DE2919184A1 - Industrial boiler with motor-generator - uses back-pressure steam turbine to drive air pump supplying boiler - Google Patents

Abstract

The industrial boiler has at least one of its air pumps driven by an electromotor or motor/generator and by a back-pressure steam turbine. When the boiler system is in normal operation the electricity produced by the motor/generator is supplied to the mains network. The boiler is high-speed and a 'cold' flue-gas velocity of at least 15 Nm/sec. (pref. 20-40 Nm/sec.) prevails at its heating surfaces. The static draught loss on the flue gas side at rated loading is at least 0.04 bar (pref. greater than 0.1 bar). The advantage lies in increased efficiency due to the use of a motor/generator to produce electrical energy in back-pressure mode.

Description

I n d u s t r i e d a in f k e s s e 1

The invention relates to an industrial steam boiler (shell boiler, Water tube boiler), which as a high speed boiler and / or in very simple Way for the generation of electrical energy - as a secondary task - trained is.

In the industrial boilers built up to now, the draft loss has been reduced to Flue gases mostly kept in amounts of 0.01 to 0.02 bar (values apply to nominal load) in order not to increase the drive requirement of the air or smoke gas fan too much allow. This fact requires relatively large heating surfaces and conditionally expensive and heavy boilers.

Was with these industrial boilers in addition to the supply of heating steam as an acknowledgment task, the generation of electrical energy in counter-pressure operation provided, the partial expansion of the steam took place in a separate counter-pressure steam turbine generator.

With shell boilers for pure 3att steam (heating steam) delivery the generation of electrical energy in back pressure operation has not yet been carried out. This is the proportion of these pure saturated steam boilers in shell boilers particularly high (approx. 80%) and their use for secondary electricity generation is off Very desirable for energy and economic reasons.

To avoid these disadvantages, an industrial boiler (shell boiler, Water tube boiler) proposed, which is characterized according to the invention, that at least one of its fresh air blower by at least one electric motor or electric motor generator and a back pressure steam turbine is driven. This combined drive allows the boiler to start up normally from the cold State by means of an electric motor or motor generator and normal operation high draft losses of the boiler, with simultaneous generation from electrical energy in the motor generator through counterpressure expansion of the steam, without a separate back pressure steam turbine generator being required for this purpose.

Through constructive measures (reduction of the heating surfaces; for shell boilers especially by reducing the diameter of the roller body) created the prerequisite for increasing the boiler operating pressure, whereby In addition, a reduction in costs and weight is possible.

Does the industrial boiler have a solid fuel furnace or such a one for solid and liquid or gaseous fuels, so is according to the invention at least one of its induced draft fan by at least one electric motor or electric rotor generator and a low pressure steam turbine driven. Even this solution allows the formation of a high speed boiler as well as the Generation of electrical energy with the motor generator in back pressure operation without separate back pressure steam turbine generator.

It is also of particular advantage that extremely cheap, high-speed Back pressure steam turbines with one or two Luaf blade rings can be used whose operating temperatures are below 573 K (3000C).

With shell boilers, which according to the new proposal are classified as high-speed boilers are formed, is the "cold" flue gas velocity in the at nominal load Heating surfaces at least 15 Nm / sec, but preferably 20-40 m / sec.

In the case of 1 water tube boiler, which is designed as a high-speed boiler , the "cold" flue gas speed is at least 12 Nm / sec at nominal load, but preferably 15-25 Nm / sec.

With shell boilers and water tube boilers of this new type the static draft loss on the flue gas side is at least 0.04 bar, preferably but more than 0.1 bar. These high draft losses can instead be caused by high breath gas velocities also due to the particularly small dimensions of the flue gas flow cross-sections (e.g. the heating pipe cross-sections for shell boilers) can be achieved.

