DE102008058736B3 - Method for operating gas network, involves variably activating gas network pressure depending on evaluation criterion, where variation of gas network pressure takes place by pressure-regulating plant - Google Patents

Abstract

The method involves variably activating the gas network pressure depending on an evaluation criterion. The gas network pressure is variably activated by a pressure controlling plant (6) for transmission of signals in a gas supply network (1) between components of the gas network for locking and increasing the gas feeding and gas receiving. The gas network pressure is variable activated depending on an evaluation criterion. The variation of the gas network pressure takes place by the pressure controlling plant.

Description

The The invention relates to a method for operating a gas network according to the preamble of claim 1.

STATE OF THE ART

• – Der Verbrauch der Verbraucher unterliegt langfristigen, mittelfristigen und kurzfristigen dynamischen Änderungen, die beispielsweise jahreszeitbedingt oder tageszeitbedingt sind und von der Außentemperatur abhängen können;
• – Die Bereitstellung von Gas von der Erdgasquelle kann variieren hinsichtlich der Volumenströme und des Preises;
• – Lokale Gaseinspeiser können ergänzend zu dem konventionellen Gasbezug aus einer Gasquelle Gas in das Gasnetz, beispielsweise im Mitteldruckbereich, einspeisen.

In known gas networks, a gas volume flow, for example, from a (natural) gas source via a high pressure line and a branch point, a medium pressure range, possibly with industrial consumers, and a low pressure range consumers supplied. Ensuring the supply of gas to consumers is particularly subject to the following conflict:

• - Consumption by consumers is subject to long-term, medium-term and short-term dynamic changes, such as seasonality or time of day, which may depend on the outside temperature;
• - The supply of gas from the natural gas source can vary in terms of volume flows and price;
• - Local gas feeders can in addition to the conventional gas supply from a gas source gas in the gas network, for example in the medium-pressure range, feed.

The explained Stress field requires a complex control of the gas flows in the Gas network, in particular the feed from the natural gas source via the High-pressure line, the removal by the consumer and the feed local feed. For Such a regulation is used by control devices which are to supply comprehensive state variables. A regulation of a feed of a local gas feeder is only conditionally possible for example, biogas plants used as decentralized gas feeders only over the long term Days or weeks influenced by the gas yield of the same are. More short-term arrangements can be made by using a storage element, For example, in the form of a gas bubble, realized. In doing so, the advancement of the gas first into the gas bubble and a regulation of the feed into the gas network over a controlled withdrawal from the gas bubble.

• – Entspricht der in dem Verbraucherbereich verbrauchte Gasvolumenstrom dem durch den Hochdruckbereich bereitgestellten Volumenstrom, wird der passende Volumenstrom unmittelbar über ein Direktentnahmeventil durch die Regeleinrichtung hindurchgeleitet.
• – Überschreitet der Verbrauch des Gases in dem Verbraucherbereich einen vorgegebenen maximalen Gasvolumenstrom, so drosselt das zwischen Hochdruckbereich und Verbraucherbereich zwischengeschaltete Direktentnahmeventil den Volumenstrom auf den vorgegebenen maximalen Volumenstrom. Infolge des erhöhten weiteren Verbrauchs von Gas im Verbraucherbereich fällt stromabwärts des Direktentnahmeventils der Druck in der Regeleinrichtung ab. Dieser verbrauchsabhängige Druckabfall wird durch einen Drucksensor erfasst, dessen Ausgangssignal einem Rechner zugeführt wird. Der Rechner öffnet in diesem Fall ein Speicherentleerungsventil, über welches ein Pufferspeicher ergänzend Gas in den Verbraucherbereich einspeisen kann. Damit wird für diese Betriebsbedingungen kumulativ der Verbraucherbereich über den Hochdruckbereich und den Pufferspeicher gespeist.
• – Liegt hingegen der verbrauchte Gasvolumenstrom unterhalb des maximal aus dem Hochdruckbereich zu entnehmenden vorgegebenen Gasvolumenstrom, wird zwischen Hochdruckbereich und Verbraucherbereich eine Entspannungsturbine zwischen geschaltet, über deren Ausgangsleistung ein Kompressor betreibbar ist, welcher – neben der Bereitstellung des verringerten Gasvolumenstroms für den Verbraucherbereich – einen Gasvolumenstrom verdichtet, mit welchem dann der Pufferspeicher gefüllt werden kann.

