DE1016274B - Processes and systems for the operation of combined heat and power plants with downstream hot water heating networks - Google Patents

Description

Processes and systems for the operation of combined heat and power plants with downstream Hot water heating networks Combined heat and power plants with downstream heating water networks generally operated in such a way that the waste heat from an engine in a Heat exchanger (heating condenser) is passed, which this heat to the in the heating circuit circulating heating water transfers. At flow temperatures above approx. 90 ° C, the The excess part is usually reheated with bleed steam in a second heat exchanger. The consumption of heating water is regulated by the consumer and the heat according to the measured Consumption billed.

If it is a question of space heating, the required amount of heat is Depending on the weather and subject to considerable fluctuations. The force generation of the Machine operated in this way is subject to the same weather-dependent fluctuations. Of the Accumulated electricity has only a minor value because of the electricity demand dictated by the consumer has a different load profile than the weather-dependent heat demand. That's why such counter-pressure machines are used with other power generation systems without a thermal power coupling operated in parallel for the purpose of load balancing. The installed machine power but can never be fully used during current peaks because of the heating load then only reached a partial value. At the same time, the different load conditions require Electricity - heat also increases the boiler output. The investment costs will be accordingly higher and the economic yield greatly reduced.

Characteristic for the load curve is z. B. that mostly the heat peak in the morning hours and the current peak in the late afternoon hours falls. The heating machine operated depending on the heat demand therefore brings in the morning the greatest power supply, i.e. at a time when there is less power demand, while in the afternoon - when there is an increased demand for electricity - the heat load and so the power consumption is relatively low. Is outside the heating time the operation of such heating machines is not possible because they are purely counter-pressure machines are completely dependent on heating. In order to improve the performance of the Increasing heating machines a little is often done in the midday hours of the heating network if possible undercooled, so that the machine also at times of higher power demand operated at a lower condenser temperature and increased steam throughput can be. The opposite way is also taken to achieve the same purpose, d. H. the heating network is overheated at noon and at times of increased Power requirement of the machine completely switched off. The heating condenser is on during this time applied with cooling water. This increase in performance comes with high Outlet gradient and distribution losses bought; it is uneconomical and because of the strong temperature change is harmful to the capacitor.

About the disadvantages of the parallel operation of counter pressure and condensation machines To reduce, you already have the heating condenser on an extraction condensing machine hung and the heating water network with high constant or partially sliding temperatures drove. The heat extraction is always regulated by the consumer. These machines can also never be extended with full condensation output, because in the heating condenser there is a greater or lesser heat gradient depending on the heating water temperature lost for electricity generation. This loss of performance must be due to additional condensation systems balanced and borne by the heater.

To balance the load between electricity and heat and to cover heat peaks memories are also used. The machines are then used for a steam flow measured from about 50 to 60% of the maximum heat demand, while the rest of the power is generated as live steam boiler output. This live steam boiler output can can be made smaller when using memories.

In a similar way, bleed condensing machines are also used in steam distribution networks come to use, but also have the disadvantage that the machine performance in relation to the steam throughput due to the high gradient loss in the amount of bleed steam is only slight. The available Performance can also be because of the fluctuating steam consumption, which is determined by the consumer and depending on the weather is also not to be assessed beforehand. The high cost of the boiler systems fall to a large extent on heating.

When designing the power plant, all of the systems mentioned can only with the lowest electrical power resulting from the most unfavorable I-Teizdampf amount results, can be used, while the rest of the power is fully provided by condensation machines must be covered. The investment costs of such thermal power stations are due to the additional Condensation performance quite high. It affects the profitability of the Combined heat and power considerably. In addition, management is difficult because the load distributor never judge the performance of the heating machine with certainty and therefore can hardly be used properly according to an economical driving style.

The invention now relates to a method for operating power plants with extraction condensation machines and centrally regulated heating water networks, with the one using the highest practically possible heat gradient and without special Compensating accumulator in a machine for pure counter-pressure operation at will Supply of heating or mixed back pressure condensation operation at higher electrical load or pure condensation operation to cover the current peaks can be driven. The inventor has recognized that there is no disadvantage for the consumer is possible under certain conditions, a centrally regulated Switch off the heating water network completely from the heat supply for several hours and only to overturn without the consumer noticing anything. The storage capacity of the The heating water network and the building are completely sufficient for this interruption of operations to bridge. Using this knowledge, the present invention is currently increased current load, the heat dissipation of the extraction condensation machine to the Heating network restricted or completely switched off while the machine is in the condensation section is dimensioned so that it has full electrical power in condensation mode can extend, with only the heating water network and the buildings supplied as Serve heat storage. If the heating condenser is operated with cooling water Cooling system or a second condenser for cooling water operation is added to the heating condenser connected in parallel, it becomes the cooling surface at lower cooling water temperatures flowing water, draining heated cooling water for the condenser is added, in order to adapt the performance of the cooling surface to the most economical amount of steam.

The details of the invention are to be explained with reference to the drawing will.

Figure 1 shows the circuit of the extraction condensation machine on a scale that allows the condensation part to be connected directly to the pressure stage of the extraction part. The withdrawal takes place at the end of the machine part 1. The overflow line 16 leads to the condensation part 1a . The heating capacitor2, which warms up the heating circuit and supplies consumers 3, is attached to the extraction stage. The circulating pump 5 pushes the returning water via the gate valve 6 through the heating condenser and allows it to flow back to the consumers via the gate valve 15 either directly via the slide 13 or, if high flow temperatures make reheating necessary, via the slide 12 into the heat exchanger 11 and then continue to flow heated to the consumer via the slide 14. The main condenser is via the cooling water pump 8 a. acted upon by cooling water that is available from an inflow channel 4.

