DE19650695C1 - Power supply for electrical door - Google Patents

Abstract

The device has a transformer (1) with AC (3) and DC (2) voltage branches on the secondary side connected in common to a transformer secondary winding (4). The DC voltage branch contains a low pass filter (6) and a bridging circuit (7) for bridging the filter when a load (8,9) is switched on in the AC voltage branch. The low pass filter is an RC filter containing a resistor (10) and a capacitor (11). The bridging circuit contains a switchable triac (12) connected in parallel with the resistance and switchable depending on the load.

Description

The invention relates to a power supply for an electrical door system, with a trans formator, with a DC voltage branch provided on the secondary side and with egg nem provided alternating voltage branch, the direct voltage voltage branch and the AC voltage branch together to a secondary winding tion of the transformer are connected (DE-OS 14 87 833).

Electric door systems, mostly a door opener and a door intercom direction include, have been known for a long time (see. DE-OS 14 87 833 ). They are usually not supplied with the AC voltage of 220 V. operated, but powered by a power supply unit, the output side both a DC voltage of relatively small size as well as an AC voltage relatively low large size. Direct voltages and alternating voltages are common in the Range up to approx. 24 V. The same is used in the known electrical door systems voltage as carrier voltage for speech communication, while the AC voltage supply for the electrical consumers, such as bell buttons, door openers and sound signal generator is used.

There are different solutions for a power supply unit for use in electrical doors plants known in the art. The known power supplies for electrical Door systems differ essentially in their structure by the way they are used Use of transformers with one or two secondary coils formation of a common or two separate neutral conductors, by using egg one-way or bridge rectifier and by supplying the electrical Consumers, such as the bell buttons, the door opener or the sound signal generator, by direct or alternating voltage. The are in the design of a Power supply for an electrical door system always existing significant problems similar. First of all, such a power supply unit should of course be constructed simply and be inexpensive to manufacture. In addition, he should also use this power supply allow the electric door system to be wired with as few wires as possible drive because additional wires always increase the installation effort. Is further basically to avoid that the electrical consumers with DC voltage be supplied, because this DC voltage to the he about the bell buttons increased wear due to corrosion and with the door openers and sound signal transmitters  leads to higher requirements in the technical execution, for example by necessity Interference suppression equipment and burn-off breaker contacts.

These are the requirements for a power supply unit for an electrical door system solved from the prior art power supply in that the Transforma gate only one secondary winding and a common neutral on the output side for the DC voltage and for the AC voltage (cf. the DE 43 40 497 C2). In such a power supply, the transformer is because it only has a secondary winding, particularly inexpensive. Also requires one Power supply unit for an electrical door system only occupies three wires. Simultaneously However, it is ensured that the electrical consumers advantageously with AC voltage are supplied. In addition, the known power supply is also available as little effort.

However, the use of this known power supply brings a very considerable amount Problem with itself. Through the rectifier necessary for the DC voltage branch ter and a voltage regulator, which is usually also provided, the Se secondary development a non-linear load, that is, the load varies, for Example due to the non-negligible forward voltage one as equal rectifier provided diode, depending on the on the secondary winding of the trans formators present voltage. Such a nonlinear load means that the otherwise, sinusoidal AC voltage present on the secondary side is clear Some sharp-edged distortions. Such distortions result in the fou spectrum of the alternating voltage applied on the secondary side to considerable fre frequency components for high-frequency harmonics of the fundamental frequency. This high Frequent harmonics now provide in connection with the fact that the ver wiring of electrical door systems related lines or the individual Wires of the lines are generally not shielded - the use of shielded cables are used for cost reasons and for reasons of storage usually rejected -, for a sometimes considerable impairment of the Speech connection. The parasitic capacitances between the individual Veins small, so that the presence of an undisturbed 50 Hz AC voltage on the Speech connection has no influence, but the high frequencies of the due to the distortion harmonics to one for these frequencies increased coupling, since it is known that the capacitive reactance with the reciprocal of the  Frequency decreases. The result is that in the speech connection DC branch significant portions of the distortion due to the sinusoidal shape of the AC voltage on the secondary side of the transformer in Fre frequency spectrum of this alternating voltage generated harmonics again and interference Depending on the installation, the speech connection may become incomprehensible.

The invention is therefore based on the object, the known power supply for To design and develop electrical door system such that even with Ver using simple cables with unshielded cores is a problem Speech connection is guaranteed.

