SE444065B - POWER SOURCE LIMIT FOR SUBSCRIPTION CENTER FOR REMOTE HEATING SYSTEM - Google Patents

Description

8404711-7 2 and the return line. E In a conventional subscriber center of a district heating subscriber, heat is transferred from the district heating system via one or more heat exchangers to the property's internal heating system for heating premises and ventilation air and for widening domestic hot water.

Control of the heat output from the district heating system to the property's internal heating system is regulated in such a way that each heat exchanger in the subscriber center receives such a large flow from the district heating system's supply that the desired supply temperatures in the internal heating system are obtained. This applies both to heat exchangers for transferring heat to the property's radiators or ventilation system, as well as to domestic hot water preparation. In the former case, the desired flow temperature is suitably outdoor temperature dependent. In the latter case, the flow temperature is desired to be constant regardless of the load, as well as for some unregulated preheating of the incoming cold water to take place.

Measurement of heat energy transferred to the property takes place by integrating instantaneous data on volume flow multiplied by the temperature difference between the district heating system's supply and return lines. The equipment that is usually used is a conventional meter for continuous volume of district heating water, temperature sensors for supply and return temperature to and from the relevant subscriber center and an electronic integration plant for calculation and integration of consumed heat energy.

The situation that is dimensioning for the district heating system as a whole in terms of production, distribution and consumption of heat, is in winter at extremely low outdoor temperatures when the need for heating premises and ventilation air is greatest. This situation coincides with the one where the maximum flow is required for distribution of district heating. In a district heating system with a large number of subscribers, the total power requirement for the preparation of domestic hot water is very small in relation to the maximum power requirement for heating premises and ventilation air. Therefore, in high-load situations, the load and thus the flow in a district heating system will almost exclusively be determined by the heating need for premises and ventilation air.

According to SBN 80, the dimensioning conditions for the internal heating systems in properties are those that occur at an outdoor temperature corresponding to LUT (lowest outdoor temperature) for the locality in question. For buildings with high thermal inertia (of eg stone and concrete) LUT 5 is applied, while for buildings with low thermal inertia (of 3 6404711-7 eg wood is used LUT 1. By definition, LUT 5 and 1 are the average temperature below 3 and 4 ° C, respectively. during a 5-day and 1-day period only once every 30 years.

By allowing properties 'properties' internal heating systems to be dimensioned for heating needs lower than those that can occur in the locality in question, it is accepted that under extreme outdoor conditions a certain power shortage arises.

In cases where a power shortage in a conventionally designed heating system arises, the shortage will normally be distributed relatively equally between different heating needs and parts of the property. The shortcoming is usually manifested in the fact that all rooms have a slightly lower temperature, get slightly colder ventilation air and hot water. In this way, the average power shortage becomes so small that it can be considered acceptable for shorter periods in extreme outdoor conditions.

If a district heating system's production apparatus and distribution lines are dimensioned for conditions corresponding to those at LUT, in the same way as for the heating system within a property, a calculated shortage situation arises at outdoor temperatures lower than LUT. In a district heating system, in contrast to the properties' internal heating system, there will not automatically be an even distribution of the power shortage between the district heating system's subscribers.

Instead, depending on the way in which the subscribers regulate their extraction of heat from the district heating system, a power shortage will in practice predominantly only affect those subscribers who have the lowest differential pressure during normal operation. The reason for this is that in practice it is impossible to distribute a given flow in a desired manner between the subscribers by means of fixed indentation, as continuous connection of new subscribers normally takes place, which constantly changes the conditions for a desired flow distribution. Furthermore, in district heating systems, several production plants in one and the same pipe network often co-operate, which means that the differential pressure available for a given subscriber center can vary very considerably (up to the ratio 1:10). These conditions make it impossible to set a fixed indentation in order to distribute a given flow. Instead, a dynamically variable throttle must take place so that there is always adaptation to the current pressure and flow situation.

What happens in the event of a power shortage in a district heating system is thus that the control valves of all subscriber exchanges will open fully and an uncontrollable flow distribution will arise.

The normal measure to avoid such situations in a district heating system is to dimension its production apparatus for such a capacity that no power shortage due to an excessive heat demand of the subscribers arises. The Swedish Heating Association therefore recommends that district heating systems are not dimensioned for the power demand that is expected to arise at LUT but at FDUT (Dimensioning Outdoor Temperature for District Heating). This temperature is about 3 ° C below LUT, which corresponds to about 10% greater power demand.

If, in the case of heat power requirements, the sizing occurs a sudden loss of production capacity, this causes the flow temperature from the plant in question to fall.

