DE3533160A1 - Control arrangement - Google Patents

Abstract

The present invention relates to a control arrangement for a central consumer unit connected to a distant heating system, with a flow measuring device, temperature transmitters for measuring the forward run and return run temperature and an integrating device for calculating and integrating consumed thermal energy as well as a variable, flow-regulating valve for regulating the flow of distant heating water through the central consumer unit. In order to avoid, in the case of increased heat requirement, situations with uncontrollable distribution of flow and energy, a control arrangement is provided according to the invention, which consists of a flow and/or energy limiting unit which has a sampling member for sampling the flow of distant heating water through the central consumer unit and/or the energy extracted from the distant heating system, a reference member which compares the value of the flow and/or of the energy extracted with a predetermined maximum value, and a control member which is connected to the flow-regulating valve and which reduces the flow and/or the energy to the said maximum value.

Description

The invention relates to a control arrangement according to the preamble of claim 1.

The distribution of heat in a common district heating system happens in that heated and cooled water through separate flow and return systems Is directed to and away from customers.

The energy requirement in a district heating system is formed by individual customers _r of the supply pipe remove a certain flow rate and let this amount passing through one or more heat exchanger where it is cooled. Then the water is fed back into the return pipe of the district heating system.

Postal checking account: Karlsruhe 76979-754 Bank account: Deutsche Bank. AG Viilingen (BLZ 69470039) 146332

Pumps are provided in the heat generation type layers, once to distribute the heat to the consumers (the pressure losses in the pipelines to overcome), and secondly, to maintain a certain differential pressure in the pipeline network, thus a sufficiently large pressure difference between the for the function of the customer center Flow and return line is created.

In a normal customer center of a district heating consumer, heat from the district heating system is passed through one or more heat exchangers on the internal heating system of the building to heat the rooms and the ventilation air as well as for the preparation of domestic hot water.

The heating energy extraction from the district heating system to the internal heating system of the building is regulated in such a way that one for each heat exchanger in the customer center so large flow rate is taken from the flow line of the district heating system that the desired flow temperatures can be achieved in the internal heating system. This applies to both heat exchangers for transferring heat to the radiators or the ventilation system of the building as well as for domestic hot water preparation. In the former In this case, the desired flow temperature is expedient depending on the outside temperature. In the latter case, it is desirable that the flow temperature is continuously from the load is independent and that a certain uncontrolled preheating of the cold water supplied takes place.

The heat energy supplied to the building is measured by integrating current information about the Flow volumes multiplied by the temperature difference between the supply and return pipes of the district heating system. The equipment commonly used includes:

a conventional knife for the flow volume of the District heating water, temperature transmitter for flow and return temperature to or from the respective customer center and an electronic integrator for calculating and integrating used thermal energy.

The circumstances regarding generation that determine the dimensions of the district heating system as a whole, Distribution and consumption of heat are extremely low outside temperatures in winter, where the need for one Heating of rooms and ventilation air is greatest. This situation coincides with the situation where the Distribution of district heating requires a maximum flow. In a district heating system with a large Number of consumers, the total energy requirement for the preparation of domestic hot water is very low in proportion for the maximum energy requirement for heating rooms and ventilation air. Therefore, at high load, the load is and thus the flow in a district heating system is almost exclusively due to the heating requirements of the rooms and the Ventilation air conditional.

The dimensions determining the dimensions for the internal heating systems of buildings are in accordance with the building regulations those that occur at an outside temperature corresponding to that occurring in the respective locality the lowest outside temperature. Used for buildings with high thermal inertia (e.g. made of stone and concrete) the outside temperature value 5, while for buildings with low thermal inertia (e.g. made of wood) the outside temperature value 1 applies. By definition, the values 5 and 1 are the average temperature that occurs during a Time of 120 or 24 hours only once every 30 years

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3 or ^{4 0} C is not reached. Since a Diniensionierung the inner heating of buildings for ¹ a lower heat requirement as to the respective location in the incoming is permitted ':., It is accepted that under extreme ambient conditions a certain lack of energy produced.

