CS212613B1 - Electronic device for signaling from mining vessels to machine room - Google Patents

Abstract

The electronic device according to the invention does not require any special sources of electrical energy in the mining vessels for its operation and the mining or balancing rope does not have to be galvanically separated from the mining vessels. Electronic device for signaling from the mining vessels to the engine room with signal transmission using a current circuit, which is formed by a mining rope and a balancing rope, the ends of which are conductively connected to the mining vessels, in which nonlinear elements affecting the impedance of the current circuit are located. This current circuit is connected to the exchange in the engine room via two receiving and two transmitting transformers. Each of the mining vessels is equipped with at least one nonlinear element.

Description

An electronic device for signaling from mining vessels to an engine room with signal transmission by means of a current circuit consisting of a hauling rope and a balancing rope, the ends of which are conductively connected to the mining vessels in which non-linear elements affecting the impedance of the current circuit are located. This current circuit is coupled to the control room in the engine room via two receiving and two transmitting transformers. Each of the extraction vessels is provided with at least one non-linear element.

The invention solves an electronic device for signaling from mining vessels to the machine room, which does not need special sources of electric power in the mining vessels for its operation.

Various devices of this kind are known, but their common disadvantage is the need for galvanic separation of the hoisting and balancing ropes from the hoisting vessels. This galvanic separation is a technically demanding and expensive task when using long ropes.

The above drawbacks are eliminated by an electronic signaling device from the mining vessels to the machine room with signal transmission by means of a current circuit consisting of a hoisting rope and a balancing rope, the ends of which are conductively connected to the hoisting vessels in which nonlinear elements affecting the current circuit impedance. This current circuit is coupled to the control room in the engine room via two receiving and two transmitting transformers. The principle of the invention is that each of the extraction vessels is provided with one coupling transformer and at least one non-linear element. The non-linear element is formed by a circuit composed of a parallel combination of a light-emitting diode and a signal button contact, wherein one coupling transformer winding is connected in parallel to the non-linear element. The second winding of the coupling transformer consists of one or the second pull of the hoisting rope. One pull of the hoisting rope is the secondary winding of the first transmitting transformer and at the same time the primary winding of the first receiving transformer. The second pull rope is the secondary winding of the second transmitting transformer and at the same time the primary winding of the second receiving transformer. One secondary winding terminal of the first receiving transformer is connected to the signal input of the first keyed amplifier. One primary winding terminal of the first transmit transformer is connected to the output of the first switch.

One secondary winding terminal of the second receiving transformer is connected to the signal input of the second keyed amplifier and one primary winding terminal of the second transmitting transformer is connected to the output of the second switch. The second terminals of the secondary windings of the two receiving transformers as well as the second terminals of the primary windings of the two transmitting transformers are coupled. The signal output and reference output of the first keyed amplifier are connected to both inputs of the first evaluation circuit, the first output of which is connected to both inputs of the first evaluation circuit. The first output of the first evaluation circuit is connected to the first indicator light, while its second output is connected to the first input of the synchronizer. A first acoustic signal, a first optical signal and a first signal recorder are connected in parallel to the first input of the synchronizer. The signal output and reference output of the second keyed amplifier are connected to both inputs of the second evaluation circuit. The first output of the second evaluation circuit is connected to the second indicator light, while its second output is connected to the second input of the synchronizer. A second acoustic signaling, a second optical signaling and a second signal recorder are connected in parallel to the second input of the synchronizer. The syncronizer is coupled with its first output to the first switch input, its second output to the control input of the first keyed amplifier, its third output to the second switch input, and the fourth output to the control input of the second keyed amplifier.

When using said electronic device for signaling from multi-state extraction vessels, the non-linear elements of each storey of each extraction vessel are connected in series with each other.

Each non-linear element may be doubled or tripled if the reliability of the electronic device is to be increased. In this case, the non-linear element is formed by at least one circuit composed of a light emitting diode, to which an additional light emitting diode is connected with the signal button contacts connected in series. The same circuits are then connected in parallel. When this non-linear element is used in an electronic device for signaling from ballast extraction vessels, the non-linear elements of the individual levels of each extraction vessel are also connected in series with each other.

