DE1028584B - Control device for steam generator depending on the engine load - Google Patents

Description

Control device for steam generators dependent on the engine load The main patent relates to a control device for steam generators that is dependent on the engine load and has a hydraulic engine controller in which the speed changes associated with a load change in the engine are converted into a proportional pulse pressure. According to the main patent, the control pulses for the boiler are taken parallel to the engine control from one point of the control oil circuit, to which the oil pressure of both as well as independently thereof, depending on the stress changes of the engine due to additional engagement - is influenced - Drehzählverstellung.

The invention represents a further development of such a control. The invention meets higher requirements for the regulation, as they are above all in Block circuit of boiler and turbine are often made, with now also sudden load fluctuations are to be regulated. Accordingly, it is considered to be speed-dependent regulated and, if necessary, also a frequency regulation, transfer power regulation or the like. Provided. Since in many cases the normal operation is not the sliding pressure operation, instead of fixed pressure operation, the regulation should continue to be used for this operating mode as well be suitable.

The load influences, which represent more or less changing quantities, go, as described in the main patent, first to the turbine steering and thus on the main steam valves of the turbine. In parallel, however, at the same time corresponding pulses to the steam generator, for example to the Load transmitter of a Benson boiler passed on. So the boiler is in its load commands coupled to the turbine and its load commands, so that both are like one unit are influenced and are also subject to the necessary safeguards together.

If the load changes are sufficiently slow, this works Regulation flawless. But if there are rapid changes in load, the Turbine control quickly take over the new load value itself, the steam generator however, it is too sluggish to be able to adapt to the new load quickly enough. If, in the event of a sudden increase in load, the turbine control system gives the command given to open the control valves further, the turbine will respond to this command in itself quickly after. The boiler is not able to do the now to apply the larger amount of steam required, and it will take a certain amount of time until the required amount of steam is available. Similarly, when suddenly Load reduction of the boiler takes some time to adapt to the new load value can.

These difficulties are eliminated by the invention. The invention causes the actual load of the turbine to be changed by suitable impulses, z. B. by a live steam pressure pulse, compared to the target load pulse, which is common is given for turbine and boiler as long as it is counterfeited to such an extent, until the boiler control has met and adapted to the new load value. The target load impulse for the boiler is not falsified, so it remains unchanged exist.

The inventive New is accordingly that, with changes in load and simultaneous waste transfer of a driving pulse to the combustion engine and the steam generator to the pulse for the engine temporarily a preferably forward steam generator group derived fault value in the sense of maintaining the existing state connectable is, without affecting the Control pulse for the steam generator is influenced. This temporary connection remains in effect until the regulation of the steam generator has been complied with. The respective difference between the actual load of the turbine and the target load of the boiler and turbine together can be monitored and measured. If necessary, this difference can be used as an additional impulse for the control.

It is already known per se to allow an additional leading pulse or a special compensating additional pulse to act on the boiler control in order to shorten the delay of the control pulse when regulating forced flow boilers. It is also known, when regulating a steam power plant, to select the characteristic of the pressure regulation to be steeper than the output characteristic in order to achieve rapid boiler regulation. Finally, further measures, the additional control pulses are in the Zureinwirkungbringung are sawn, known become lower in a system of boilers storage capability, thereby enabling a faster effective boiler control. While in these known arrangements these measures are only taken within the framework of the boiler control, the invention relates to a control device in which the boiler control and oil pressure control that is also effective for the turbine control is assumed. In contrast to these known devices, each control pulse is therefore always given both to the steam generator and to the engine. While in the known devices means are used to accelerate the intervention of the boiler control, the invention provides not to intervene in the boiler control, but to place it directly under the control without additional influences. In contrast, it is ensured that the control of the power machine initially remains in its previously existing state.

The invention is to be explained in more detail with reference to the drawing. the Figures show exemplary embodiments in their essential parts for the invention in a greatly simplified, partly schematic representation.

In Fig. 1 a scheme is shown on the basis of which the principle of the invention is to be explained in more detail. A turbine 1 , which drives a generator 2, is provided as the engine. An oil hydraulic device 3 is used to control the speed of the turbine, which z. B. consists of an oil pump, which is dependent on the speed and creates oil pressure in the oil line 4 that grows with it, the size of which is a measure of the speed. A hydraulic pressure transducer is symbolized by 5 , which is acted upon on the one hand by the oil pressure in the oil line 4, but on the other hand is under the influence of an externally supplied variable, for which a manually or electrically adjustable speed setting device 6 is used, for example. In their place or in addition to this, other devices can be used which are derived, for example, from the generator 2 or the electrical network, or which effect a speed setting from a remote point.

