FR2558657A1 - Ignition generator for gas- or oil-fired burner in heater - Google Patents

Abstract

The generator has a capacitor (4) in series with a resistor (2) in parallel with the terminals (1) of an ac source. A triac (5) is connected in series with the primary winding of the transformer across the capacitor. The control electrode (of the triac) is coupled via a diac (11) and a second resistor (10) to the junction between the first resistor (2) and capacitor (4). The primary (6) of the transformer is wound on an iron-powder core (7) and insulated from the hv secondary winding (8) embedded in the same encapsulant. A second capacitor (12) shunts the series combination of resistor (2) and first capacitor.

Description

 The invention relates to an arrangement for the continuous production of a series of ignition sparks, which is particularly suitable for achieving the safe ignition of devices operating with a gas and Pu oil and producing heat, and for which the voltage of the network can be selected within wide limits - without switching - and which can be formed by the assembly of terminating elements customary in the trade, with a low expense from the work point of view.

 Compared to the influences of the ambient climate, the assembly according to the invention is as resistant as the known technical solutions, but its overload capacity in operation is significantly greater than that of the generally known types (such as for example types of assemblies offered by the companies known as Honeywell, Statronic, Danfoss), and even a short circuit in the secondary circuit does not lead to any serious damage, the action leading to an overcurrent - in the case of abnormal operation - more low than in the usual case and such a device can be used correspondingly for an application adapted according to the purpose of use (ignition of hydrocarbons).

 To carry out the ignition of heating devices operating with hydrocarbons, a series of technical solutions are known, among which the dielectric piezoelectric ignition devices (for example Junkers) based on the principle of induction are actuated by generally by manual force and are used in small installations.

 The continuously operating spark ignition devices used in large devices are generally devices supplied by the mains voltage, such as, for example, the 052L0003B plate core transformer from the company known as Danfoss.

These spark ignition devices are equipped with a high-voltage secondary coil (10-20 kV) of special realization, from which the voltage is taken to be applied to the ignition electrodes arranged in the combustion chamber . These continuously producing sparking systems generally operate as long as the automatic system, which guarantees the operating conditions and which controls the entire heating system, allows it. A disadvantage is that in the event of the appearance of an automatic system failure, there are first of all, in the construction elements, harmful effects at the level of the spark ignition device with continuous operation. spark ignition devices with continuous operation are generally provided with an ignition transformer of particular constitution comprising a secondary coil having a high insulation resistance and a core of fr made of soft iron, and in these devices the technology manufacturing process, which meets special requirements, greatly increases manufacturing costs.

 The primary circuit of the transformer, supplied by the network current, is dimensioned, in order to guarantee the high power as well as taking into account the need in place serving to ensure the required conditions of insulation - for admissible volumes - in such a way that the operating time of the transformer is equal to a maximum of 2-3 minutes per hour in the case of a connection time of 30%. The determined connection time allows the transformer to operate without damage - only in discontinuous operation at intervals, relative to the time unit, when for example a break of 7-8 minutes must follow each operation of a duration 2-3 minutes.

In the case of normal operating conditions, this operating rate is quite sufficient, but in the case of a longer connection time and following erroneous commands or else in the case of an operating time of 10 -15 minutes, destruction occurs in the excessively heated transformer, which can no longer be remedied and which can lead to frequent operating failure, which ultimately makes the transformer unusable and faulty In order to avoid these problems, transformers are often used whose primary circuit is supplied by a current having a higher frequency deviating from that of the mains current or having a low voltage ( for example transformers
ZT801 from Satronic, S720A from Honeywell), in which case it is necessary to use, for their power supply unit, in order to guarantee the high power, semiconductor elements having a high dissipation and for which it cooling must be ensured under hot operating conditions.These systems, which work essentially on a switching operation with conversion to alternating current - direct current - alternating current, can, as a source of radio frequency disturbances, disturb the operation of the electronic flame control devices, located in their immediate vicinity (for example the transformer
ZT801 from the company known as Satronic and the electronic ionization flame control system from the company known as
Danfoss), which causes the flame control devices used to provide safety functions to become unreliable, precisely from this point of view.

