DE1020834B - Device for operating gas turbines - Google Patents

Description

Apparatus for Operating Gas Turbines The invention relates to on a. Device for operating gas turbines with open circuit. Below gas turbines are to be understood in which the actual turbine is produced by a mixture powered by air and products of combustion, the air in a compressor compressed and then by combustion with a pulverized solid fuel is heated in a combustion chamber, whereupon the mixture expands in the turbine.

A device for operating such turbines must essentially meet two requirements: first, the fuel must be in the combustion chamber in which the air is under high pressure with a minimum loss of high pressure air and, secondly, the feed rate of the fuel in the combustion chamber can be regulated quickly and precisely without generating pulsations.

It has already been proposed to operate such gas turbines used pulverized solid fuel in the fluidized bed state to move, the fuel being whirled up in two stages. It facilities for the operation of gas turbines have also become known at those of the pulverized fuel depending on the speed of the turbine is regulated.

It has now been found that the regulation of the flow of the fluidized fuel in the fluidized bed state in direct dependence on the speed of the gas turbine alone is not sufficient to fully meet the requirements set out above. Therefore, when the object of the present invention forming device, the flow of the swirled fuel to be controlled to the second stage of the Aufwirbelns effecting pressure column essentially as a function of the level height of the fluidized bed in the relevant column, whereby an accurate and rapid control achieved will.

In the drawing, the invention is in one embodiment for example illustrated.

1 shows a schematic representation of a gas turbine plant according to the invention; Fig. 2 shows a schematic representation of the switching arrangement of the hydraulic and electrical regulators; Fig. 3 shows in section the control valve for the fuel supply from the atmospheric column to the positive pressure column; Fig. 4 shows in section the control valve for the fuel supply from a source to the atmospheric column.

In the following, the gas turbine and its various devices will be described in sequence. As illustrated in Fig. 1 , peat is fed from a dewatering press, not shown, to a centrifugal mill 11 , where it is crumbled into moderately small lumps. These arrive at a rotating blind drying device 12, where they are dried by the exhaust gases from the gas turbine, which are fed in through a pipe 13 and discharged through a pipe 14. The lumps of peat then fall from the drying system onto a turntable15, where they are separated into two parts; some parts are being returned by a mixing conveyor belt 16 to the not shown dewatering press, the other passing through the pipeline 17 to 19, an edge runner mill In both cases, the supply is controlled by adjustable blades 18 on the rotary table 15 °. Blow through the pan 19 w-rd by a stream of air which passes through a side pipe 20 into the pipeline 17 . The fuel pulverized in the pan 19 is then separated from the conveying air in a cyclone 21.

The cyclone 21 is arranged above an atmospheric column 22 which acts as a reservoir. From there, the fuel arrives at a peat pulp 23 which is supplied with high pressure air through a pipe 24 and which puts the supplied fuel under high pressure. From the pump 23 the swirled peat flows through a pipe 25 to a small cyclone 26 which is arranged above a positive pressure column 27 and in which the high pressure air is separated from the peat conveyed through the same. The peat is fed from the overpressure column 27 through a valve 28 and a pipe 29 to the combustion chamber 30 of the turbine 31.

Gt, the high pressure air passes from the small cyclone 26 30 through a conduit 32 into the combustion chamber, the atmospheric column 22 through a pipe 33 with operating air from any suitable source, the befindeniann outside of the power unit, versor '. The operating air for the überdrucksäule27 is promoted by the compressor 34 of the gas turbine 31 via an auxiliary fan 35. A branch line 36 of the auxiliary fan 35 serves to supply the pulverized peat from the control valve 28 to the combustion chamber 30. Between the fuel level of the overpressure column 27 and the pipe 29 through which the peat reaches the combustion chamber 30 from the control valve 28 , there is an open connecting line 37, 32 arranged.

In FIG. 2, the circuit arrangement of the electrical and hydraulic control elements for the gas turbine according to FIG. 1 is illustrated.

The height of the fluid that is whirled up in the overpressure column 27 can vary between two limit values which are determined by adjusting the height of two electrical scanners 40 and 41. These two scanners are connected to a double-acting relay 42 which can be set to one of two positions, namely open contacts or closed contacts, by a suitable current and which remains in this position regardless of the cessation of this current until an opposite occurs effective current begins. The possibility of feeding the relay 42 with currents of opposite sense from the scanners 40 and 41 is indicated by cable lines which lead from the scanners to the two ends of the relay coil; however, this is only a schematic representation which does not necessarily correspond to the coil connection actually used. When the level of the fluid that has been swirled up in the column 27 moves upwards until it reaches the upper scanner 41, the contacts of the relay 42 are opened and remain open afterwards, regardless of the fact that the level drops below the higher scanner 41 again. Only when the mirror sinks below the lower scanner 40, the contacts of the relay 42 are closed, whereby the electrically controlled switching valve 61 is closed by means of a current coil.