The hydraulic pressure transducer 5 causes oil pressure in the absence dependence forward in the pressure conduit 4, which is regarded as the primary pressure line, an accordingly changing oil pressure in the secondary Oldruckleitungen 7 and g. The pressure transducer 5 can not only be designed so that an amplification or conversion to higher pressures takes place, but it is advantageously designed so that a falling oil pressure in the primary line 4 is converted into an increasing oil pressure in the secondary system 7, 8 and if necessary, the pressure curve is also carried out according to another function.

The secondary control oil pressure in the line system 7, 8 now acts simultaneously on the turbine control 9 and on the load transmitter 10 for the boiler control. The turbine control works on the control valve 11, the load transmitter 10 on the boiler control of the steam generator 12, which is not shown in detail.

If there is a sudden change in load, the oil pressure in the primary and, accordingly, also in the secondary pressure system changes, so that the regulation for the steam generator 12 immediately tends towards the new load value via the boiler load sensor 10, but without being able to reach it quickly enough. The turbine regulator 9 also endeavors in the same way, only that its regulation is able to adjust itself to the new value immediately. Now, however, via the influence symbolized by the pulse line 13 from the boiler, for example by a live steam pressure pulse, the actual load of the turbine is temporarily falsified compared to the target load pulse given for the turbine and boiler until the boiler control has complied and adapted to the new load value. As the illustration shows, the target load pulse for the boiler is not falsified, but rather remains unchanged.

14 with an additional device is referred to, which monitors and measures the respective difference between the actual load of the turbine and the target load of the boiler and turbine, this difference on the influence 15 still as an additional pulse for the control, z. B. the boiler is used.

In FIG. 2, an exemplary embodiment for the regulation of a block system containing a condensation turbine with reheating is illustrated. Only the parts essential to the invention are shown here in greater detail and the remaining details are drawn in a greatly simplified and schematic manner. A bellows arrangement 17, which is part of the hydraulic pressure transducer, is connected to the primary oil circuit, which is derived from the control gyroscope seated on the turbine shaft and denoted by 16. This operating as a velocity controller assembly includes a recliner forth influenced from the outside 18, corresponding with your 6 designated institution of the drawn in Fig. 1 system. The moving parts of the pressure transducer work on the separate arrangements 19, 20 and 21 which control the secondary oil pressure systems, of which parts 19 and 20 work on the turbine via the control oil lines 30 and 31 and part 21 on the boiler. A high-pressure control valve, which is actuated via the hydraulic drive 23 , is designated by 22. A medium-pressure control valve is denoted by 24, to which the associated medium-pressure quick-closing valve 25 is connected. While the high pressure quick stop valve is not shown, a relief valve 26 is shown.

In the symbolic representation, 27 symbolizes the boiler and 28 a superheater. 29 represents a safety valve. Via the high-pressure quick-acting valve 32 , the live steam flows through the high-pressure control valve 22 ', which is designed in accordance with the valve 22. The engine contains a high-pressure turbine 33, a medium-pressure turbine 34 and a low-pressure turbine 35. The generator is denoted by 36. Safety regulator 37 and quick-release device 39 are indicated on the turbine shaft.

The boiler control is influenced by the part 21 of the speed controller 38, 38 ' , with a corresponding pulse via the influencing line 40 and load transmitter 41 initiating the boiler control, as indicated by the pulse line 42. At the same time at a load change also the part 19 has the speed controller 38 to adjust the effort to the turbine control system for high-pressure valves accordingly. The 'se adjustment but is inhibited by a temporary disturbance variable feedforward in the sense of maintaining the existing state is performed in accordance with the steam pressure on the pulse line 43 by means of the regulator 44th The actual load of the turbine is thus, as indicated by the arrows 45, falsified by changing the oil pressure in the oil line 30 until the boiler control is complied with. A change in the target load, i. H. however, there is no change in the oil pressure in the oil line 40.

In the exemplary embodiment shown, the speed controller 38 also has a special feature. Here the pressure pin 46, which is moved up and down by the bellows, does not act directly on the plate 47, but an intermediate member is used in order to be able to switch on a translation which varies from case to case. It would actually be possible to take measures on each of the arrangements connected to the secondary control oil systems in order to be able to set a certain statics of the regulation. For example, it is possible. to the drive 23 of the high pressure - to bring the control valve 22, the tapered abutting surface 48 of the push rod by turning to another angle of its generatrix, so that therefore the static to a different value can be set at will. A different valve position would then correspond to a certain value of the control oil pressure. Similar parameters can also be found on the other arrangements connected to the oil lines 30, 31 and -10 . In many cases, however, it may be desirable not to be able to carry out these adjustments individually at several locations, but rather at a central location. If you now bring in a selectable transmission ratio in the transmission of the pin 46, you are able to make the desired adjustment simultaneously for all three oil pressure lines 30, 31 and 40 and the arrangements connected to them.