If the industrial boiler is a saturated steam boiler, there is another one Feature of the invention in the water-vapor space of the shell boiler (salt body) or at least one drying area in the drum of the water tube boiler arranged, which emerges from the counterpressure steam turbine during operation Steam is flowing through it. The damp steam is in this steam dryer heating surface transformed back into saturated steam or into slightly superheated steam. By the big ones The water-side and steam-side heat transfer coefficient is the dimension of the steam dryer heating surface tiny. Every simple large water room saturated steam boiler can be equipped with such a steam dryer heating surface be equipped. The temperature gradient in this heating surface is given by that the primary saturated steam or d-as boiling water in the roller body or in the The drum has a higher boiling temperature than that coming from the back pressure steam turbine partially expanded wet steam.

A shell boiler can also have a flue gas-heated steam dryer heating surface own - which may also be designed as a superheater - the one in the boiler or one of its Nachschaltheizflächeblockblocks and arranged during operation is traversed by the steam emerging from the back pressure steam turbine.

The high air pressure of the fresh air blower (due to the drive with the counter-pressure vapor turbine) also allows the arrangement of a high-speed air heater, which enables low exhaust gas temperatures to be reached even with small heating surface dimensions (approx. 100 ° C) allowed. The high flue gas velocities reduce the corrosion problems in the air heater. Its small size also allows its manufacture from expensive corrosion-resistant Material (e.g. austenite tubes).

If the Luiterhitzer is designed as a tubular heat exchanger, then is at least the "cold" Rauchgasgeschwirldigkeit in its heating surface at nominal load 15 Wim / sec, but preferably 20-30 Nm / sec. The "cold" air speed is at least 12 Nm / sec.

In a shell boiler, the air heater is better known in @@ Arranged next to, above or below the boiler, preferably preferably its length illit the length of the Großwasserrauinkes s els corresponds or arlgenihert matches.

In the back pressure steam turbine, electric motor or

electric motor generator and fresh air or induced draft fan Blower set, the blower is advantageous between the electric motor or motor generator in turn and the back pressure steam turbine arranged on the other hand. This allows in the event of damage to one of the two drive units, another (limited) Continuation of operations.

According to a further feature of the invention is the industrial boiler for conveying the combustion air and for charging the boiler when it is fired with a compression-expansion unit (exhaust gas turbocharger of diesel engines) equipped by at least one electric motor or electric motor generator and a back pressure steam turbine is driven.

Charging to 3 - 5 bar on the firing side brings an additional one Improvement of the heat transfer conditions and thus a further reduction in required boiler heating surface. In particular, they reduce the Flame tube diameter - and thus a further increase in boiler pressure - possible. An increase in the boiler efficiency is also possible or the conditions become for the generation of electrical energy by the motor generator improved.

During operation, the gas turbine of the compressor / expansion unit is turned off from the actual boiler or its secondary heating surface block or his Nachschaltheizflächeblocks exiting flue gases acted upon.

The flue gases from the actual boiler enter the gas turbine and from this into at least one Mach pad block, this increases the possibility of generating electrical energy through the motor generator because the gas turbine of the compression-expansion unit then delivers more power than the compressor needs.

If the flue gases from the secondary heating surface block enter the gas turbine and from this via the flue gas duct into the chimney, then there is the possibility the achievement of a very high boiler efficiency without accepting corrosion problems in the boiler heating surfaces.

The exhaust gas temperature after the gas turbine can be lower at nominal load than 373 K (1000C), preferably about 353 K (80 ° C). In this case it is enough the power output of the gas turbine due to the low flue gas inlet temperature not off to cover the power consumption of the compressor. The lack of performance is applied by the back pressure steam turbine, which is also used in the motor generator additionally generated electrical energy.

To reduce the amount of combustion air conveyed at partial load of the boiler (in order to maintain near-stoichiometric combustion) the Speed of the blower unit in a manner known per se compared to the full load speed lowered. The speed change takes place advantageously by means of thyristors. Of the The electric motor or the electric motor generator is known in a manner known per se designed as a gear motor or gear motor generator, provided that the speed control using thyristors is not sufficient.