The supply of operating fluidized substance from the atmospheric column 22 to the pipeline 25 is regulated by means of a valve 43, which is shown in detail in Fig. 3. This valve 43 has a working piston 44 and a closing element 45 which is connected to the piston and which, together with the piston, is pressed elastically upwards by a spring 46. The cylinder 47 containing the piston 44 is permanently connected at its upper end to a pressure oil line 48 and is provided with relief lines 49, 50 and 51 at three different, stepped height points. The relief line 49 arranged at the top contains an electrically controlled switching valve 52, "which in its open position offers a leakage path for the pressurized oil when the piston 44 is brought into its uppermost position by the spring 46. If, on the other hand, the valve 52 is closed, the piston 44 is displaced downwards until it exposes the second relief line which contains the switching valve 61. When this valve is open 61, the piston 44 stays in this middle position. in contrast, when the valve 61 is closed, the piston 44 continues to shifted down until it exposes the constantly open relief line 51.

These three possible settings of the piston 44 result in three possible settings of the closing element 45 in relation to corresponding openings 53 through which the operating medium can flow. In the uppermost position, the openings 53 are mutually blocked so that no fuel can flow through. In the middle position, an opening 54 in the closing element 45 allows a restricted flow of the operating material from the atmospheric column 22 to the overpressure column 27. In the lowest position, a large opening 55 allows the full flow of the operating material.

In this way an arrangement is created in which the feed of powdered fuel from the atmospheric column to the positive pressure column depending on your level of the fluid that is whirled up in the overpressure column is regulated.

The supply of the fuel to the atmospheric column 22 is regulated as a function of the level of the fluidized bed in said column. This mirror height is measured by the static pressure difference between the fluidized part and the bottom of the fluidized bed. This static pressure difference is shown schematically as if it were operating in two pneumatic lines 56 which are connected to the two sides of a core chamber of a control device 57 of the shredder loading which is illustrated in detail in FIG.

By adjusting the Meinbran 58 , the increase in the oil pressure in a cylinder 59 and thereby the adjustment of a piston 60 in this cylinder is regulated. This piston 60 controls the setting of the adjustable blades 18 (FIG. 1). by which the rate of supply of the fuel to the atmospheric column is determined.

In this way the supply of the fuel becomes atmospheric Column 22 is regulated by the height of the fluidized bed in this column. The high of Fluidized bed in said column is created by the outflow from the same and thus determined by the level in the positive pressure column, and the level in the positive pressure column is in turn by the outflow from the same and thus by the speed of the gas turbine regulated.

Claims (2)

PATENT CLAIMS: 1. Device for the operation of gas turbo machines in which the pulverized fuel, which has been put into the state of the fluidized bed, is regulated as a function of the speed. wherein the fluidization of the fuel in two stages, characterized in that the supply of fluidized Breimstoffes is controlled by the atmospheric column (22) to the zurÜberdrucksäule (27) leading pipe (25) by means of a valve (43) which in the absence dependence on the level of the fluidized bed in the column is controlled. 2. Device according to claim 1, characterized in that the control cylinder (47) of the control valve (43 ') between the pressure columns (22 and 27) is continuously acted upon at one end with control oil from a line (48) and at three different stepped points of the Piston stroke path is provided with relief lines (49, 50 and 51) . 3. Device according to claim 2, characterized in that the first relief line is provided at the beginning of the piston stroke with an electromagnetically controlled valve (52) . 4. Device according to claim 1, characterized in that the supply of fuel into the atmospheric column (22) is regulated as a function of the level of the fluidized bed in the column. 5. Device according to claim 4, characterized in that the static pressure difference in the column is pneumatically transmitted to the control device (57) of a charging device. Documents considered: Engineering, Vol. 175, 1953, pp. 308 to 311; The Engineer, Vol. 195, 1953, pp. 350/351; Chemie Ingenieur Technik, Vol. 24, 1952, pp. 58 to 65; U.S. Patent No. 2,568,127 .