In those cases where there is a lack of energy in one in conventional If the heating system is constructed in a manner that is well designed, the deficiency is normally distributed relatively evenly between different heat requirements and parts of the building. The deficiency is usually noticeable by that all rooms receive a slightly lower temperature, slightly colder ventilation air and domestic hot water. So the average lack of energy remains so small that it is under extreme conditions for shorter periods of time External conditions can be regarded as acceptable.

If the heat generation plant and distribution lines of a district heating system sized for circumstances equivalent to the lowest outside temperature a calculated deficiency arises in the same way as for the heating system within a building Outside temperatures that are even lower than the lowest outside temperature specified for the location in question. In contrast to what is the case in the internal heating systems of buildings, in a district heating system an even distribution of the lack of energy does not take place automatically. Instead, it becomes dependent how the consumers regulate their extraction of heat from the district heating system, an energy shortage in practice for the most part only affect those customers who have the lowest differential pressure during normal operation

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to have. The reason for this is that in practice it is impossible to achieve a given flow rate in a desired Way to distribute between consumers by fixed throttling, if a continuous connection normally takes place by customers, which always changes the requirements for a desired flow distribution. It also often occurs in district heating systems sin joint operation of several heat generation plants in one and the same line network, from which it follows that the for a given customer center available differential pressure can vary extremely considerably (up to a ratio of 1: 1O). These circumstances make it impossible to set a fixed restriction to distribute a given flow. Instead of this there must be a dynamically variable throttling so that there is always an adjustment to the prevailing pressure and flow situation takes place.

Sias in the event of a lack of energy in a district heating system happens, is thus the following: The control valves of all Customer centers are fully opened and an uncontrollable flow distribution arises.

Normally one avoids such situations in a district heating system by having the heat generating plant of the system is dimensioned for such a capacity that there is no lack of energy on a too high heat demand is due to the customers. The Swedish District Heating Association recommends accordingly that telecommunication systems are not designed for the lack of energy - with which one is determined The lowest outside temperature is calculated, but rather for an energy meter as calculated according to the calculation

can arise in the dimensioning of the determining outside temperature for district heating. This temperature is approximately 3 ^° C. below the lowest outside temperature, which corresponds to an approximately 10% higher energy requirement.

If at a lower heating energy requirement than the Dimensioning a sudden loss of heat generating capacity takes place, this means that the The flow temperature of the respective system drops. For one In such a situation there are the following two alternative approaches: The capacity of the distribution pumps is increased inevitably degraded in such a way that me so much water distributed; will, as it is the remaining Energy of the system. This means that the desired flow temperature is maintained. Through the Inevitable reduction in the capacity of the distribution pumps becomes available to the customer centers standing differential pressure decreased. This means that the control valves of the pumps are fully open. As a result of the humiliated Differential pressure are only those customers who are in the immediate vicinity of the heat generation plant receive warmth, while the most remote ones remain completely without warmth in practice.

The distribution pumps run as before and the flow temperature drops. This means that the takers depending on how the lower flow temperature reaches it, to compensate for the lower flow temperature seek to fully open their control valves. This leads to the same situation in terms of flow as created in the case of heating energy demand and thus a flow demand beyond that for which the system is dimensioned. Thus, mainly the buyers

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with the lowest differential value in normal operation Affected by a lack of energy, while the other customers in closer proximity to the heat generation plant have a significant get larger share; in certain cases your entire heating energy requirement is satisfied.

The following problems are described above

Intended and necessary oversizing of the heat generation system of the district heating system in relation to the heating energy demand below those for the customers Dimensioning determining circumstances, namely to situations with uncontrollable distribution of flow and energy in the case of higher heat requirements than those in the circumstances determining the dimensioning the internal heating systems of the buildings are available.

Uncontrollable distribution of flow and energy in the event of a lack of energy, due to loss of heat generation capacity.