Out DE 35 05 320 C2 a gas network is known, in which between a high-pressure area and a medium or low pressure area (hereinafter also "consumer area") a control device is interposed. The control device has different operating states:

• If the gas volume flow consumed in the consumer area corresponds to the volume flow provided by the high-pressure area, the suitable volume flow is led directly through a direct-draw valve through the control device.
• If the consumption of the gas in the consumer area exceeds a predetermined maximum gas volume flow, then the direct sampling valve interposed between the high-pressure area and the consumer area throttles the volume flow to the predetermined maximum volume flow. As a result of the increased further consumption of gas in the consumer area, the pressure in the control device drops downstream of the direct draw valve. This consumption-dependent pressure drop is detected by a pressure sensor whose output signal is fed to a computer. The computer opens in this case, a memory drain valve, via which a buffer memory can additionally feed gas into the consumer area. Thus, for these operating conditions, the consumer area is cumulatively fed via the high-pressure area and the buffer memory.
• If, on the other hand, the consumed gas volume flow lies below the maximum gas volume flow to be taken from the high-pressure area, an expansion turbine is interposed between the high-pressure area and the consumer area, via the output power of which a compressor can be operated, which compresses a gas volume flow in addition to providing the reduced gas volume flow for the consumer area , with which then the buffer memory can be filled.

About the It should be possible to control the volume of the Buffer memory comparatively low, because the gas fed via the compressor the pressure in the high pressure area can be compressed out. hereby more gas can be stored in the cache. In summary It should be noted that in the known from the publication control device a regulation of an injection from a buffer memory in accordance with a Pressure occurs due to the withdrawn volume flow in Consumer area results.

Further prior art is out DE 100 18 612 C1 . DE 638 801 A . DE 372 396 A . DE 693 13 230 T2 . EP 1 777 389 A2 . EP 0 074 267 B1 . US 2008/0115840 A1 . US 73 74 941 B2 . US 2006/0278276 A1 . US 2005/0145018 A1 . US 2003/0196660 A1 . US 64 60 565 B1 . US 30 62 271 A and Ullmann's Encyclopedia of Industrial Chemistry, 4th ed., Volume 10; Verlag Chemie GmbH; in: Weinheim; 1975; Pp. 605-611.

OBJECT OF THE INVENTION

The present invention is based on the object, a method for operating a gas propose network in which a simple communication between components of the gas network is possible, in particular a simple control of the components of the gas network is possible.

SOLUTION

The The object of the invention according to the invention with a method with the Characteristics of the independent Patent claim 1 solved. Further embodiments of the invention will become apparent accordingly the dependent claims 2 to 21.

DESCRIPTION OF THE INVENTION

Of the The prior art mentioned at the beginning is based on the basic idea that on the consequences of a change Gas extraction of at least one gas consumer in the form of a pressure drop downstream a direct-acting valve to respond with the single goal for one to a maximum limited feeding gas flow from one High-pressure range different, even exceeding this maximum Gas volume flows too to ensure consumers. On the other hand, the invention does not go the new way, the gas network itself only for the provision of the gas for the To use the gas network rather than a kind of "signal path". This is done by over a suitable control device according to the invention, the gas network pressure actively varies becomes what basically independently can be done from a gas flow just taken. Since that Gas network anyway connected to the individual components of the gas network is, a transfer takes place of the actively varied gas network pressure under certain circumstances without further additional expenditure between the components of the gas network. The components of the gas network can then "evaluate" the active variation of the gas network pressure or into an appropriate action for which the active variation of the gas network pressure so by the control device is that this with a predetermined meaning correlated. Here is the transmission any signals over the gas network pressure possible, whereby the variation can take place in the long, medium or short term, for example in the form of pressure pulses, stepped pressure changes, Oscillations of pressure with constant or varying frequency or with ramp-like pressure changes, being for the pressure transmission the topology of the gas network is to be considered, which, for example, unsteady, sudden pressure changes in steady pressure changes transforms.

In a sense, the invention is a transmission of features of a known design of power grids, for which it is known to use the power not only for electrical power supply, but via a modulation of the electrical quantities in the power network complementary signals to consumers connected to the mains and / or feeders (cf. WO 2008/049556 A1 ).

Preferably the variation of the gas network pressure takes place in the time domain of minutes, especially 2 to 20 minutes or 5 to 15 minutes. This embodiment is based on the knowledge that shorter times u. U. technical hard to realize and longer Times energy wise do not make sense.