The back pressure steam turbine of the Geblj.seaggregates is during the During operation, the steam generated in the boiler flows through it in whole or in part. In this case, the counterpressure steam turbine is preferably acted upon by those withdrawn from the steam space of the shell boiler or the boiler drum Saturated steam.

In order to reduce the steam pressure in large volume boilers without adverse consequences (higher weight, higher price) becomes a decrease in diameter of the roller body proposed. A flame tube is used for this in a manner known per se symmetrically or approximately synimetrically in the vertical longitudinal plane of symmetry of the Roller body arranged. Also, only one heating tube bundle is provided, which is preferably is housed split on both sides of the flame tube (i.e. the shell boiler is a two-pass boiler).

The remaining heating surfaces (superheater, economizer) are in at least a Nachschaltheizflächenblock housed, the side or above or below the actual shell boiler is arranged. The Lfingc des Nachschaltheizflächenblockes preferably corresponds to the length of the boiler or roughly match.

To achieve short steam side, combustion air side and The flue gas-side connecting lines and ducts are used by the counter-pressure steam turbine containing blower set advantageously on or above the steam boiler and - if available - arranged in its building module. The blower set containing the back pressure steam turbine can also be arranged on a common base frame together with the boiler, which results in a very compact block construction (package construction).

In the case of steam boilers where the fresh air fan is only operated by a Back pressure steam turbine and an electric motor or

electric motor generator is driven, these three units can flanged directly to the air supply housing of the burner.

The drawings show three exemplary embodiments of the subject matter of the invention @chematically shown.

It shows: FIG. 1 a vertical cross section through a large water space boiler With side heating area block and luff as well as integrated in the roller body Steam dryer heating surface in which the fresh air fan is driven by a counter-pressure steam turbine (Sattdarnpfturbine) and an electric motor generator is driven, as a first embodiment.

Fig. 2 is an axonometric representation of the first embodiment with the arrangement of the main components and the steam dryer heating surface within the Roller body.

Fig. 3 shows a vertical cross section through a bulk water boiler with side heating area block, without air heater, in which the fresh air blower set from a compression-expansion unit, a counter-pressure steam turbine (saturated steam turbine) and an electric motor generator as a second embodiment. From The flue gases exiting the secondary heating surface block flow to the gas turbine. the Steam dryer heating surface is arranged in the secondary heating surface block and is heated by flue gases.

Fig. 4 is a vertical, burner-side front view of a shell boiler with fresh air blower set as in Fig. 3, in which the from the actual boiler escaping flue gases to the gas turbine and from there to the secondary heating surface block stream, as a third embodiment. The steam dryer heating surface is in the roller body integrated.

In the case of the one shown in FIGS. 1 and 2 as a shell boiler In the first embodiment of the invention, the roller body 1 is supported (Druckkö.rper) over the boiler chairs 2 onto the base frame 3. The roller body 1 contains water space 4 and steam space 5. In water space 4 is the flame tube 6, the split heating tube bundle 7 and the steam dryer Heating surface 8 arranged. The latter can optionally also be accommodated in the steam space 5.

In the vapor space 5, the moisture separator 9 is arranged over which the steam in the saturated steam line 10 and from this to the back pressure Danjpfturbine 11 where he partially relaxes.

The counter-pressure steam turbine 11 forms with the fresh air blower 12 and the electric motor generator 14 provided with a gearbox 13, the fresh air blower set 11/14, which is on a common support frame 15 above the boiler and its I4achschaltheizflächenblock 16 is arranged. The latter contains the two-part economizer in two flue gas flues 17th

The combustion air passes from the fresh air fan 12 via the fresh air duct 18 to the flue gas heated air heater 19 and from there via the warm air duct 20 to burner 21.

The flue gases come from the burner 21 via the flame tube 6, the flue gas turning chamber (not shown), the divided heating tube bundle 7 and the two-part economizer 17 into the air heater 19 and from there via the exhaust duct to the chimney.