In the illustrated embodiment, the upper tip of the pin 46 presses, as said, not immittelbar to the plate 47, but against a movably mounted at 49 intermediate plate 50. Between the intermediate plate 50 and the overlying plate 47 is, stressed transfer body only on pressure 51 provided, which can be displaced in the direction of the double arrow # 53 by a suitable adjusting device 52 . The back pressure is maintained by the spring 54 with such strength that the parts always lie tightly against one another. If the pressure body 51 is now moved in the direction of the axis of rotation 49, a reduction, as it were, occurs, i.e. That is, the movement of the plate 47 is reduced, while when the pressure body 51 is displaced in the other direction, a translation with greater movement of the plate 47 is formed. By suitably designing the moving parts, it is also possible to achieve certain movement characteristics which result in a non-proportional transmission ratio. Incidentally, instead of such an arrangement, variable ratios that act differently are also conceivable.

In Fig. 3 , a further Atisführung example for the invention is illustrated. The boiler is denoted by 55. The live steam reaches the high-pressure part 57 of the turbine via the high-pressure control valve 56 , the middle and lower areas of which are denoted by 58 and 59. 60 symbolizes a speed regulator, in which a tour adjustment or. Load changing arrangement 61 is provided. Through this impulse, the control pistons 63 and 64 for the control oil lines are adjusted via suitable transmission members 62. The control oil pressure is fed to the control unit 65 through the line 66 and reaches the control pistons 63 and 64 via the start-up control reducing valve 67 via the oil line 68. Accordingly, a load-dependent pulse oil pressure is created in the oil pressure lines 69 and 70. This acts on the one hand on the pulse converter 76 for the boiler control (load regulator with oil pressure piston manometer), the effect of which on the boiler 55 is symbolized by the pulse line 71. Furthermore, the high-pressure control valve 56 for the turbine is influenced via the arrangement 72, which contains the high-pressure control cylinder 73. Finally, the oil pressure that has come about in the line 70 acts on the medium pressure control 74 with the medium pressure control valve 75 of the turbine part 58.

According to the oil pressure in the line 69 , the pulse converter 76, as symbolized by the pulse line 71 , causes an immediate setting of the boiler sizes. For example, in the event of a sudden increase in load, the resulting increased pressure in the oil line 69 brings about a boiler control in the sense of increased steam output. Since the high-pressure turbine valve control 72 is now also connected to the oil line 69 , the latter tries to open the control valve 56 further. This process is now inhibited by the fact that, as indicated by the pulse line 82 , a pulse converter 77, which can be designed, for example, as a pre-pressure regulator with a vapor pressure piston manometer, is influenced on the boiler side in such a way that a disturbance pulse is superimposed on the high-pressure control unit 72 via an additional oil pressure line 78 . As a result, the actual load of the turbine is falsified until the boiler control is complied with. The impulse for the boiler control indicated by the impulse line 71 is not influenced. The pulse converter 77 is connected to the oil line 79 via the reducing valve 80 to the oil line 81 from the control unit 65 .

Claims (2)

PATENT CLAIMS: 1. Regulating device for steam generators that is dependent on the engine load and has a hydraulic engine controller in which the changes in speed associated with a load change in the engine are converted into a proportional pulse pressure and the control pulses for the boiler are taken from one point in the control oil circuit parallel to the engine control which the oil pressure is influenced both as a function of the changes in the load on the engine and independently of this by additional intervention, according to patent 945 029, characterized in that the impulse for the engine is temporarily activated in the event of load changes and simultaneous delivery of a control pulse to the engine and to the steam generator The disturbance value derived preferably from the steam generator can be switched on in the sense of maintaining the existing state without the control pulse for the steam generator being influenced as a result. 2. Device according to Claiml, characterized in that the interference value can be derived from the live steam pulse of the steam generator. 3. Device according to claim 1 or 2, characterized in that the disturbance value switching takes place so long and to such an extent that the boiler control has complied and has adapted to the new load value. 4. Device according to claim 1 to 3, characterized in that an additional device is provided which monitors the respective difference between the actual load of the engine - fake pulse - and target load of the steam generator and engine - falsified pulse. 5. Device according to claim 4, characterized in 'that the difference is formed between the actual load of the engine and target load used by the steam generator and the engine as an additional impulse for the control. Considered publications: German Patent Nos. 612 310, 686 159; S. G. G erassim ow ', Automatic control of boiler systems, 1952, pp. 321 to 323.