In Further embodiment of the method according to the invention, the transmission takes place a special signal over the active variation of the gas network pressure, namely a signal to control or Regulation (hereinafter "regulation") of the gas supply at least one gas feeder and / or a gas extraction at least a gas consumer. This is done in a control device Gas network pressure depending varies actively from one evaluation criterion. For the choice of the evaluation criterion there are many meaningful possibilities.

For example the evaluation criterion can be a kind of "oversupply" (or signal a kind of "undersupply"), for which currently or for the future is indexed that a provided gas volume flow is larger (or less) than a current or expected gas flow rate for the Gas withdrawal by consumers. By suitable variation of the Gas net pressure can be such an "oversupply" (or "undersupply") to the Components of the gas network are signaled, which then measures to eliminate the "oversupply" (or "undersupply") can, in particular in a reduction of gas feed through at least one gas feeder and / or increasing the gas extraction by at least one gas consumer (or increasing the gas supply by at least one gas feeder and / or reduction of gas withdrawal by at least one gas consumer) exist. An exemplary another evaluation criterion can be cost-based. So can at temporary increased Gas prices for a removal from the high-pressure area via a variation of the gas network pressure in the middle or Low pressure range are signaled to the local gas feeders, that a reinforced Infeed desired is to supply at least partially from the high pressure area to relocate to local feeders.

According to another proposal, the gas network pressure according to the invention in a Toleranzbe varies between a lower threshold and an upper threshold, said thresholds being constant or depending on other operating parameters. For example, the thresholds can ensure proper operation and supply of gas consumers. Between the mentioned threshold values, the gas network pressure can be varied as desired, in particular continuously or in stages, for example with three stages with the lower threshold value, an average value and the upper threshold value or in an extreme case also as type two-position controller with the two limit values.

In Further embodiment of the method according to the invention is proposed that the variation of the gas network pressure via a gas pressure regulating system he follows. This can be in the medium pressure range or low pressure range be arranged. Preferably, the gas pressure regulating system is in the transition region between provided individual pressure ranges. For example, the gas pressure regulator in the transition area be arranged from the high-pressure region to the medium-pressure region, for example about a pressure control or a flow control.

A special further embodiment of the method according to the invention is given when using the variation of gas network pressure a gas expansion engine, in particular an expansion turbine or a Gasentspannungs- or piston engine (see, for example, www.spilling.de/produkte_gasexpansion.php) or equivalent facilities in which a conversion between takes place a pressure in another form of energy takes place, which for example, in the transition area from the high pressure area to the medium pressure area. In the case of the use of a piston engine is advantageous that when fluctuating Flow higher Efficiency can be achieved even in a partial load range.

• – eine Gaseinspeisung aus dem gefüllten Speicherelement erfolgen kann, auch wenn keine Gasproduktion durch den Gaseinspeiser erfolgt, oder
• – die Gasproduktion des Gaseinspeisers dem Speicherelement zugeführt wird, während keine Gaseinspeisung in das Gasnetz erfolgt.

Another aspect of the invention is concerned with the type of dimensioning of a gas feed of at least one gas feeder taking into account the varied gas network pressure. While an adjustment of the gas production of the gas feeder itself is basically possible, a change in this gas production may only be possible in the long term. The invention proposes to associate with the gas feeder a storage element, for example a gas bubble. The storage element is a kind of buffer element with a storage volume filled with the gas. The direct connection between the volume flow of the gas production of the gas feeder and the gas feed of the gas feeder into the gas network can be decoupled via the storage element, in an extreme case

• A gas feed can take place from the filled storage element, even if no gas is produced by the gas feeder, or
• - The gas production of the gas feeder is supplied to the storage element, while no gas is fed into the gas network.

Between these extreme cases are any operating conditions possible. Ultimately, by appropriate reduction or increase in the Withdrawal from the storage element the volume flow of the gas feed increased in the gas network or reduced, causing load peaks of the gas network be compensated. This can also be done in a relatively short time Time range for which a variation of the gas production of the gas feeder would not be possible.

One Another proposal of the invention extends this idea on the at least one gas consumer. Accordingly, it is proposed that the gas consumer is assigned a memory element, via which the gas extraction of the gas consumer from the gas network of the consumption the gas is at least temporarily decoupled by the gas consumer becomes.