The split heating tube bundle 7, the two-part economizer 17 and the Air heaters 19 are designed as hole velocity surfaces. The air heater 19 can also be integrated into the roof switching heating surface block 16.

The partially relaxed comes from the back pressure steam turbine 11 Steam, which now has a moisture content of approx. 10 percent, via the wet steam line 22 to the steam dryer heating surface 8 back into the roller body 1. In the steam dryer heating surface 8 so much heat is supplied to the steam that it is dry or slightly again becomes overheated. A special regulation is not required for this, what is called a particular advantage of this solution is to be seen. From the steam dryer heating surface 8, the steam flows via the connecting steam line 23 to the (heating) steam consumer.

The electric motor enerator 14 provides power during normal boiler operation electrical energy that it emits into the electrical network. It also serves as an electric motor for commissioning the boiler from the cold state.

For power control is between the saturated steam line 10 and the Wet steam line 22 is a motor-driven steam-side bypass valve 24 to the back pressure steam turbine 11 arranged.

in iii Fig. 5 also shown as a shell boiler The second embodiment of the subject matter of the invention comprises the fresh air blower set 11j26 except for the back pressure steam turbine 11 and the electric motor generator 14 with gear 13 still the compression-relaxation unit 25/26.

The latter consists of the compressor 25 and the gas turbine 26 and serves to charge the boiler on the combustion side in order to improve it further the heat transfer conditions, the costs, dimensions and weights of the same to reduce and increase its efficiency and its limit performance. moreover can achieve a very high level of efficiency without an air heater; will. Additionally the generation of electrical energy ii counter-pressure operation is possible.

From the compressor 25, which compresses the combustion air to 3 - 5 bar, this flows through the fresh air duct 18 to the burner 21. Both the flame tube 6, the divided heating tube bundle 7, as well as those arranged in the secondary heating surface block 16 Heating surfaces are under this pressure on the flue gas side. (The actual loss of traction in the heating surfaces it was only a few tenths of a bar.) From secondary heating surface block 1 6 the flue gases flow through the flue gas-side connecting duct 27 with a Temperature of only about 473 K (20,000) to the gas turbine, in which it is at a temperature expand from approx. 353 K (80 ° C), resulting in a very low flue gas loss of the boiler provides no corrosion problems on the flue gas side in the boiler heating surfaces.

The flue gases flow from the gas turbine 26 via the exhaust gas duct 28 to the chimney, which components are easily protected against corrosive attack can.

With the solution presented here, the power output of the Gas turbine 26 does not stop to cover the power requirement of the compressor 25, because the inlet temperature of the flue gases into the gas turbine 26 is too low. The missing Power for the compressor 25 is supplied by the back pressure steam turbine 11, which also generates electrical energy in the electric motor generator 14.

The steam dryer heating surface 8 is heated with flue gas and together with the economizer 17 in the Nachschaltheizflächenblock 16 arranged. if required this steam dryer heating surface 83 can also be designed as a superheater.

In the case of the boiler shown in FIG. 4 as a large water tank The third embodiment of the device is the fresh air blower set 11/26 identical to that of the second embodiment. The difference, however, is in its flue gas control.

In this solution, only the heating surfaces arranged in the roller body 1 are available On the flue gas side under a charge pressure of 3 - 5 bar, the heating surfaces of the secondary heating surface block 16 are (almost) under atmospheric pressure.

From the flue gas chamber 29 on the furnace-side face of the Roller body 1, the flue gases flow at a temperature of approx. 973 K (70,000) via the connecting duct 27 on the smoke gas side to the gas turbine 26, where they expand. The flue gases flow from the gas turbine 26 at a temperature of approx.

773 K (500 ° C) via the turbine exhaust duct 30 to the secondary heating surfaces in the I1achschaltheizflächenbock 16 where it continues to an exhaust gas temperature of approx. 453 K (180 ° C).

All heating surfaces are designed as high-speed heating surfaces.

This solution does not allow an extremely low exhaust gas temperature to achieve at the boiler, but it brings a particularly high generation of electrical Energy and, moreover, a small and cheap boiler system.