The advantage of the electronic device according to the invention is that, apart from the hoisting rope, which is an equally essential part of the hoisting devices, it is not dependent on any conductors. The hoisting rope does not have to be galvanically separated from the hoisting vessels, since the galvanic separation of long ropes is technically a very costly task. Another advantage is that the non-linear elements in the two extraction vessels can be exactly the same, each element being substantially simple, since it is made up only of the contacts of the signal button and one or two light-emitting diodes. The signal from the individual mining vessels is differentiated and is also confirmed back from the engine room to the mining vessel by a higher brightness of the light emitting diode (s).

The considerable simplicity of the non-linear elements enables their use in individual levels of the mining vessels. Furthermore, it is possible to double or triple the non-linear elements, which greatly increases the reliability of the entire device even at low cost.

Another advantage is the small dimensions of the non-linear element, so that there are no problems with its positioning and in addition it is possible to continuously signal the correct operation of the whole device even in containers, and this so-called diagnostic signaling enables to quickly find a possible diode or faulty contact.

The machine works with both standing and moving mining containers.

The accompanying drawing shows schematically an embodiment of an electronic device according to the invention, in which it shows:

Fig. 1 is a simplified cross-sectional view of a shaft and an electronic device, Fig. 2 shows the connection of non-linear elements in a multi-tonnage extraction vessel, Fig. 3 shows the connection of a non-linear element for doubling or tripling individual elements .

At each end of the hoisting rope HL. driven by friction disc TK. one KlK2 extraction vessel is suspended and at the same time is attached to the lower parts of the KlK2 extraction vessels. K2 DL leveling cable connected. Both ropes HL. The DLs are with both K1 lifting bins. K2 connected conductively. Each extraction vessel K). 12 is provided with one non-linear element and one coupling transformer TD. The non-linear element influences the impedance of the current circuit, which is formed by the ^1- cable HL. the first and second extraction vessel Kl. K2 and leveling rope DL. The two non-linear elements are identical and each consists of a circuit composed of a parallel combination of light-emitting diode D and the contacts of the signaling button T. The non-linear element is connected in parallel to one winding of the respective coupling transformer TD. the second winding of which constitutes the first or second pull of the hoisting rope HL.

The first pull of the hoisting rope HL is the secondary winding of the first transmit transformer TV1 and also the primary winding of the first receive transformer TP1. The second pull rope HL is the primary winding of the second receiving transformer TP2 and also the secondary winding of the second transmitting transformer TV2. Both transmitting transformers are TVI. TY2. as well as both TP1 receiving transformers. TP2 provides the connection with the control room in the engine room.

The control room in the engine room consists of a first and a second evaluation circuit VI. V2. of the first and second keyed amplifiers Z>. Z2. of the first and second switches Q1. G2. synchronizer SG. as well as signals, i.e. first and second indicator lights P1. P2. first and second acoustic signaling R1. R2. first and second optical signaling S1. §2 and the first and second TA1 signal recorders. TA2.

These parts are interconnected as follows:

One secondary winding terminal of the first receiving transformer TP1 is connected

2126.3

Ir. the signal input 10 of the first keyed amplifier Z1 and one primary winding terminal of the first transmit transformer TV1 is connected to the output of the first switch GJ. Furthermore, one secondary winding terminal of the second receiving transformer TP2 is connected to the signal input 20 of the second keyed amplifier Z2 and one primary winding terminal of the second transmitting transformer TV2 is connected to the output of the second switch G2.

The second terminals of the primary winding of the first and second transmit transformers TV1. TV2 and the second terminals of the secondary winding of the first and second receiving transformer TP1. TP2 are bumpy. The signal output 12 and the reference output 13 of the first keyed amplifier gj d * are connected to both inputs of the first evaluation circuit XJ, the first output 24 of which is connected to the first indicator light P1. The second output 83 of the first evaluation circuit V1 is connected to the first input 18 of the synchronizer gG. The first acoustic signal R1 is connected in parallel to this first input 18. a first optical signaling S1 and a first signal recorder TA1.

