CS257559B1 - Connection of two-phase contactless rail receiver - Google Patents

Abstract

Two-phase contactless connection The rail receiver is designed for safe use evaluation of track circuit freedom which is the primary information in terms of gravity on the basis of which the resulting result is derived security of downstream security equipment. So far known contactless receivers they are disproportionate, ie multiple more expensive than contact rail relays and therefore are used and further projected at ČSD mainly contact rail relays. U naposled named relays have recently a number of serious deficiencies. Principle contactless rail receiver connection allows you to significantly reduce the cost in comparisons with previously known solutions.

Description

The invention relates to the connection of a two-phase contactless rail receiver with high immunity to disturbances and with a safe control of the critical elements of the device.

The previously known contactless rail receiver used by ČSD also has high technical parameters, ie high immunity to interference and a high switch-off factor, but its cost is high due to the use of special elements and complex construction.

The above drawbacks are eliminated in the wiring of a two-phase non-contact rail receiver according to the invention arranged so that the first output of the local transformer is connected to the input of the first generator, while the second output of the local transformer is connected to the input of the first rectifier. and at the same time to the input of the second switching element such that the first working terminal of the first switching element is connected in series with the first element transmitter to the first rail transformer output, while the second working terminal of the first switching element is connected in series with the first resistor to the second terminal of the output transformer, the second working terminal of the first switching element being connected to the second working terminal of the second switching element, while the first working terminal of the second switching element u is connected in series with the transmitter of the second control element and in series with the second resistor to both the second terminal of the rail transformer and the second terminal of the first capacitor, the first output terminal of the first rectifier being connected to the second terminal of the auxiliary transformer connected in series with the receiver of the first control element to the first terminal of the auxiliary transformer, and in series with the receiver of the second control element to the third terminal of the auxiliary transformer, while the output of the auxiliary transformer is connected to the input of the second rectifier. generator, while the first output of the second generator is connected to the input of the third switching element, but the second output of the second generator is connected to the input of the fourth switching element, while the first working terminal of the third the switching element is connected to the first terminal of the output transformer, while the first working terminal of the fourth switching element is connected to the third terminal of the output transformer, the contact transformer evaluation elements of the contact transformer being connected to the output transformer output.

The progress achieved by the invention is that the two-phase contactless rail receiver according to the invention achieves comparable technical parameters to the top two-phase ferritotransistor rail receiver used in CSD, but is considerably cheaper compared to the latter receiver due to the original solution of safe controls of critical switching elements. These checks are based primarily on discretization of the discriminator processed signal. The high switch-off factor is achieved primarily due to the rectangular hysteresis loop of the ferromagnetic material of the output transformer or of the auxiliary transformer.

Due to the supersaturity of the output circuit's magnetic circuit with 50 Hz signal currents, in addition to the immunity provided by the discriminator itself, immunity to dangerous interference by the disturbing industrial frequency and its close harmonic multiples significantly increases.

It should be noted that the nominal operating frequency of the discretization signal provided by the first generator, but also the frequency of the output transformer, which is determined by the second generator, is in an area about two orders of magnitude higher than the signal frequency. As a result, the dimensions of the output and auxiliary transformers can be relatively small. Therefore, the wiring of a two-phase contactless rail receiver according to the invention is also more advantageous than in the prior art solutions.

Figure i shows the wiring of a two-phase contactless rail receiver. Figure 2a shows the discretization of local stress. Figure 2b shows the general pattern of local stress and rail stress. Figure 2c shows an example of a discriminator current pattern.