For such a situation, there are the following two alternative courses of action: _ The capacity of the distribution pumps is forcibly controlled in such a way that only as much water is distributed as corresponds to the remaining power in the plant. This means that the desired flow temperature is maintained. Through forced dimming of the distribution pumps, the differential pressure available to the subscriber exchanges will be reduced. As a result, their control valves will open fully. Depending on the reduced differential pressure, only those subscribers who are in the immediate vicinity of the production facility will receive heat, while those furthest away in practice will be completely without.

The distribution pumps must run as before and the supply temperature drops. This means that the subscribers, as the reduced flow temperature reaches them, will try to compensate for this by fully opening their control valves. This will cause a flow-equivalent situation as in the case of heat output requirements and thus flow requirements in addition to the system is dimensioned ¿for. Thus, mainly those subscribers with the lowest differential pressure during normal operation will suffer from a power shortage, while others closer to the production plant will have a considerably larger share and in some cases their entire heat power requirement satisfied; The following issues have been described above: Intentional and necessary oversizing of the district heating system's production apparatus in relation to the heat power requirement at conditions dimensioning for the subscribers. This is in order to avoid situations with uncontrollable distribution of flow and power at heat requirements higher than those at dimensioning conditions for the properties' internal heating systems.

Uncontrollable distribution of flow and power in the event of a power shortage due to loss of heat production capacity.

The above problems can be solved by utilizing equipment located in each subscriber exchange center for active limitation of the flow and / or power extractable in each subscriber exchange from the district heating system. The control equipment according to the invention therefore has a flow and / or power limiting unit, comprising a sensing device connected to the flow meter and / or the integration plant for sensing the flow of district heating water through the subscriber center and / or the power taken from the district heating system, a comparator which compares the value of the flow and / or the extracted power with a predetermined maximum value for this and a control device which is connected to the control valve and which, when the flow and / or the extracted power exceeds said predetermined maximum value due to for example, that the district heating system's heat production plant does not cover the power requirement for all subscribers connected to the district heating system, reduces the flow and / or the power to said highest value by reducing the flow through the control valve.

An active flow-limiting function is obtained according to an advantageous embodiment thus by obtaining a signal from the existing flow meter on the current flow and if this exceeds a predetermined maximum value, the equipment takes over control of existing control valves for heat exchangers for heating premises (and possibly also those for heating premises). heating of ventilation air and tap hot water) and then controls the total flow to the desired level. In the event of heat power requirements exceeding the district heating system dimensioned for and in the event of loss of production capacity and in the event of operation according to the latter of the alternatives described above, a desired distribution of the flow is maintained and thus the remaining power and shortage is distributed between all subscribers. way.

A suitable embodiment for active limitation of the heating power removable from a subscriber can be obtained in a corresponding manner.

This is done by retrieving a signal for the extracted power from existing heat quantity measuring equipment or retrieving pulses for indicating consumed energy and by measuring the time intervals between these or measuring the number of pulses per time interval, determining the current power output. If the current 8404711-7 6 power outlet exceeds the predetermined maximum value for this, existing control valves are forcibly controlled down in such a way that the predetermined maximum power is not exceeded. In this way, the total power requirement in the district heating system can always be limited to the sum of all subscribers' predetermined maximum power. In this way, the district heating system's production apparatus can also be dimensioned for this. In this way, the total production capacity in the district heating system can be reduced by around 10%.

There is no established definition of the said predetermined maximum flow or power, but the values for this may be determined by means of a template based on e.g. heated area, previous years' energy consumption or a calculation of the power requirement carried out by the property owner. The latter applies primarily to the connection of new construction.

The invention will be described in more detail below with reference to the accompanying drawing, in which the only figure is a schematic diagram of a subscriber exchange connected to a district heating system with a single heat quantity measuring equipment of conventional type, a control equipment according to the invention and a control automation of conventional type.

The subscriber exchange 1 shown in the figure comprises at least one heat exchanger for radiator water, possibly several heat exchangers for radiator water, ventilation air, domestic hot water, etc. The subscriber exchange 1 is connected to the district heating system via a supply line 2 and a return line 3 and to the property's heating system via a supply line 4 a return line 5, and transfers heat from the district heating water to the radiator water in the property's heating system. To measure the amount of heat energy transferred, a flow meter 6 is used, which is connected to the return line 3, and temperature sensors 7 and 8, which are connected to the supply line 2 and the return line 3, respectively. Obtained flow and temperature values are fed via lines 17, 18 and 19, respectively. an electronic integration plant 9, which on the basis thereof calculates and integrates consumed heat energy.

A control valve 10 is used to regulate the flow of district heating water through the subscriber exchange 1. The control valve 10, which is mounted on the return line 3, is manually or automatically controlled to give the radiator water the temperature required for optimal heating effect, depending on the outdoor temperature.