The signal output 22 and reference output 23 of the second keyed amplifier Z2 are connected to both inputs of the second evaluation circuit Xg, the first output 26 of which is connected to the second indicator light P2. while its second output 27 is coupled to the second input of the synchronizer SG. A second acoustic signal R2 is connected in parallel to this second input 19. a second optical signaling S2, a second signal recorder TA2. The synchronizer SQ is connected by its first output 14 to the input of the first switch GJ, by the second output 15 to the control input 11 of the first keyed amplifier Z1. the third output 16 with the input of the second switch G2 and the fourth output 17 and the control input 21 of the dual keyed amplifier 22 >

When using an electronic device for signaling in a KJ vlceetáž mining container,

K2 are individual non-linear elements in each of its. connected to each other in series, as is evident from the example in Fig. 2.

In order to increase the reliability of the device, each non-linear element can be doubled or tripled by parallel connection of the individual circuits of the element. In this case, the non-linear element is formed by a circuit consisting of a light-emitting diode 6, to which an additional diode D1 is connected in parallel with the signal button contacts T in series. The parallel connection of these additional circuits is indicated in dashed lines in FIG.

When using double or triple non-linear elements in the electronic signaling equipment in the K1 waggonage extraction vessel. K2, the individual double or triple non-linear elements in each of its levels are connected in series, as is evident from the example in Fig. 4.

The functions of the electronic device are as follows:

The synchronizer SQ rhythmically generates switching pulses for controlling both switches G1, G2, and keying pulses for controlling both keyed amplifiers Z1. Z2 so that you create in odd tact! the switching pulses for controlling the first switch 01, and the cushioning pulses for controlling the first keyed amplifier Z1 are generated in an even cycle! switching pulses for controlling the second switch Q2, and click pulses for controlling the second keyed amplifier Z2.

In the odd cycle, the back-acknowledged transmission of commands from the first extraction vessel to the control panel in the engine room is carried out by means of the SG synchronizer. the first switch GJ, the first transmit transformer TV1. of the first TP1 receiving transformer. the coupled TD transformer with a non-linear element, the first keyed amplifier Z1. a first evaluation circuit 11, as well as a first acoustic signaling R1. a first optical signaling gj, a first signal recorder JAJ, and a first warning light P1. In an even cycle, a back-acknowledged transmission of commands from the second extraction vessel K2 to the control panel in the engine room is carried out by means of a synchronizer SQ. a second switch G2, a second transmit transformer TV2. the second TP2 receiving transformer. associated coupling transformer TD with non-linear element, second keyed amplifier Z2. a second evaluation circuit Xg, as well as by means of a second acoustic signaling R2. second optical signaling S2. a second TA2 signal recorder; and a second warning light ř2.

The operation of the even-clock device is analogous to the odd-clock operation and is therefore explained in this odd clock only in the following description of the device function.

The first switch Gl. controlled by switching pulse SG synchronizer. switches the voltage on the primary winding of the first transmit CTI. On this winding of the first transmit transformer CTI, the rectangular pulses generated by the first switch G1 are differentiated. Positive exponential pulses generated by the derivation of non-parallel edges of these rectangular pulses are signaling. Negative exponential pulses resulting from the derivation of the falling edges of said rectangular pulses are reference. Both signaling and reference pulses are fed to the first receiving transformer TP1 via a moving current circuit formed by the hoisting rope HL. a first trough vessel 21 »with a balancing rope CL · and a second trough vessel K2 or via a current circuit formed solely by the traction rope HL ·. the first extraction vessel K1 and the conductive equipment of the shaft, whereby the impedance of this current circuit can be changed by means of the respective coupling transformer TD and the non-linear element. At rest with the signaling switch 6 in the first extraction vessel K1 closed, the first winding of the associated coupling transformer TD has it. which is formed by the hoisting rope HL. low linear impedance.

In this case, there is no change in the basic amplitude ratio of the signaling and reference pulses passing through the current circuit. The mixture of these pulses is further fed via the first receiving transformer TP1 to the signal input 10 of the first keyed amplifier 21, where it is amplified, the reference pulses are separated from the signal pulses by means of amplitude and time selection. output pulses at the signal output 12 of the keyed amplifier 21, at whose reference output 13 reference pulses are formed. First evaluation circuit VI. both inputs are connected to the signal output 12 and reference output 13 of the first keyed amplifier Z1. in this case, it does not evaluate any signal for the signals, which are the first warning light P1. first acoustic signaling R1. a first optical signaling SI and a first signal recorder TA1.