For example It can thereby be made possible for a gas consumer, the gas network priority or only at times with a reduced withdrawal price To take gas flow. Besides the possibility of the memory element to run as gas storage, can also be a memory for Final energy can be used, such. A thermal buffer, after the conversion of chemical energy into heat energy is arranged.

In order to be able to predict the reaction of gas feeders and gas consumers to an active variation of the gas network pressure and thus to determine a dimensioning of a required level of variation of the gas network pressure, a further method according to the invention uses a model in which, depending on the gas network pressure (and under certain circumstances further operating parameters) the change in the gas feed of at least one gas feeder and / or the change in the gas take-off of at least one gas consumer is modeled. To name just a simple example here, it can be stored in the model that a change in the gas network pressure by a pressure difference Δp ₁ results in the volume flow being increased by an amount ΔV. ₁ due to modified gas supply and / or removal changes. This has the advantage that the control device from a current or future required change in the volume flow using the model, the required change of the gas network pressure Δp ₁ can determine.

Ideally, as many variables as possible are detected in the gas network, in particular gas volume flows and / or gas pressures. The gas network is usually a complex fluid dynamic system, for example. With storage tanks, throttles, shut-off valves, long tubular conduit connections and the like. Therefore, strictly speaking, the detection of the gas flow rates and the gas pressures at a plurality of different locations of the gas network is required. If, for reasons of cost, only a small number of measuring locations and measuring sensors are desired, the invention proposes that actually relevant, but not metrologically detected, gas volume flows and / or non-measured gas pressures be approximated by a simulation using an observer. Here, an observer system with a Luenberger observer and a node load observer can be used. Further details on the realization of such an observer can the article
"Process-accompanying simulation of a gas distribution network with incomplete measurement infrastructure", Hans-Peter Beck, Cathrin Schröder and Ernst-August Wehrmann in Gas Natural Gas GWF, No. 2, 149 (2008), pp. 106-112 and the references cited in this article
be removed.

For another Embodiment of the method according to the invention takes place in a regulation of the gas supply of at least one gas feeder besides the consideration the gas network pressure in addition a consideration the degree of filling a memory of the gas feeder and a feed characteristic. For example, the regulation of the presetting of the gas network pressure may be stronger or follow faster when the storage element of the gas feeder a high degree of filling while, while an infeed under circumstances too decrease if the filling level the storage element of the gas feeder is reduced. Next can the scheme is a forecast for take into account a gas yield of the gas feeder that may depend from the available Starting materials (quantity, quality the feedstock) and the operation management in the fermenter.

Also possible is that a regulation of the gas pressure taking into account a characteristic that's a change the variation of the volume flow dV. depending on a change the gas network pressure dp, which is a map, Characteristics or more complex dependencies, also from other company sizes, act can.

A Such dV ./dp characteristic can in particular from the outside temperature and / or a temporal information. Here, the Forecast based on season cycles, for example with a increased Retrieving a gas-based heating capacity in winter compared to Summer, and / or based on weekly Cycles of heating capacity and / or hot water demand with the distinction from weekday and weekend or on daily fluctuations. Likewise, the prognosis can be based on those gained in the past Experience. Also possible is a forecast for the consumer, which can lead to pressure fluctuations.

Is possible, that's carrying the variation of the gas network pressure, in particular the appropriate design a necessary change of gas network pressure to effect a desired one Effect, taking into account a simulation takes place. This can, for example, under consideration dynamic components of the gas network, the effect of a variation the gas network pressure Δp on a change the gas volume flow .DELTA.V. simulate. Possible is also that in this case resorted to in the past collected data becomes.

Farther It is proposed that in the method according to the invention for the simulation the infrastructure of the gas network with its gas-dynamic characteristic Properties considered becomes.

The Advantages of features mentioned in the introduction to the description and combinations of several features are merely exemplary and can alternatively or cumulatively, without the benefits mandatory of embodiments of the invention must be achieved. further explanation are the drawings - in particular the illustrated geometries and the relative dimensions of several Components to each other and their relative arrangement and operative connection - refer. The combination of features of different embodiments the invention or features of different claims also different from the selected ones The antecedents of the claims possible and is hereby stimulated. This also applies to such features are shown in separate drawings or in their description to be named. These features can be combined with features of different claims. As well can in the claims listed Features for further embodiments the invention omitted.

BRIEF DESCRIPTION OF THE FIGURES

In the following, the invention will be described with reference to FIG The figures illustrated preferred embodiments further explained and described.