 Due to the compromises relating to the volume and power insulation, it is also possible to apply to these transformers the criterion of discontinuous operation at intervals which corresponds approximately to what is described for the core plate transformers. The internal destruction, which is reproduced in the supply transformers in the network as a result of excessive heating or under the effect of the short circuit of the secondary circuit, causing the same phenomenon, can lead to the iron core carrying out a conduction. of metallic type, comes into galvanic contact with the high voltage electrodes which can be freely contacted, which increases the risk of accidents under the effect of an overvoltage.

 The high voltage also induced erpermanence in the secondary winding as a result of the permanent excitation provided by the network - in particular in low impedance embodiments - also increases the risk of accident.

 The object of the invention is to eliminate the drawbacks mentioned above and to develop an arrangement which eliminates the drawbacks of ignition transformers supplied by the network and producing sparks continuously, and simultaneously reducing the manufacturing costs of 'such an arrangement.

 The invention is based on the fact that the energy, which is stored according to the pulse operation with a repetition time determined by the frequency of the network, can be used for an approximately identical repetition time, but within the space of a duration of several orders of magnitude lower, to produce a power pulse which is approximately identical to the secondary power of the usual transformers and is sufficient for the ignition of hydrocarbons.

 To solve this problem, an assembly has been developed which is provided with a charging circuit, a discharge circuit and a transformer and in which the secondary winding is connected to the electrodes producing a discharge arc.

 This problem is solved in accordance with the invention in an arrangement of the type indicated above, characterized in that a capacitor, connected in series with a resistor, is connected in parallel across the terminals of the alternating voltage source and that d on the other hand in parallel with the capacitor is connected a first semiconductor switching element, connected in series with the primary winding having a small number of turns, of the transformer, and of which the control electrode is connected via '' a series circuit consisting of a second semiconductor switching element and a second resistor, at the common point of the resistor and the capacitor, the primary winding of the transformer being wound on an iron powder core and being galvanically separated and located away from the high-voltage secondary winding installed in an insulating mass.

 In the load circuit used in the circuit according to the invention, the energy is stored and used several times during a period and this is guaranteed by the semiconductor circuit used (which operates in synchronism with the network), which performs a calculated relaxation oscillation and consists of the second semiconductor switching element, the second resistor and a second capacitor. Energy is used at a standard spark gap, which is connected to the high-voltage secondary winding of a pulse transformer with an iron powder core and with The transformer is made with a primary winding having a reduced number of turns (2-50) and a secondary high-voltage winding - of the type also used in the television technique which are wound on a ferrite core ensuring a corresponding transmission of pulses and manufactured according to powder metallurgy processes.

 The impulse control of the transformer is surely carried out by a semiconductor switching element formed of four layers and having a low resistance of passage and which can be formed by a thyristor or by a triac, while the control of the latter is carried out surely at the rate of a relaxation oscillation, by a semiconductor diode or a diac, having a characteristic of which a part is negative.

 By choosing the duration of the relaxation oscillation, it is possible to influence the energy usable in the secondary circuit, namely the current of the ignition arc.

 The advantages of the assembly according to the invention compared with the known systems mentioned are very numerous.

 The impulse operation is obtained for a frequency of 50 Hz and therefore the disturbances at radio frequencies, which appear in transformers with alternating current - direct current - alternating current operating at high frequency, are suppressed (for example in the case type ZT801 from the company known as Satronic). In the case of assembly in accordance with the invention, it suffices to ensure that the noduced disturbances towards the network, due to the transient components supplied by the circuit of the semiconductor elements, are eliminated by filtering.

 It is for this purpose that a low-pass filter is used mounted in the branch for connection to the network and which is constituted by a choke coil by a capacitor.