In this solution there is again a steam dryer heating surface integrated in the roller body 1 8 provided for the wet steam emerging from the back pressure steam turbine 11.

For those in the second and third embodiment of the subject invention Compression-relaxation units 25/26 that are to be used are expedient Exhaust gas turbochargers used for diesel engines, which are available in series on the market are.

The remaining components of Fig. 3 and Fig. 4 are illit the Components of Fig. 1 and Fig. 2 match if their item numbers are the same are.

L e r s e i t e

Claims (30)

t a t e n t a n s p r ü c 1l e 1. Industrial steam boiler, trained as a shell boiler or as a water tank, characterized in that at least one of its fresh air blowers (12) by at least one electric motor or electric motor generator (14) and a back pressure steam turbine (11) driven is. 2. Industrial steam boiler, designed as a shell boiler or as a water boiler, with a furnace for solid uiid / or liquid and / or gaseous Fuels, characterized in that at least one of its induced draft fans by at least one electric motor or electric motor generator (14) and one Back pressure steam turbine (11) is driven. 3. Industrial boiler according to claim 1 or 2, characterized in that that in normal operation - but at least at nominal load - in the motor generator (14) electrical energy is generated and from this ii the electrical network is output. 4. Shell boiler according to claim 1 or 2, characterized in that that it is designed as a high-speed boiler, in its heating surfaces at Nerin load a "cold" breath gas speed of at least 15 Nm / sec, preferably but there is a rate of 20-4 ¢ Nm / sec. 5. Water tube boiler according to claim 1 or 2, characterized in that that the same is designed as a high-speed boiler, in the heating surfaces at nominal load a "cold" flue gas speed of at least 12 Nm / sec, preferably but this is 15-25 Nm, sec. 6. Industrial boiler according to claim 1 or 2, characterized in that that the static draft loss b @ i nominal load on the flue gas side is at least 0. u4 bar, preferably but is more than 0.1 bar. 7. Industrial steam boiler, designed as a shell boiler or Water tube boiler, the steam of which is partially in at least one counter-pressure steam turbine is relaxed, characterized in that in the water-steam space (4/5) of the shell boiler or in the ironmiel of the water tube boiler at least one steam dryer heating surface (8) is arranged, which during operation of the from the back pressure steam turbine (11) escaping steam is flowed through. 8. Shell boiler, the steam in at least one counter-pressure steam turbine is partially relaxed, characterized in that it has at least one flue gas heated Has steam dryer heating surface (8) in the boiler or in one of its secondary heating surface blocks (16) arranged and during operation of the back pressure steam turbine (11) flowing through the exiting D.unpf, where appropriate ils superheater is trained. 9. Industrial boiler according to claim 1 or 2, characterized in that that it has at least one designed as a high-speed heat exchanger Lufterhitzct '(19) is removed, in whose heating surfaces a "cold" Flue gas speed of at least 15 Nm / sec, but preferably such a speed of 20 - 30 Nm / sec prevails. 10. Industrial boiler according to claim 1 or 2, characterized in that that it is equipped with at least one air heater (19) in its heating surfaces at nominal load there is a "cold" air speed of at least 12 Nm / sec. 11. Shell boiler according to claim I or 2, and according to claim 9 and / or 10, characterized in that the air heater (19) is known per se Neise next to, above or below the boiler is arranged, preferably its Length corresponds or approximately corresponds to the length of the shell boiler. 12. Industrial boiler according to claim 1 or 2, characterized by gekenrizeichnet, that the fresh air fan (12) or the induced draft fan between the electric motor or eiektjischen motor generator (14) on the one hand and the counter pressure Dc-l.lllpftur (11) is arranged on the opposite side. 13. Industrial boilers, designed as shell boilers or water tube boilers, characterized in that for promoting the combustion air and for the fire side At least one compression-relaxation unit (25/26) is provided for charging the boiler is that by at least one electric motor or electric motor generator (14) and a back pressure steam turbine (11) is driven. 