When signaling from the first extraction vessel K1, the signaling button T is pressed and the light-emitting diode D illuminates very slightly by passing through the transformed reference pulses, the second winding being formed by the coupling rope transformer TDI. which is formed by the hoisting rope HL. will have a significantly greater * impedance for the signal pulses than for the reference pulses, so that on the secondary winding of the first receive transformer TP1, the positive signal pulses will be substantially less than the negative reference pulses. In this case, there was a significant change in the ratio of amplitudes of signaling and reference pulses. The mixture of these pulses is further processed as described above except that due to the changed amplitude ratio of the signaling and reference pulses, the output pulses at the signal output 12 of the first keyed amplifier 21 are not evaluated. for a synchronizer 22 which increases the repetition frequency of the signal and reference pulses, which, by passing through the light emitting diode 6, increases its brightness, which is a confirmation of the transmitted signal.

In case of failure of the basic circuits of the device, resp. if the cables break in the tower or in the extraction vessel 21, resp. 22 »both the signal and reference pulses have disappeared and there is zero voltage at both inputs of the first evaluation circuit VI. In this case, the circuit works by illuminating the first warning light P1.

As with the non-linear elements shown in FIGS. 1 and 2, the electronic device according to the invention works analogously to the non-linear elements shown in FIGS. 3 and 4, wherein the non-linear elements shown in FIG. or 22 correct functioning of the whole device by means of LEDs β and Dl.

Claims (4)

SUBJECT OF THE INVENTION 1. Electronic equipment for signaling from hoisting vessels to engine room, with the transmission of signals by means of a current circuit, coupled through two receiving transformers and two transmitting transformers and a central machine room control system, consisting of a hauling rope and a balancing rope. in which each extraction vessel (K1, K2) is provided with one coupling transformer (TD) and at least one non-linear element formed by a circuit composed of a parallel light-emitting diode combination (D), ) and the contacts of the signaling button (T), where one coupling transformer (TD) winding is connected in parallel to this non-linear element, the second winding being formed by one or another pulling rope (HL), one pulling rope (HL) being secondary winding the first transmitter transformer (TV1) and primary winding of the first receiving transformer (TP1), the second pulling rope (HL) is the secondary winding of the second transmitting transformer (TV2) and also the primary winding of the second receiving transformer (TP2) (TPI) is connected to the signal input (10) of the first keyed amplifier (Z1), one primary winding terminal of the first transmitting transformer (TV) is connected to the output of the first switch (G1), one secondary winding terminal of the second receiving transformer (TP2) is connected to the signal input (20) of the second keyed amplifier (Z2), one primary winding terminal of the second transmitting transformer (TV2) is connected to the output of the second switch (G2), the second secondary winding terminals of both receiving transformers (TP1, TP2) blame The three output transformers (TV1, TV2) are grounded, the signal output (12) and the reference output (13) of the first keyed amplifier (21) are connected to both inputs of the first evaluation circuit (VI), the first output (24) of which the first indicator light (P1), while its second output (25) is connected to the first input (18) of the synchronizer (SG), the first acoustic signal (R1), the first optical signaling (SI) are connected in parallel to this first input (18) and the first signal recorder (TA1), the signal output (22) and the reference output (23) of the second keyed amplifier (Z2) are connected to both inputs of the second evaluation circuit (V2) whose first output (26) is connected to the second indicator light (P2), while its second output (27) is connected to the second input (19) of the synchronizer (SG), a second acoustic signaling (R2), a second optical the second output (14) is connected to the input of the first switch (G1), the second output (15) to the control input (11) of the first keyed amplifier (Z1) , a third output (16) with a second switch input (G2) and a fourth output (17) with a control input (21) of the second keyed amplifier (Z2). 2. An electronic device for signaling from the extraction vessels to the engine room according to claim 1, characterized in that the non-linear elements of the individual levels of each extraction vessel (11 E2) are connected in series with each other. Electronic device for signaling from mining vessels to the engine room according to Claims 1 and 2, characterized in that the non-linear element consists of at least one circuit composed of a light-emitting diode (D) to which another light-emitting diode (D1) is connected in series the signal button contacts (T). 4. An electronic device for signaling from mining containers to the engine room according to claim 3, characterized in that the individual circuits of the non-linear element are connected in parallel to each other. 3 sheets of drawings