If a higher machine output is required at times of increased current load, the heating circuit can be partially switched off from the heating condenser by opening the slide 7, because part of the heating water flows into the return, bypassing the condenser. The steam consumption in the heating condenser then goes down, and the low-pressure part 1 a can be subjected to higher pressures. If the machine is to run fully on condensation, the slide 6 and 15 are closed when the slide 7 is open. The corresponding pressure-resistant heating built capacitor is then switched off completely from the network, and the total amount of vapor flows to the condensing part l a, too. The machine runs as a pure condensation machine.

Fig. 2 shows the arrangement in a machine with high performance, wherein the overflow line 16 branches off from a higher pressure level than the withdrawal to the heating condenser. The heating condenser is shown in a split version. The mode of operation is the same as described under Fig.l, but can be used for Increase in performance of the high-pressure part 1 of the machine with an increased amount of steam be applied if during condensation operation from the extraction stage of the machine Steam is fed into the cooling water part of the split condenser 2. The pump 8 supplies the cooling water to the cooling surface. It flows through line 10 in the general When the cooling water temperature is low, it becomes the outlet speed uneconomically high in the last extraction stage, then it is over the slide 18 heated cooling water fed to the inflow and thus the cooling capacity on the economic level depressed. The utilization of the from the withdrawal stage in the Cooling water part of the heating condenser 2 conducted heat takes place naturally with decreased efficiency because the vacuum is worse than in the main condenser. Nevertheless, it may be advantageous to take this route, e.g. B. if from the overload capacity of the boiler during the current peak in addition Steam is made available and the high pressure part of the machine up to the overflow line 16 can absorb the steam output of the cooling surface of the split condenser 2. The worsened efficiency is financially compensated by that the additional performance with existing system parts, so without additional Capital expenditure, is achieved. Of course, a split capacitor This can also be advantageous for a machine version according to Fig. 1, if the high-pressure part 1 of the machine can be overloaded and steam is also available from the boiler system stands.

In Fig.3 the circuit of a machine with high power is shown, the same as the machine according to Fig. 1 with the heating switched off with full Slope utilization can run as a condensation machine. The machine complies of Fig. 2, but also has an overflow line branching off at the extraction pressure stage 19, which = opens into the low-pressure part at the corresponding pressure level. While of the current peaks are the Heating condenser from the heating network, such as before described, separated and the overflow lines 16 and 19 fully open. the The machine then runs in pure condensation operation with the normal operation for condensation machines usual vacuum.

It is obvious that in this mode of operation the always warm Machine without operational preparation and without difficulties due to restrictions or interruption of the heat supply to the heating circuit at will on condensation mode switched and used with full electrical power in the event of current peaks can be. Limit the additional costs compared to a pure condensation system on slightly higher machine costs, they hardly noticeably burden the heating. Large and large units can be used, as can the power supply requires according to economic principles. The expansion of the power plant can also Rush ahead of the development of the heating network because the machines are in condensation mode run barely noticeably more uneconomical than condensation machines. It is also it can be seen that in heating mode the heat is always low with the weather adapted quality can be taken from the machine, so that the heat generation costs come very close to the theoretical minimum. Depending on the economic advantage the load on the heating capacitor according to that corresponding to the electrical load Withdrawal pressure set and the heat exchanger 11 for reheating via the tapping stages 17 is used, or if the electrical load is too low, a choke is used in the overflow line 16, the pressure at the extraction stage is built up. The latter The mode of operation limits the profitability. It is used at power plants several machine units are hardly necessary because of the electrical load primarily imposed on heating machines that operate with greater efficiency will.

The heat generation costs only reach one in this mode of operation Fraction of the fixed costs arising from debt servicing, personnel costs, taxes, administration, Maintenance costs of the systems and the like arise. Even with larger fluctuations In terms of heat consumption, the heat can therefore be transferred to the heating plant without risk Sell consumers at a flat rate. According to the weather statistics and practical experience but the fluctuations in consumption move only in the range of about 10 ° / o around the Value of the normal year. The advertising advantage of flat-rate billing, yours Administrative convenience and the elimination of expensive meters create one further economic incentive for the operating procedure described. Alone the installation and maintenance of heat meters require z. B. a cost in the amount of 15% of the total capital costs to be raised for city heating networks.

Claims (2)

PATENT CLAIMS: 1. A method for operating power plants with extraction condensation machines and centrally controlled heating water networks, characterized in that at the time of increased current load the heat output of the extraction condensation machine to the heating network is limited or completely switched off, while the machine in the condensation section is dimensioned so that it is in condensation mode the full electrical power can be deployed, whereby only the heating water network and the buildings supplied serve as heat storage. 2. The method according to claim 1, wherein the heating condenser receives a cooling system operated with cooling water or the heating condenser is connected in parallel with a second condenser for cooling water operation, characterized in that outflowing heated cooling water for the condenser is added to the cooling water inflow. Copies considered: German Patent Specifications Nos. 563 973, 565 046, 608 470, 541 230, 672 733.