 A secondary power of around 200 W is associated with an average power consumption of 11 W on the primary side, while in the case of the transformer mentioned by the company called Danfoss, this power consumption is 270 W.

 The assembly in accordance with the invention makes it possible to obtain continuous operation in the case of a connection duration of 100% in a volume of 1/4 dm3, without any harmful heating. In the case of a permanent short circuit in the secondary, the losses transformed in return and resulting from the high load have the effect that the system consumes minimum energy, that the primary current decreases and that, as a consequence of this process chain , the transformer is not damaged, but operates unchanged after the removal of the short circuit. None of the generally known transformers has such a characteristic. The correspondingly encapsulated device, sealed in a suitable polyester, therefore withstands the influences of the ambient climate, even in the case of a humid environment.

Other characteristics and advantages of the present invention will emerge from the description given below taken with reference to the appended drawings, in which
Figure 1 shows the block diagram of the assembly according to the invention
FIG. 2 represents an embodiment of the assembly according to the invention which uses the two half-waves of the alternating voltage
FIG. 3 represents an embodiment completed with a relaxation control device; and
FIG. 4 represents an embodiment which uses a single alternation of the alternating voltage.

In accordance with FIG. 1, a capacitor 4 connected in series with a resistor 2 is connected in parallel to the source of the alternating voltage, at its terminals 1, by means of a low-pass filter constituted by a coil stop 13 and by a capacitor
In parallel with the capacitor 4, there is mounted a series circuit formed by a first semiconductor switching element 5 and a primary winding 6 of the transformer, which is wound on an iron powder core 7 having a number of fairly low turns. The case point at resistor 2, capacitor 4 and the first semiconductor switching element 5 is connected to the control electrode of the first semiconductor switching element5 via 'a series arrangement comprising a second resistor 10 and a second semiconductor switching element 11. In addition a secondary winding 8 at high voltage of the transformer is wound on the iron powder core 7. According to Figures 2 and 3, the first semiconductor switching element 5 is constituted by a triac and the second semiconductor switching element 11 is constituted by a diac.

The assembly according to the invention operates in the following manner
the current supply of an alternating voltage network of 180-380 V, 50/60 Hz is carried out via terminals 1 (preferably network lines) when the voltage is applied to terminals 1 at an instant and for a period of time, which are determined manually or by an automatic system. The capacitor 4 is charged via the resistor 2 at the start of the alternation of the network voltage. During this alteration, after the second semiconductor coemutation element 11 has reached its conduction voltage, there occurs, under the effect of the current fixed by the second resistor 10, the first element of the semiconductor switching 5, which connects via its low dynamic resistance primary winding 6, having a low resistance, of the transformer, to the capacitor 4, which has the effect that the charge of the latter discharges into the primary winding 6. The discharged capacitor 4 is therefore no longer able to maintain the current of the first semiconductor switching element 5, and consequently the latter is blocked. The imeulsional discharge of the capacitor 4, which takes place in the primary winding 6, magnetizes the iron powder core 7 and consequently simultaneously causes the modification of the magnetization, which is characteristic for the operation of the transformer. The impulse modification of the induced flux, in the secondary high-voltage winding 8, a high-voltage pulse decreasing monotonously, the maximum of which is equal to 15 kV and the repetition duration of which is equal, for example, to 3 ms, as a function of the working and relaxation point setting of the second semiconductor switching element 11. The discharge time is on the order of magnitude of the microsecond. These periodically repeating high voltage pulses are sent to the initiating electrodes çage connected to terminals 9, and there occurs between them the discharge of an arc, which is suitable for igniting hydrocarbons. This process is repeated during each alternation. Appropriate dimensioning of the various elements guarantees that, even in the case of a permanent short circuit between the terminals9, no dangerous amplitude of current / voltage appears in any way and the power, which is taken from the network and which is limited in this case only to the replacement of the pressure drops, decreases. If one uses in addition to the second semiconductor switching element 11, a capacitor 12 appropriately dimensioned connected between the point of the rod- tion of the second resistor 10 and the second semiconductor switching element 11 and the common point of junction of the capacitor 4 and the primary winding 6 (FIG. 3), a relaxation oscillation can be obtained which guarantees, during alternation, a multiple repetition of the process described above, which makes it possible to obtain a desired increase in the current of the arc at the secondary.