1 shows a schematic representation of a gas network, which can be operated by the method according to the invention.

2 shows a schematic block diagram with method steps of a method according to the invention for operating a gas network with a default of a gas network pressure by a pressure control system.

3 shows a schematic block diagram with method steps of a method according to the invention with a determination of a target specification for a feed-in at a local gas feeder.

DESCRIPTION OF THE FIGURES

1 schematically shows a gas network 1 , In the gas network 1 there is a provision of a gas, in particular from a gas source, via a transport network or a high-pressure line 2 , with a high-pressure area 3 is formed.

Via one of several branching points 4 of the high pressure area 3 feeds the high pressure area 3 a medium pressure range 5 , Between high pressure area 3 and medium pressure range 5 is a pressure control system 6 interposed over the passage of gas from the high pressure area 3 to the medium pressure range 5 is controllable. For example, it is in the pressure control system 6 around a regulated throttle valve or a gas expansion engine 7 , For an extended embodiment, the pressure regulator 6 additionally via a regenerative compressor 8th have a return of gas from the medium-pressure range 5 in the high pressure area 3 by raising the pressure level is possible.

About further branching points 9 are at the medium pressure range 5 several pressure control systems of local network stations 10 tethered. Also via branching points 9 to the medium pressure range 5 Tailored are special contract customers 11 , which are, for example, industrial consumers, which refer to gas at medium pressure level. Furthermore, via a branch point 12 the medium pressure range 5 with the interposition of an overfeed device 13 with another subnet 14 , preferably the same pressure range, be connected. After the local network stations 10 This is followed by a low pressure area to which in particular several (small) consumers or households are connected. To name just one example, in the high-pressure range, the gas may be present at a pressure of 40 to 80 bar, gas in the medium-pressure range of 4 to 20 bar, and gas at a pressure of 0.2 to 1 bar in the low-pressure range Pressure ranges may vary depending on the operator.

• – die Überspeiseeinrichtung 13 mit zugeordnetem Teilnetz 14,
• – die Ortsnetzstationen 10 mit zugeordneten einzelnen Verbrauchern und/oder
• – die Sondervertragskunden 11.

gas consumers 15 in the sense of the present invention are in particular

• - the overfeed device 13 with assigned subnet 14 .
• - the local network stations 10 with associated individual consumers and / or
• - the special contract customers 11 ,

An infeed into the medium pressure range 5 usually takes place on a large scale with large volume flows through the pressure control system 6 making it a global gas feeder 16 forms.

Furthermore, there is a local gas feed through several local gas feeders 17 in which it is biogas plants for the illustrated embodiment 21 is. These are with a fermenter 18 for the required fermentation processes, a post-fermentation facility 19 and a digestate warehouse 20 formed in a conventional manner. It is possible that the biogas plant 21 not only or constantly feeds biogas in the gas network, but temporarily or partially otherwise converts the biomass into energy. The biogas plant 21 has at least one storage element 22 , in particular a gas bubble 23 , The gas yield of the biogas plant 21 will be in the gas bubble 23 cached and can, depending on need and regulation via a treatment plant 24 and a compressor 25 in the gas network 1 , here the medium pressure range 5 to be fed. The processing plant 24 is used, for example, to eliminate unwanted CO ₂ contained in the raw biogas and / or to eliminate unwanted harmful gases and particles in the raw biogas and to ensure the desired calorific value. A control device 26 the biogas plant 21 becomes a pressure signal 27 fed, which is one in the medium pressure range 5 , preferably immediately adjacent to the biogas plant 21 , arranged pressure sensor is detected. Furthermore, the control device 26 a memory state signal 28 which provides information about the filling state of the storage element 22 or the gas bubble 23 gives. The control device 26 determines a control signal 29 , which is a control input of the compressor 25 is supplied.

In a particularly simple embodiment of the method according to the invention, the pressure control system 6 operated such that there is a variation of the gas network pressure in the medium-pressure region 5 results in, for example, a reduction of the gas network pressure for the purpose of providing a signal that a current or future gas shortage in the Mit teldruckbereich 5 looming. Such a reduction of the gas network pressure can be detected on the one hand by the consumers who can restrict the consumption of gas. On the other hand, the reduced pressure signal 27 the control device 26 fed, which is a control signal 29 generated, which on an increase of the feed of the local gas feeder 17 is aligned, for example, via an increase in the speed of the compressor, so that a gas bubble 23 the biogas plant 21 can be increasingly emptied.