The object derived and shown above is achieved according to the invention in that that in the AC branch of the power supply a low-pass filter and an over bridging circuit for bridging the low-pass filter when switching on a load in the AC branch are provided. By the measure according to the invention is advantageously ensured that in the unloaded AC branch of harmonics essentially free sine voltage with the mains frequency of at for example, 50 Hz is present, which hardly influences the speech connection. He According to the invention, it has also been recognized that it is intended to be removed by the Vorse hen the low-pass filter resulting current limitation is necessary, an over bridging the low-pass filter when switching on a load in the AC voltage to provide branch. Through this measure, the speech connection with the Switching on a load affects, but this only happens for a short time and it is also during the operation of the door opener or the tone signal bers usually no speech connection, so that the existing in this period Impairment is not noticed. So overall, using a simple Measure of the unrestricted use of a very simple power supply guaranteed for a door system with high quality of the speech connection.

The teaching according to the invention experiences a first advantageous embodiment in that that the bypass circuit is in parallel with the resistance of the as an RC low pass filter trained low-pass filter switched load-dependent switchable triac points. The use of a triac is advantageous in the present case, since this, once ge  ignites, fluctuations in the control current tolerated and only when falling below one certain holding current is deleted.

If the bypass circuit has one in the phase conductor of the AC voltage two arranged bidirectional diode cascade and is the phase conductor with its the transformer, viewed from the bidirectional diode cascade, abge connected side to the ignition electrode of the triac via a control line, this ensures that when a load is applied in the AC branch A sufficient ignition voltage to ignite the triac via the diode cascade falls off.

Advantageously, the bypass circuit in the control line of the Triacs a limiting resistor, which limits the gate current of the triac guaranteed.

As parasitic loads occur regularly in electrical door systems, this is the case The present invention is particularly advantageous in that parallel to the bidi tional diode cascade a threshold resistor is connected. That swell the stand prevents the triac from igniting due to parasitic loads. Otherwise therefore the AC voltage filtered by the low-pass filter is not subsequently connected distorted again via the diode cascade.

Have the DC branch and the AC branch in common seed neutral conductor, it is ensured that the electrical door system with a total only three wires can be operated. However, the teaching according to the invention is not based on such an execution is limited. They are also versions with a separate zero conductors of the direct and alternating voltage branch conceivable.

Finally, the power supply according to the invention is further simplified by that to derive the DC voltage from the on the secondary winding lying AC voltage a one-way rectifier is provided. Such a One-way rectifier has a simple structure and is in any case connected with a voltage regulator is easily able to use one for a speech to provide sufficiently smoothed DC voltage.  

In particular, there are a variety of ways that the invention To design and develop a power supply unit for an electrical door system. To on the one hand, reference is made to the subordinate Pa claims, on the other hand to the description in connection with the drawing. In the drawing, the only figure shows the circuit structure of an embodiment example of a power supply according to the invention for an electrical door system.

In the single figure of the drawing, an embodiment of a power supply unit according to the invention for an electrical door system is shown, which has a transformer 1 , a DC branch 2 provided on the secondary side and an AC branch 3 provided on the secondary side. The DC voltage branch 2 and the AC voltage branch 3 are jointly connected to a secondary winding 4 of the transformer 1 . As is known, the primary winding 5 is connected to an AC voltage source, not shown.

According to the invention, a low-pass filter 6 and a bridging circuit 7 are provided in the AC voltage branch 3 for bridging the low-pass filter 6 when a load is switched on in the AC voltage branch 3 . As an example of such a load, a signal generator 8 and a door opener 9 are shown in the single figure. In the exemplary embodiment shown, the low-pass filter 6 consists of a resistor 10 and a capacitor 11 . To bypass the low-pass filter 6 , the bypass circuit 7 has a triac 12 connected in parallel with the resistor 10 and switchable as a function of the load.

The bypass circuit 7 of the embodiment of a power supply unit according to the invention shown in the single figure has a bidirectional diode cascade 14 arranged in the phase conductor 13 of the AC voltage branch 3 . To control the triac 12 , the phase conductor 13 is connected by its side facing away from the transformer 1 relative to the bidirectional diode cascade 14 via a control line 15 to the ignition electrode of the triac 12 . A limiting resistor 16 for limiting the gate current of the triac 12 is also arranged in the control line 15 .

The bridging circuit 7 has, in addition to the components already described, a threshold resistor 17 connected in parallel with the bidirectional diode cascade 14 . This threshold resistor 17 ensures that an existing in the AC voltage branch 3 parasitic load, for example a moisture-related leakage current in bell buttons, does not lead to a control of the diode cascade 14 .