In addition to the elements described, it is possible to provide a capacitor connected in parallel with the network and connected in series with a choke coil 13, and these additional elements guarantee the filtering of disturbances propagating towards the network and formed of transient components.

 In the embodiment of Figure 4, only alternation (negative) of the network voltage is used. As follows from the operating principle - a diode 3 connected in the passing direction is used in the charging circuit and a thyristor in place of the triac in the discharge circuit.

This assembly works as follows
The capacitor 4 is charged by the current determined by the resistor 2, by means of the diode 3 connected in the passing direction, during the negative alternation of the network voltage. After the mains voltage has been canceled, the charging circuit indicated above is disconnected from the network by the diode 3 during the positive half-wave and simultaneously, after the semiconductor switching element 11 has reached via the second resistor 10 its conducting voltage (voltage dQ3valanche), the semiconductor switching element 5 of the discharge circuit connected in parallel with the capacitor 4 is opened in an impulse fashion, which has the effect that this semiconductor switching element 5 connected to the primary winding 6, which is connected in series with it, uses the charging energy of the capacitor 4.

 In this exemplary embodiment, a relaxation oscillation of the resistor 10 and of the semiconductor switching element 11 can also be obtained in a known manner as a function of the impedance conditions between the connected circuits.

 Advantageously, the number of turns of the primary winding 6 of the transformer is between 2 and 50, while the secondary winding 8 of the transformer is formed by a high voltage coil of a television set.

Claims (8)

 1. Assembly for the continuous production of a series of ignition sparks, which is provided with a charging circuit, a discharging circuit and a transformer, the secondary winding of which is connected to the electrodes producing a discharge arc, characterized in that a capacitor (4), connected in series with a resistor (2), is connected in parallel to the terminals (1) of the alternating voltage source and that on the other hand in parallel with the capacitor (4) is connected a first semiconductor switching element (5), connected in series with the primary winding (6), having a small number of turns, of the transformer, and of which the control electrode is connected by via a series circuit consisting of a second semiconductor switching element (11) and a second resistor (10), at the common point of the resistor (2) and the capacitor (4), the primary winding ( 6) of the transformer being wound on a ier powder core (7) and being separated re galvanically and located at a distance from the high-voltage secondary winding (8) installed in an insulating mass.  2. Assembly according to claim 1, characterized in that the first semiconductor switching element  (5) is formed by a triac and that the second semiconductor switching element (11 is formed by a diac.  3. Installation according to claim 1 or 2, characterized in that a capacitor (12) is connected between the common point of the second resistor (10) and of the second semiconductor switching element (11) and the point of connection of the capacitor (4) to the network.  4. Installation according to claim 1, characterized in that the first semiconductor switching element (5) is formed by a thyristor and that the second semiconductor switching element (11) is formed by an avalanche diode  5. Assembly according to claim 4, characterized in that a diode (3), connected by its anode to an electrode of the first semiconductor switching element (5), is connected between the common point of the resistor (2) and of the second resistor (10) and the point common to said electrode of the first semiconductor switching element (5) and of the capacitor (4).  6. Installation according to any one of claims 1 to 5, characterized in that the number of turns of the primary winding (6) of the transformer is in the range from 2 to 50.  7. Installation according to any one of claims 1 to 6, characterized in that the secondary winding (8) of the transformer is formed by a high voltage coil of a television set.  8. Installation according to any one of claims 1 to 7, characterized in that there is provided a capacitor (14) connected in parallel to the terminals (1) of the alternating voltage source and in series with a coil of stop (13).