In an increased level of detail, method steps of a possible method according to the invention are shown in the block diagram according to FIG 2 schematically shown: In this case, the in 2 In particular, the method illustrated is the default of a suitable varied gas network pressure downstream of the pressure control system 6 through the pressure regulator 6 with associated control device.

In one process step 30 takes place at any location of the medium pressure range 5 downstream of the pressure control system 6 a detection of a pressure via a sensor, wherein - as already mentioned - using an observer, a pressure not measured at a desired location can be approximated.

Furthermore, in a parallel process step 31 a detection of the gas volume flow V, in particular immediately adjacent to the pressure control system 6 or at any other measuring point.

In one process step 32 are first in the process steps 30 and 31 recorded state variables, here the gas network pressure p and the gas flow V, for a representative period, for example, a daily, weekly, monthly and / or annual cycle, stored, which can also be detected over several such cycles. From the stored data, a map is then created, which is preferably a map dV ./dp. In addition, such a map may depend on a time of day, a day of the week (weekday / weekend) and / or a season and a temperature. To give just an example, from such a map, also under suitable interpolation between suitable adjacent values, it can be determined how the volume flow as a function of a change in the gas network pressure in the past depends on the time of day, the day of the week, the season and / or the outside temperature has changed what the stored data is used for. Based on historical data, it is already possible to predict the pressure difference through the pressure control system using the characteristic map mentioned above 6 is to be specified if a nominal change for the change in the volume flow dV. is desired.

This dependency, which is based on historical data, is as a result 33 a process step 34 fed.

In a parallel process branch are in one process step 35 Data used, on the one hand, the dynamic feed behavior of a gas feeder, so describe a change in the feeding gas flow rate in response to a pressure change. On the other hand, data on the dynamic consumer behavior are used, which can describe a change in the gas sampling volume flow as a function of a predetermined pressure change.

Furthermore, in one process step 36 Data regarding the infrastructure of the gas network, so for example. To topology, roughness, the flow resistance, the length of the piping, throttle characteristics, storage volumes and the like, determined.

The results in the form of in the process steps 35 . 36 The data obtained becomes a procedural step 37 in which a predictive simulation of the fluidic conditions in the gas network 1 he follows. The aim of this simulation is the anticipation of the effect of a pressure change Δp on the gas volume flow ΔV .. Also on this branch of the method thus becomes a result 38 determines which in itself would already allow the prediction of which pressure change through the pressure control system 6 is to control a desired change in the gas flow rate .DELTA.V. to reach.

In the process step 34 will then be out of the results 33 . 38 an improved result 39 determined, for example, by weighting the results 33 . 38 or evaluation or correlation of the results 33 . 38 , The improved result 39 thus contains for a desired change in the gas flow rate .DELTA.V. a good approximation of the required pressure change Δp. The new pressure setpoint becomes a procedural step 40 fed in which the pressure control system 6 is properly controlled to bring about the desired variation of the gas network pressure. This can be done, for example, by presetting the pressure control valve or suitable moment application and acceptance on a gas expansion machine of the pressure control system 6 respectively.

For carrying out the method steps according to 2 can the pressure regulator 6 have a suitable CPU or control unit, in which the evaluation of the signals and data takes place, wherein the control unit is a suitable interface for the drove the signals from the addressed sensors owns. It is also possible that such a control unit directly to the pressure control system 6 is arranged.

3 shows a block diagram for determining a target input for a feed-in power at least one local gas feeder:
In one process step 41 there is a measurement of the gas network pressure, preferably in the region of a local gas feeder 17 associated feed-in node or elsewhere using an observer. In this case, the measurement of the gas network pressure takes place in particular continuously.

With the detected gas network pressure is in one step 42 a map created or adapted, which represents the gas network pressure present in the gas network as a function of other state variables, in particular the day and season, the day of the week and the outside temperature.

Parallel to this, in one process step 43 a forecast for the gas yield of the local gas feeders 17 created in a coming period, which can be timed triggered. This forecast includes in particular the gas yield of the biogas plant 21 without consideration of a storage effect of a memory element 22 or a gas bubble 23 ,

The results of the process steps 42 . 43 become a procedural step 44 fed. In the process step 44 the parameters of a feed-in control are determined. These include a set flow for the feed from the biogas plant 21 associated memory element 22 depending on the predicted gas yield of the local gas feeders 17 assuming the usual pressure profiles for the day and season, the day of the week and the outside temperature. In this case also the current degree of filling of the memory element 22 considered. Result of the process step 44 is preferably a characteristic field or a feed-in characteristic 45 , which may be a standard volume flow / pressure map.