In Figure 1, the first output 1-3; 1-4 of the local transformer JL connected to input 3-1; 3-2 of the first generator 3, while the second output 1-5; 1-6 of the local transformer 1 is connected to input 4-1; 4-2 of the first rectifier 1, wherein the output 3-2; 3-3 of the first generator 3 is connected to input 9-1; 9-3 of the first switching element 9 and at the same time, at the input 10-1; 10-3 of the second switching element 10 such that the first working terminal 9-2 of the first switching element 9 is connected in series with the transmitter 71 of the first control element 7 ^{to the} first output terminal 2-3 of the rail transformer 2, while the second working terminal 9-3 the first switching element 2 is connected in series with the first resistor 11 to both the first capacitor 12 and the second terminal 16-2 of the output transformer 16, the second working terminal 9-3 of the first switching element 23 being connected to the second working terminal 10- 3 of the second switching element 10, while the first working terminal 10-2 of the second switching element 10 is connected in series with the transmitter 81 of the second control element 8 and in series with the second resistor 13 to the second terminal 2-4 of the rail transformer 2 and to the second terminal 12-2 of the first capacitor 12, wherein the first output terminal 4-3 of the first rectifier 2 is connected to the second terminal 5-2 of the auxiliary transformer 5; while the second output terminal 4-4 of the first rectifier 8 is connected in series with the receiver 72 of the first control element 7 to the first terminal 5-1 of the auxiliary transformer 5, and in series with the receiver 82 of the second control element 8 to the third terminal 5-3 of the auxiliary transformer a transformer 5, whereas an output 5-4; 5-5 of the auxiliary transformer 5 is connected to input 17-1; 17-2 of the second rectifier 17 wherein ^- outlet 17-3; 17-4 of the second rectifier 17 is connected to input 6-1; 6-3 of the second generator 8, while the first output 6-2; 6-3 of the second generator is connected to input 14-1; 14-3 of the third switching element 14, but the second outlet 6-4; 6-3 of the second generator 2 is connected to input 15-1; 15-3 of the fourth switching element 15, while the first working terminal 14-2 of the third switching element 14 is connected to the first terminal 16-1 of the output transformer 16, while the first working terminal 15-2 of the fourth switching element 15 is connected to the third terminal 16 -3 of output transformer 16, wherein to output 16-4; 16-5 of the output transformer 16, the evaluated elements of the contactless rail receiver are connected, while input 2-1; 2-2 of the rail transformer 2 3® is connected to the output of the rail circuit under evaluation. Figure 2a shows the dependence of discretized local voltage 100 on time t. Figure 2b shows the phase angle between local voltage waveform 001 and rail voltage 1000. Figure 2c shows the dependence of discriminated current 1001 on time t.

1 shows the principle of operation of the two-phase rail receiver. The local voltage 001 is discretized in one way by the first generator 3, which, for example, generates rectangular oscillations whose frequency lies in an area which is approximately two orders of magnitude higher than the signal frequency, i.e. the frequency of the local voltage. Output 3-3; 3-2 of the first generator 2, therefore, a discretized local voltage 100 is generated (see Figure 2a).

At the time of impulse of the discretized voltage 100, for example, the first switching element 9 is actuated, while at the time corresponding to the gap of the discretized voltage 100, the second switching element 10 is actuated, or vice versa. Assuming there is a nonzero intersection of the local voltage 001 and the rail voltage 1009 (see Figure 2b), conditions for the flow of the discriminator current 1001 see Figure 2c are generated, the source of which is the rail transformer 2 ^{and the} first resistor 11, first capacitor 12 and output transformer circuit 16.

The current flow of the first switching element is controlled by the first control element 7, whose output terminal 7-4 is connected to the first terminal 5-1 of the auxiliary transformer 5. The current flow of the second switching element 10 is controlled by the second control element 2, whose output terminal 8-4 is connected to the third terminal 5-3 of the auxiliary transformer 2 · ^Assuming a trouble-free current flow through the first switching element 10, a voltage is generated at the output 5-4; 5-5 of an auxiliary transformer 5, the magnetic circuit of which is formed from a ferromagnetic, whose hysteresis loop is rectangular or near rectangular. In other words, the one-way excitation of the auxiliary transformer 5 will not result in the generation of the output voltage of the auxiliary transformer 2.

Assuming that the auxiliary transformer 2 generates an output voltage, conditions are provided for the operation of the second generator 2, which is supplied from the output 17-3; 17-4 second rectifier 17. For proper operation of the second generator 17, conditions are created for pulsed switching of the third switching element 14 and fourth switching element 2 to 2 · if ^the track voltage is greater or equal to the pull of the track receiver processor generates output voltage at output 16-4? 16-5 of the output transformer.

