of the filament and the filament (10) is short-circuited. In this case, the current flowing through the lighting line (P1) continues even if the core is disconnected. Therefore, in the above-mentioned configuration, core disconnection / welding cannot be detected. In order to cope with such a case and to detect the core disconnection more surely, in this embodiment, a photodiode (PHD) is arranged near the lamp, and the circuit configuration as shown in FIG. do it. For example, if the filament (10) is broken by welding, the lamp (L1) will not light up, but the current will continue to flow through the lighting line (P1), and the signal generator (13) will return a signal of the frequency (f1). It will continue to be output. However, as a result of disconnection and extinction, the photodiode (PHD) does not flow current, so no output appears at the output terminal of the subsequent AND circuit (14), and the return signal of (f1) is returned by the filter (F1). It can be seen that the lamp (L1) is disconnected even when it is welded because it cannot receive.

When the core (12) is inserted on the short-circuit line (P2) side, the output from the photodiode (PHD) becomes a negative input (inversion) as shown in FIG. The gate section may be a negative input AND circuit.

INDUSTRIAL APPLICABILITY As described above, according to the present invention, since the core disconnection detection device is provided for each lamp of a large number of lamps connected in series, which lamp is core disconnected can be centrally controlled from a remote location. It is suitable for use as a guide light for a runway in an airfield, for example, and can further ensure safety when taking off and landing an airplane.

Claims (3)

(57) [Claims] 1. A transformer for extracting induced power based on a lamp lighting current, an AC signal generator driven by an output voltage of the transformer, and an output signal of the AC signal generator for induction on a lamp lighting current transmission line. Superimposing means for superimposing as an electric current,
A lamp disconnection detection apparatus comprising a detection circuit connected to the lamp lighting current transmission line and configured to include a filter for detecting a superimposed output signal. 2. A lamp lighting line (P1) is wound as a first winding (N1) arranged corresponding to each of the lamps (L1 to Ln) connected in series along a lamp current transmission line. Core (1
2) and the second winding (N) provided to each core (12) to extract electric power according to the current flowing through the lamp lighting line (P1).
2) and the output voltage of each second winding (N2) is used as a power source to correspond to each lamp (L1 to Ln) and different frequencies (f1
To fn) and a third winding provided on each core (12) for superimposing and transmitting an output signal of a predetermined frequency from the oscillator (13) on the lamp lighting line (P1). (N3)
, And the lamp (L1 ~
Ln) a switch (SW1) that short-circuits the lamp terminals when the corresponding one is broken, and a plurality of switches for individually detecting the superimposed output signals connected to the lamp lighting current transmission line. A lamp disconnection detection device comprising a detection circuit including a filter. 3. A lamp lighting line (P1) is wound as a first winding (N1) arranged corresponding to each of the lamps (L1 to Ln) connected in series along a lamp current transmission line. Core (1
2), the second winding (N2) applied to each core (12) to extract the power of the lamp lighting line (P1), and the output voltage of each second winding (N2) as a power source. An oscillator (13) that oscillates different frequencies (f1 to fn) associated with each lamp (L1 to Ln) and an output signal of a predetermined frequency from the oscillator (13) is superimposed on the lamp lighting line (P1).・ Third winding (N3) applied to each core (12) for transmission and each lamp (L1 ~
Ln) and a photodiode (PHD) arranged near the
The output of the photodiode (PHD) and the oscillator (1
An AND circuit (14) that outputs an output signal of a predetermined frequency according to the AND condition with the output signal of 3), and a plurality of filters that are connected to the lamp lighting current transmission line and individually detect the superimposed output signals. A disconnection detection device for a lamp having a detection circuit configured to include.