The above problems can be solved by utilizing one provided in each customer center Device for active limitation of the flow that can be taken from the district heating system in each customer center and / or energy,

According to the invention, the control arrangement mentioned at the outset

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An active, flow-limiting function is therefore in accordance with an advantageous embodiment obtained in that

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A signal about the respective flow is retrieved from the existing flow meter and that, if this flow exceeds a predetermined maximum value, the arrangement controls the existing control valves of the nana exchanger for heating rooms (and possibly also the heat exchanger for heating domestic hot water and ventilation air ) takes over and then reduces the entire flow to the desired level. With a higher heat requirement than that for which the district heating system has been dimensioned, and h <? L loss of heat generation capacity and when handling according to the latter of the two alternatives described above, the desired distribution of the flow and thus the remaining energy is maintained Defect is distributed among all customers in the desired manner.

An expedient embodiment for the active limitation of the heating energy that can be drawn off by a consumer can be created in a corresponding manner. This is done by calling up a signal from the existing heat quantity measuring device about the withdrawn energy or pulses to indicate the amount of energy consumed and by measuring the time periods between the pulses to determine the energy withdrawn in each case. If each power drawn exceeds the maximum value for this is the existing control valves are forced controlled in such a way that the pre-determined maximum energy is not th übersehrit. In this way, the entire energy requirement in the district heating system can always be limited to the sum of the predetermined maximum energies of all consumers. This allows the heat generation

The district heating system must also be dimensioned for this. In this way, the total heat generating capacity can in the district heating system can be reduced by 10%.

Since there is no fixed definition of the specified maximum flow or maximum energy, must the values for this as a template based on e.g. the heated area, the energy consumption in earlier Years or the energy demand calculation carried out by the homeowner. The latter applies above all to the connection of new buildings.

The invention is illustrated below with reference to the accompanying drawing described in more detail. The only figure in the drawing is a schematic diagram, one of a district heating system connected Abriehinerzentrale with a heat quantity measuring device of the usual type, a control arrangement according to the invention and a control machine of the usual type represents.

The customer center 1 illustrated in the drawing has at least one heat exchanger for radiator water, possibly several heat exchangers for radiator water, ventilation air, domestic hot water, etc. The customer center 1 is connected to the district heating system via a supply line 2 and a return line 3 and to the heating system of the building via a supply line 4 and a return line 5 and transfers heat from the district heating water to the radiator water in the heating system of the building. A flow meter 6, which is coupled to the return line 3, and temperature sensors 7 and S, which are connected to the flow line 2 or

Return line 3 are coupled. The obtained flow and temperature values are transmitted via lines 17 or 1d, 19 given in an electrical integrator 9, the based on these values, the heat energy consumed is calculated and integrated. A control valve 10 is used to regulate the flow of district heating water through the customer center 1. The control valve 10, which is mounted on the return line 3, is controlled manually or automatically, to give the radiator water the temperature that is suitable for an optimal heating effect is required.

In order to limit to limit in energy shortage due to 2.B ₅ of damage in the district heating heat generation system or a too large energy requirements, the flow through the pickup unit and / or the extracted energy as well as to distribute the defect under all devices connected to the district heating system purchasers, is one control arrangement 11 connected according to the invention to the relevant customer center. For this purpose, the control arrangement 11 has a flow and / or energy limiting unit 12 which, if the flow of district heating water through the customer center 1 and / or the energy taken from the district heating systems exceeds a predetermined maximum value, reduces the flow and / or the energy to this value . Various methods are given above for obtaining this maximum value. To simplify the manufacture and assembly of the control arrangement 11, the flow and / or energy limiting unit 12 is also made with scanning and comparison elements which, on the one hand, scan the flow through the Abnenmerzentrale 1 and / or the energy taken from the district heating system and, on the other hand, use the value for this compare the predetermined highest flow and / or energy value

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This comparison then determines / ob the flow and / or Fnergiebegrenzungseinheit 12 is activated to _t to reduce the respective flow and / or energy v / ground or not. The process is therefore continuous. The control arrangement 11 can be provided with all the necessary components for its function; however, the manufacture and assembly are simplified and the costs for this can be reduced by using the equipment already located in the customer center. The flow and / or energy limiting unit 12 is connected to the flow meter 6 in the heat quantity measuring equipment via a line 20 for sampling the respective flow and via a line 21 to the control valve 10 in order to throttle the flow through the control valve if necessary. In addition, or instead of the connection to the flow meter 6, the unit 12 is connected to the integrating device via a line 22 in order to call up a signal for withdrawn energy or pulses about consumed or transferred energy, the time span between the pulses indicating the energy withdrawn in each case.