In one process step 46 becomes the degree of filling of the memory element 22 determined, which on the one hand the process step 44 is supplied and on the other hand, a process step 47 ,

Input signals for the method step 47 are next to the degree of filling of the memory element 22 in the process step 41 recorded gas network pressure and the feed characteristic 45 , In the process step 47 the target specification for the feed-in capacity is the filling level, the gas network pressure and the feed-in characteristic 45 or the standard volume flow / pressure characteristic map.

In a subsequent process step 48 then takes place a regulation of the local gas feeder 17 on in the process step 47 Determined target specification. For example, a corresponding control of the speed of the compressor 25 take place, one stroke of the compressor 25 or the control of a variable frequency drive of the compressor 25 ,

In Future is reinforced Expansion of biogas plants to expect, in which usually the biogas is not converted into electricity at the place of production. In the absence from cheap to be opened heat sinks near the biogas plant is transported to the biogas produced there, where there is in cogeneration can be utilized with high overall efficiency. The material Transport of biogases is energetically cheaper and technical less expensive as that of electricity and heat. In addition to the construction of gas networks with the supply of biogas Biogas plants offer a treatment of biogas to natural gas quality and a Feed into a natural gas network to the existing infrastructure of natural gas transport. The feed is usually occur in the distribution networks, since plants for the production of biogas because of the catchment area of the needed Biomass substrate will not grow indefinitely. According to the invention, it is proposed For example, the feed of a biogas generator with a to raise falling gas network pressure at the feed-in node. This is possible because the storage bubble of the biogas plant the further use of the Production of biogas decoupled by the biogas plant. A feed compressor could in such a case at night with little gas sales and higher pressure throttled while running the feed compressor during the day with Full load can push the contents of the storage element into the gas network.

Of the Gas network operator can over the load-dependent change of the gas network pressure by means of the gas pressure regulator or gas expansion machine the passages from one pressure level to the next lower one Pressure level on the pressure level in the downstream pressure stage actively influence to take. This can be done without the need for an additional Communication infrastructure decentralized gas feeders of grid or operator side.

Since the gas network pressure in piping systems of the same pressure level is not constant, but varies depending on the network topology and consumer structure, it makes sense for a more accurate estimation of the pressure change effect at the feed point of the local gas injector by a control pulse to carry out a calculation on the gas pressure regulating system. As a rule, gas networks are only very roughly measured. With a known configuration of the gas network, however, a sturdy result with regard to the condition of the gas network can be determined even with incomplete measurement infrastructure by disturbance observers. The method described can be used with feeders as well as consumers, which regulate a fed or related (standard) volume flow as a function of the gas network pressure.

The influence of the gas volume flow can be used to a defined stroke .DELTA.V. as "control energy" to generate in the gas network. On the other hand, a maximum gas volume flow V. _max , which should not be exceeded in order to limit the peak load in the considered subnetwork.

1

gas network

2

High-pressure line

3

High pressure area

4

branching point

5

Medium pressure range

6

Pressure Control System

7

Gas expansion machine

8th

Recovery compressor

9

branching point

10

Local network stations

11

Special contract customers

12

branching point

13

About feeder

14

subnet

15

gas consumers

16

global Gaseinspeiser

17

local Gaseinspeiser

18

fermenter

19

Nachgärungseinrichtung

20

digestate

21

biogas plant

22

storage element

23

gas bubble

24

processing plant

25

compressor

26

control device

27

pressure signal

28

Storage state signal

29

control signal

30

step

31

step

32

step

33

Result

34

step

35

step

36

step

37

step

38

Result

39

improved Result

40

step

41

step

42

step

43

step

44

step

45

feed-in

46

step

47

step

48

step

Claims (21)