The operating current of the second switching element 10 has a source formed by the first capacitor 12. The failure of the first capacitor 12 is thus transferred in a more secure direction by the contactless rail receiver according to the invention. Since the magnetic circuit of the output transformer 16 is formed from a ferromagnetic with a rectangular hysteresis loop, it is output 16-4; 16-5 generates voltage only when the third switch element 14 and the fourth switch element 15 are operating properly and at a sufficient discriminator current level of 1001. In addition, due to said rectangular hysteresis loop of the magnetic circuit material of the output transformer 16 and auxiliary transformer 5, the quality of the rail receiver is decisively characterized.

Another decisive parameter is the immunity of the receiver against disturbances, especially the industrial frequency. This is achieved, on the one hand, by its own discriminator, and on the other hand, in that the magnetic circuit of the output transformer 16 is chosen to be supersaturated at the industrial frequency. As a result, the transmission is terminated, thereby transferring the fault in a safer direction. Last but not least, the elimination of disturbing currents is provided by the circuit of the second switching element 10, the operation of which is safely controlled in the manner described above.

The present solution of the discriminator is described as a one-way system for ease of interpretation. It is obvious that the proposal of a discriminator can be conceived in a double action. In this case, both the local transformer 1 and the rail transformer 2 would have one more winding and downstream circuits. The temperature independence of the decisive parameters of the track receiver is easier to achieve than the prior art track receivers, since a more stable temperature mode of the decisive switching elements can be selected, apart from the Curie temperature ferromagnetics, from which the magnetic circuits of the output transformer 16 and auxiliary transformer 5 are made. may be substantially higher than ferrite materials with a rectangular hysteresis loop.

The two-phase contactless rail receiver can be used, for example, to upgrade the existing rail receiver of the DSš series at the Czechoslovak state railways, which has recently appeared to be extremely topical.

Claims (6)

SUBJECT OF THE INVENTION Connection of a two-phase contactless rail receiver characterized in that the first output (1-3? 1-4) of the local transformer (1) is connected to the input (3-1? 3- 2) first generator ( 3), and the output (1-5? 1-6) of the local transformer (1) is connected to the input ( 4-1? 4-2) of the first rectifier (4), wherein the output (3-4-3-3) of the first generator (3) is connected to the input (9-1? 9-3) of the first trip element (9) and simultaneously to the input ( 10-1; 10-3) of the second switching element (10) wherein the first working terminal (9-2) of the first switching element (9) is connected in series with the transmitter (71) of the first element (7) to the first output terminal (2- 3) the rail transformer (2), the second working terminal (9-3) of the first switching element (9) is connected in series with the first resistor (11) to the first capacitor (12) and to the second terminal (16-2) of the output transformer (16), and the first operating terminal (10-2) of the second switching element (10) is connected in series with the transmitter (81) of the second control element (8) and in series with the second resistor (13) to the second terminal (2). -4) a rail transformer (2), to the second terminal (12-2) of the first capacitor (12), and the first output terminal (4-3) of the first rectifier (4) is connected to the second s vorku ( 5-2) of the auxiliary transformer (5), while the second output terminal (4-4) of the first rectifier (4) is connected in series with the receiver (72) of the first control element (7) to the first terminal (5-1) of the auxiliary transformer (5), in series with the receiver (82) of the second control element (8) to the third terminal (5-3) of the auxiliary transformer (5), and the output (5-4-5-5) of the first transformer (5) is connected to the input (17-1? 17-2) of the second rectifier (17), and the output (17-3? 17-4) of the second rectifier (17) is connected to the input (6-1? 6-3) of the second generator (6) ), and the first output (6-2? 6-3) of the second generator (6) is connected to the input (14-1; 14-3) of the third switching element (14), and the second output (6-4; 6-3) of the second generator (6) is connected to the input (15-1; 15-3) of the fourth switching element (15), and the first working terminal (14-2) of the third switching element (14) is connected to the first terminal (16-1) of the output transformer (16), and the first working the terminal (15-2) of the fourth switching element (15) is connected to the third terminal (16-3) of the output transformer (16) and to the output (16-4; 16-5) of the output transformer (16) are connected the evaluation elements of the contactless rail receiver , and the input (2-1; 2-2) of the rail transformer (2) is connected to the output of the rail circuit under evaluation.