As can be seen from the embodiment according to the figure, the control valve 10 is normally via a line 23 controlled by a machine, which consists of a temperature controller 13, which via lines 24 and 25 to Encoders 14 and 15 are connected to information about obtain the respective outside temperature or the flow temperature of the radiator water and use this information to regulate the flow through the valve 10 so that the radiator water receives the correct temperature. In order to prevent the temperature controller 13 at a resulting deficiency the control valve 10 keeps mainly completely open, so that the flow through the valve

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til and / or the withdrawn energy is greater than the predetermined maximum value for this _f , the flow and / or energy limiting unit 12 has a switch-off element 16 (here on the line 21) which switches off the temperature controller and allows the control valve to take over control, so that the flow is reduced to the stated maximum value for the flow and / or the extracted energy.

If a deficiency that has arisen, and thus a reduced flow and / or reduced energy, persists over a longer period of time, the flow and / or energy limiting unit 12 , if the customer center 1 also includes a heat exchanger for domestic water, has a timer which, after a certain period of time, interrupts the supply of heat to the heat exchanger for domestic water by completely closing the associated control valve.

The control arrangement explained above is preferably switched on, if the maximum heat energy demand is greater than the heat energy demand for which the district heating system is used is dimensioned, i.e. at outside temperatures below the dimensioned outside temperature for District heating or in the event of a possible lack of energy due to the loss of heat generation capacity. aside from that the control arrangement is of course also switched on when the heat energy extraction in one of the customer centers during normal operation the predetermined flow and / or maximum energy drawn exceeds.

Claims (3)

PATENT CLAIMS 1. Control arrangement for one connected to a district heating system Abnehmerζzentrale, whereby to the customer center a measuring device consisting of a flow meter that measures the flow of district heating water through the customer center, temperature transmitter for measuring the flow and return temperatures of the district heating water and an integrating device for calculating and integration of used thermal energy based on the measured flow and temperature values, as well as a variable, flow regulating valve for regulating the flow of district heating water through the Customer center are connected, characterized by a flow and / or energy limiting unit (12), which has a sensing element attached to the flow meter (6) and / or the integrating device (9) is connected to the flow of district heating water through the customer center (1) and / or the dem To sample the energy taken from the district heating system, a comparator that shows the value of the flow and / or the compares the withdrawn energy with a predetermined maximum value and has a control element that an the flow control valve (10) is connected and that when the flow and / or the withdrawn Energy exceeds the specified maximum value Postal checking account: Karlsruhe 7697S-754 Bank account: Deutsche Bank AG Viliingen (BLZ 69470039) 146332 progresses because, for example, the heat generation system of the district heating system meets all of the energy requirements the district heating system of connected consumers does not cover the flow and / or the energy by means of reduction the flow through the flow control valve is reduced to the stated maximum value. 2. Control arrangement according to claim 1, wherein a temperature controller ir1.1 sensors for outside temperature and radiator water a ^: the flow control valve for steamer the same is coupled, characterized in that the 5 the flow and / or energy limiting unit (12) also has a shut-off element (16) which, when the flow and / or the extracted energy, the aforementioned exceeds the predetermined maximum value, the temperature controller (13) switches off and the takeover of the Control by the flow control valve (10) to reduce the flow through the valve allows. 3. Control arrangement according to claim 1 or 2, wherein the customer center separate heat exchangers for Has radiator water or domestic hot water, characterized in that the flow and / or energy limiting unit (12) a timer wakes up after a predetermined period of time from Flow and / or reduced energy interrupts the heat supply to the heat exchanger for domestic hot water.