In order that in the event of a lack of power due to for example, a breakdown in the district heating production plant or excessive power demand, limiting the flow through the subscriber center and / or limiting the drawn power and distributing the shortage over all subscribers connected to the district heating system, a control equipment 11 according to the invention is connected to the respective subscriber center. The control equipment 11 here comprises a flow and / or power limiting unit 12, which, when the flow of district heating water through the subscriber center 1 and / or power taken from the district heating systems exceeds a predetermined maximum value, reduces the flow and / or power to this value. Different ways to obtain this maximum value are given above. In order to simplify the manufacture and assembly of the control equipment 11 and to allow the use of equipment already existing in the subscriber center, the flow and / or power limiting unit 12 has a sensing device, which is connected via a line 20 to the flow meter 6 in the heat quantity measuring equipment. for sensing the current flow of district heating water through the subscriber exchange 1, and a comparator which compares the value of the flow with the predetermined maximum value for this. This comparison then determines whether or not to activate the flow and / or power limiting unit 12 to reduce the current flow. The process is thus continuous. Reduction of the flow to the predetermined maximum value is effected by means of a control device connected to the control valve 10 via a line 21, in order to restrict the flow through the valve when required. In addition, or instead of the connection to the flow meter 6, the sensor 12 of the unit 12 is connected via a line 22 to the integration unit 9 to retrieve a signal for output power or pulses for consumed or transmitted energy, the time interval between the pulses or the number of pulses per time interval indicating current power output.

As can be seen from the embodiment according to the figure, the control valve is normally controlled via a line 23 by an automation consisting of a temperature regulator 13, which via lines 24 and 25 is connected to sensors 14 and 15 to obtain information about the current outdoor temperature and the radiator water supply temperature and based on this information, regulate the flow through the valve 10 so that the radiator water gets the right temperature. In order to prevent the temperature controller 13 in the event of a shortage situation from persistently keeping the control valve 10 substantially completely open so that the flow therethrough and / or the output power is greater than the predetermined maximum value for this, the flow and / or power limiting unit 12 has a disconnector 16 (here on line 21) which disconnects the temperature controller and allows the control of the control valve to be taken over to reduce the flow down to said maximum value for the flow

Claims (3)

i, .-,. ,, ._ 8404711-7 and / or output power. Should a shortage situation arise and thus a reduced flow and / or reduced power remain for a longer period of time, the flow and / or power limiting unit 12 in cases where the subscriber exchange 1 also includes a heat exchanger for domestic hot water, a time device which after a given time interval interrupts the heat supply to the heat exchanger for domestic hot water by completely closing the associated control valve. The control equipment according to the invention has been stated above to be activated especially when the maximum heat power requirement is greater than that for which the district heating system is dimensioned, i.e. at outdoor temperatures lower than FDUT, or in the event of any shortage situations due to breakdown in the district heating system's heat production facility. It should therefore be noted that the control equipment naturally also comes into operation when the heat output of a subscriber exchange, during normal operation, exceeds the predetermined maximum value for the flow and / or the output. It is obvious to the person skilled in the art that the present invention can have many applications and within the scope of the following patent claims present many constructive embodiments without departing from the idea and purpose of the invention. Patent claims Control equipment for a subscriber center connected to a district heating system, wherein the measuring center (1) is connected to a measuring equipment consisting of a flow meter (6) which measures the flow of district heating water through the subscriber center, temperature sensors (7, 8) for measuring district heating water and the front heating water. return line temperature and an integration plant (9) for calculation and integration of consumed heat energy based on measured flow and temperature values, as well as a variable, flow control valve (10) for regulating the flow of district heating water through the subscriber center, characterized by a flow and / or power limiting unit (12), having a sensing device connected to the flow meter (6) and / or the integration unit (9) for sensing the flow of district heating water.by the subscriber exchange (1) and / or that from the district heating system the drawn power, a comparator comparing the value of the flow and / or w the drawn power with a predetermined tamed maximum value for this and a control device which is connected to the control valve (10) and which, when the flow and / or the extracted power exceeds said predetermined maximum value due to for example that the district heating system's heat production plant does not cover the power requirement for all subscribers connected to the district heating system, reduces the flow and / or the power to said highest value by reducing the flow through the control valve. Control equipment according to claim 1, wherein a temperature regulator (13) with sensors (14, 15) for outdoor temperature and radiator water is connected to the flow control valve (10) for controlling it, characterized in that flow and / or the power limiting unit (12) further has a disconnecting device (16) which, when the flow and / or the drawn power exceeds said predetermined maximum value, disconnects the temperature controller (13) and allows the control of the flow control valve (13) to be taken over. 10) to reduce the flow therethrough. Control equipment according to claim 1 or 2, wherein the subscriber comprises separate heat exchangers for radiator water that the central (1) and hot water, respectively, characterized by the flow and / or power limiting unit (12) have a time which, after a predetermined time period of reduced flow and / or reduced power interrupts the heat supply to the domestic hot water heat exchanger. '