Method for operating a gas network ( 1 ) with components such as a high pressure area ( 3 ), a branch point ( 4 ), a medium pressure range ( 5 ), a gas expansion engine ( 7 ), a recovery compressor ( 8th ), Local loop stations ( 10 ), Overfeed facilities ( 13 ), Gas consumers ( 15 ), Gas feeders ( 16 . 17 ), Fermenters ( 18 ), Post-fermentation facilities ( 19 ), Biogas plants ( 21 ), Memory elements ( 22 ), Gas bubbles ( 23 ), Compressors ( 25 ) and / or regulating devices ( 26 ), characterized in that the gas network pressure by a pressure control system ( 6 ) for transmitting a signal in the gas network ( 1 ) between components of the gas network ( 1 ) is actively varied to reduce or increase the gas feed and / or gas withdrawal. Method according to claim 1, characterized in that a) a gas network pressure is actively varied as a function of an evaluation criterion and b) a regulation ba) a gas feed of at least one gas feeder ( 17 ) and / or bb) a gas extraction of at least one gas consumer ( 15 ) taking into account the varied gas network pressure. Method according to claim 1 or 2, characterized that the variation of the gas network pressure in the time domain of minutes, especially 2 to 20 minutes or 5 to 15 minutes. Method according to claim 2 or 3, characterized that the gas network pressure in a tolerance range between a lower Threshold and an upper threshold is varied. A method according to claim 2, 3 or 4, characterized in that the variation of the gas network pressure via the pressure control system ( 6 ) he follows. Method according to one of the preceding claims, characterized in that the variation of the gas network pressure by a gas expansion engine ( 7 ) he follows. Method according to one of the preceding claims, characterized in that the variation of the gas network pressure via a control of the transfer from a gas network stage (high pressure area 3 ) to a neighboring gas network stage (medium pressure range 5 ) he follows. Method according to one of the preceding claims, characterized in that a gas feeder ( 17 ) a memory element ( 22 ) is assigned, via which the gas feed of the gas feeder ( 17 ) into the gas network ( 1 ) of the gas production by the gas feeder ( 17 ) can be at least temporarily decoupled. Method according to one of the preceding claims, characterized in that a gas consumer ( 15 ) a memory element is assigned, via which the gas removal of the gas consumer ( 15 ) from the gas network ( 1 ) of the consumption of the gas by the gas consumer ( 15 ) and / or the provision of final energy at the consumer can be at least temporarily decoupled. Method according to one of the preceding claims, characterized in that for a design of a variation of the gas network pressure, a model for a) the change in the gas feed of at least one gas feeder ( 17 ) and / or b) changing the gas extraction of at least one gas consumer ( 15 ) is used as a function of the gas network pressure. Method according to one of the preceding claims, characterized in that not metrologically detected gas flow rates and / or not metrologically detected gas pressures at different locations of the gas network ( 1 ) are approximated via a simulation using an observer. Method according to one of the preceding claims, characterized in that a regulation of the gas feed of at least one gas feeder ( 17 ) or the gas removal of at least one gas consumer taking into account a) the degree of filling of a storage element ( 22 ) of the gas feeder ( 17 ) or the degree of filling of a storage element of the gas consumer, b) the gas network pressure and c) a feed-in characteristic ( 45 ) he follows. A method according to claim 12, characterized in that a regulation of the gas feed of at least one gas feeder ( 17 ) or the gas extraction of at least one gas consumer taking into account a forecast for the gas production of the gas feed ( 17 ) or the final energy demand of the gas consumer. Method according to one of the preceding claims, characterized characterized in that a regulation of the gas network pressure taking into account a dV ./dp characteristic takes place. Method according to claim 14, characterized in that that the dV ./dp characteristic of an outside temperature and / or a Time information, in particular a season, a time of day or a weekday depending is. Method according to one of the preceding claims, characterized characterized in that a variation of the gas network pressure under consideration a simulation of the effect of a variation of the gas network pressure Ap on a change the gas volume flow .DELTA.V. he follows. Method according to claim 16, characterized in that a simulation of the effect of a variation of the gas network pressure Δp on a change the gas volume flow .DELTA.V. past recorded data regarding the variation of the gas network pressure Ap for a change the gas volume flow .DELTA.V. considered. Method according to claim 16 or 17, characterized in that a simulation of the effect of a variation of the gas network pressure Δp on a change of the gas volume flow ΔV. the infrastructure of the gas network ( 1 ) considered. Method according to one of the preceding claims, characterized marked that a change the gas volume flow .DELTA.V. one predetermined setpoint, which depends on other parameters. Method according to one of the preceding claims, characterized in that a control exceeding a predetermined maximum gas flow rate V. _max avoids. Method according to one of the preceding claims, characterized marked that a) a gas flow V. at least a location in the gas network is measured, b) the gas network pressure determined at the pressure control system, c) determines a map becomes.