14. Industrial boiler according to claim 13, characterized in that in normal operation - but at least at nominal load - electrical in the motor generator (14) Energy is generated and fully discharged into the electrical network. 15. Industrial boiler according to claim 13, characterized in that during operation the gas turbine (26) of the compression-expansion unit (25/26) in a manner known per se from the deln boiler or its Nachschaltheizflächenblock (16) or its Nachschaltheizflächeblocks exiting smoke gases acted upon will. 16. Industrial boiler according to claim 13, characterized in that during operation from the gas turbine (26) of the compression-expansion unit (25/26) escaping smoke gases in a manner known per se in at least one Nachschaltheizflächenblock (16) of the boiler flow. 17. Industrial boiler according to claim 13, characterized in that during operation from the gas turbine (26) of the compression-decompression unit (25/26) escaping flue gases flow through the flue gas duct (28) to the chimney. 18. Industrial boilers according to Part 13 and 17, thus marked, that the outlet temperature of the flue gases at the gas turbine (26) of the compression-expansion unit (25/26) at nominal load is less than 373 K (1000C), preferably about 353 K (8000). 19. Industrial boiler according to claim 1 or 2 or 13, characterized in that that in a known manner the speeds of the blower unit (fresh air blower unit 11/14 or 11/26 or induced draft fan unit) are lower for partial loads than at full load. 20. Industrial boiler according to claim 1 or 2 or 13, and according to claim 19, characterized in that the speed change of the electric motor or electric motor generator (14) in a manner known per se by means of thyristors he follows. 21. Industrial boiler according to claim 1 or 2 or 13, characterized in that that the electric motor or clever motor generator (14) in a known manner is designed as a gear motor or gear motor generator. 22. Industrial boiler according to claim 1 or 2 or 13, characterized in that that the back pressure steam turbine (11) in a manner known per se for the whole or in part steam generated by the boiler flows through it. 23. Industrial boiler according to claim 1 or 2 or 13, as well as according to claim 22, characterized in that ile counterpressure steam turbine (11) during operation from that withdrawn from the steam chamber (5) of the boiler or from the steam chamber of the boiler drum Saturated steam @ is applied. 24. Industrial boiler according to claim 1 or 2 or 13, designed as Shell boiler, characterized in that in a known Neise im Roller body (1) in flame tube (6) symmetrically or approximately symmetrically to the vertical Is arranged longitudinal symmetry plane of the roller body (1) 25. Industrial boiler after Claim 1 or 2 or 13, designed as a shell boiler, characterized in that that it is designed in a manner known per se as a two-pass boiler and only one Ileizrohrbündel (7), which is preferably divided on both sides of the flame tube (6) is housed. 26. Industrial steam boiler according to claim 1 or 2 or 13, formed as Shell boiler, characterized in that in a per se known [{eise svenigstens a Nachschaltheizflächenblock (16) on the side or above or below the actual Shell boiler is arranged, whereby the length of the roof heating area block (16) corresponds or approximately corresponds to the length of the boiler. 27. Industrial steam boiler according to claim 1 or 2 or 13, and according to Claim 26, characterized in that at least one superheater in a secondary heating surface block (16) is arranged. 28. Industrial steam boiler according to claim 1 or 2 or 13, characterized in that that at least one blower set containing a back pressure steam turbine (11) (fresh air blower set 11/14 or 11/26 or induced draft fan set) on or above the steam boiler and / or ropes construction module is arranged. 29. Industriedarnpfkesse1 according to Claim 1 or 2 or 13, characterized in that that at least one blower set (fresh air blower) containing a back pressure steam turbine (11) set 11/14 or 11/26 or induced draft fan set) together with the boiler on one common base frame (3) is arranged. 30. Industrial steam boiler according to claim 1 or 2, characterized gekennzei.cilulet, that the back pressure steam turbine (11) together with the fresh air blower (12) and the electric motor or electric motor generator (14) directly on the air duct housing of the burner (21) is arranged.