The illustrated embodiment of a power supply unit according to the invention has a common neutral conductor 18 for the DC voltage branch 2 and the AC voltage branch 3 . Compared to separate neutral conductors, this saves one wire in the line to be installed for the installation of a door system.

To derive the DC voltage from the secondary voltage of the transformer 1 , a one-way rectifier, namely a diode 19 , is provided in the exemplary embodiment shown for a power supply unit. The DC voltage is then smoothed using a capacitor 20 and regulated to a constant value using a voltage regulator 21 .

The following is the function of the embodiment shown in the single figure example of a power supply unit according to the invention once again in summary tert.

If the DC voltage branch 2 , in particular by an existing speech connection, is loaded, there is a distorted, outlined in the single figure, voltage at the connection point between the secondary winding 4 and the phase conductor 13 . In the event that the AC branch 3 is not loaded, the triac 12 is not conductive, so that Oberwel len contained in the distorted AC voltage are derived by the low-pass filter 6 and via the resistor 17 on a load 8 , 9 facing the end of the phase conductor 13 a sinusoidal AC voltage is present, as is again indicated in the single figure. This AC voltage now does not couple into the wires of the DC voltage branch 2 even on long wires of a line that are laid over long distances.

However, if the AC voltage branch 3 is charged, for example, by the actuated signal tone generator 8 , the voltage drop across the threshold resistor 16 rises above the value of the total forward voltages of the diodes of the bidirectional diode cascade 14 , so that these are switched through, thus bridging the threshold resistor 17 and provide sufficient ignition voltage to ignite the triac 12 at its connection facing away from the transformer 1 . The connected triac 12 now bridges the resistance 10 of the Tiefpaßfil age 6 , so that load-independent from the secondary winding 4 via the phase conductor 13 to the load 8 , 9 only the sum of the forward voltages of the triac 12 and the diodes of the bidirectional diode cascade 14 drops. Correspondingly, the transformation ratio of the transformer 1 is to be designed such that a slightly higher voltage than the voltage required by the consumers 8 , 9 is present at its output. Finally, if the AC voltage branch 3 is no longer loaded, the triac 12 becomes non-conductive. At the moment of deletion of the triac 12 , the Tiefpaßfil ter 6 resumes its work and ensures that in the ge of the transformer 1 behind the bidirectional diode cascade 14 part of the phase conductor 13 there is a sinusoidal AC voltage free from harmonics.

Claims (7)

1.Power supply unit for an electrical door system with a transformer ( 1 ), with a DC voltage branch ( 2 ) provided on the customer side and with an AC voltage branch ( 3 ) provided on the secondary side, the DC voltage branch ( 2 ) and the AC voltage branch ( 3 ) being connected together to a secondary winding ( 4 ) of the transformer ( 1 ) are connected, characterized in that in the AC voltage branch ( 3 ) a low-pass filter ( 6 ) and a bypass circuit ( 7 ) for bridging the low-pass filter ( 6 ) when a load ( 8 , 9 ) is switched on AC voltage branch ( 3 ) are provided. 2. Power supply according to claim 1, wherein the low-pass filter ( 6 ) is designed as an RC low-pass filter with egg nem resistor ( 10 ) and a capacitor ( 11 ), characterized in that the bridging circuit ( 7 ) has a parallel to the resistor ( 10 ) of the low-pass filter ( 6 ) switched, load-dependent switchable triac ( 12 ). 3. Power supply unit according to claim 2, characterized in that the bridging circuit ( 7 ) has a bidirectional diode cascade ( 14 ) in the phase conductor ( 13 ) of the AC voltage branch ( 3 ) and the phase conductor ( 13 ) with its the transformer ( 1 ), viewed from the bidirectional diode cascade ( 14 ), the side facing away is connected via a control line ( 15 ) to the ignition electrode of the triac ( 12 ). 4. Power supply according to claim 3, characterized in that the bridging circuit ( 7 ) in the control line ( 15 ) of the triac ( 12 ) has a limiting resistor ( 16 ). 5. Power supply according to claim 3 or 4, characterized in that a threshold resistor ( 17 ) is connected in parallel to the bidirectional diode cascade ( 14 ). 6. Power supply according to one of claims 1 to 5, characterized in that the direct voltage branch ( 2 ) and the alternating voltage branch ( 3 ) have a common neutral conductor ( 18 ). 7. Power supply according to one of claims 1 to 6, characterized in that a one-way rectifier is provided for deriving the DC voltage from the secondary winding ( 4 ) of the transformer ( 1 ) AC voltage.