DE3312140A1 - Method and devices for local control of heating surfaces through which liquid flows and for measuring the heating work - Google Patents

Abstract

The invention relates to a method and devices for local control of heating surfaces through which liquid flows and for measuring the heating work. The output of heating surfaces through which liquid flows depends on parameters specific to the heating surface (heat transfer conditions between heating medium and space, size of heating surface, arrangement in space, etc.), as well as on the respective operating conditions (liquid feed temperature, mass flow, room temperature). Local control of capacity is generally performed by varying the liquid mass flow. It is the aim of the invention to undertake ON/OFF control of the heating surfaces. A constant heating medium mass flow is ensured by suitable measures (bypass valves or volume flow governors). The difference between the feed and return temperatures is measured simultaneously. The magnitude of the heating medium mass flow under the particular installation conditions can be determined by measuring the temperature difference between feed and return and the room temperature in a "calibration trial". By counting the ON pulses of the control, which works with the same pulse durations, it is possible in conjunction with simultaneous multiplication by the actual temperature difference between feed and return to make an accurate measurement of the instantaneous heating capacity or of the heating work of the heating surface. DDC control with the aid of microprocessors offers particularly effective conditions for applying the method. In terms of rooms and dwellings ... Original abstract incomplete.

Description

The invention relates to a method for local regulation of liquid

through-flow room heating surfaces and for measuring the heating work as well several facilities to carry out the procedure.

There are both methods for the local regulation of heating surfaces as also those for measuring the heat consumption of the individual heating surfaces of the centrally heated ones Known building. The local regulation can be carried out without auxiliary power (thermostatic radiator valves) or with auxiliary power (e.g. electrical or pneumatic), whereby either each heating surface has its own controller with actuator or one controller per room is provided, the multiple heating surfaces over one or more parallel working Control organs regulate. It is also known that the control devices mentioned with locally or centrally arranged options for manual or time-controlled Setpoint changes (e.g. night reduction) can be provided. There are also Process known in which the control of all heating surfaces of a building or part of a building is carried out by a centrally located microcomputer, which Via a double electrical line and, if necessary, additional local decoders with all Controllers and actuators for the heating surfaces controlled by it is connected, which set setpoints and the associated actual values of the room temperatures continuously queries with the help of coded signals and, using the same method, the and actual value comparison are transmitted to the associated control elements (DDC regulation, direct digital control).

local and / or central switching interventions via a central Automatic time switch of the microcorrputers intervene in the regulation, are with these Control methods are known to be particularly simple.

For the measurement of the EEarm emission of individual heating surfaces are preferred simple systems are used, which due to the system-related measurement inaccuracies usually only serve to provide a known heating consumption for the entire building or a certain proportion of this on the individual connected heating surfaces to apportion the consumption share (heat cost allocator). (Heat cost allocator).

From the great variety of the systems mentioned, one can distinguish between where ß for the EEårmausgabe of the heating surface one of the heating surface temperature dependent evaporated liquid mass, the mean difference between the temperatures the heating surface and the room or the flow and return and the room or the mean difference between room temperature and air temperature is taken as a basis. All known systems are hardly suitable for underfloor and ceiling heating systems.

On systems that control room temperature and record heat consumption at the same time serve, the following are known: In a system is a conventional thermostatic valve Similar thermostatic heater valve 1 is used, its setpoint adjustment is used as a measure of the heat emission (regardless of the actually achieved Temperature in the room). The corresponding signal is recorded at certain intervals and summed up for the measurement period and for the consumption evaluation with one of the Heating output roughly the same size (e.g. standard output of the connected Heating surfaces or heated room surface) multiplied. The disadvantage of the procedure lies in the fact that there is only a tax variable for the consumption evaluation, not on the other hand, their effects on the heat consumption of the room or

the heat output of the heating surface can be recorded.

Another well-known method, but only to one apartment-wise Recording of the heat consumption is intended, works with two-point controlled heating surface valves, those for an apartment in parallel from a Raumheritxfr staten in a pilot room of the The apartment can be opened or closed. In the pilot room will also be ongoing the flow temperature is recorded, in addition to the water mass flow in stationary operation the performance of the heating surface is determined. The heat output of the heating surfaces is turned off the opening time of the valves controlled in parallel, taking into account one of the measured flow temperature-dependent correction variable is formed. Time controls for the setpoints can be easily built into the system. The advantage over the first-mentioned system can be seen in the fact that with a relatively simple structure for the determination of consumption two variables are recorded, the output of the heating surfaces significantly influence. The disadvantage is that the respective mass flow is not taken into account by the heating surfaces and that, in addition, the performance-determining mean temperature of the heating surfaces even with the same flow temperature for the different rooms or apartments in the building can be very different. The mass flow through the heating surfaces, which among other influences is the average The temperature of the heating surface also changes in systems of this type in particular in that on the same pipe network depending on the regulation or control of the individual Apartments, the differential pressures on the heating surfaces change to a large extent. aside from that the proportionality between the opening time of the valves and the AEarm delivery applies of the radiator under otherwise known conditions only for the stationary Operation that is not given here according to the task (open-close operation according to Controller request).

The object of the invention is to provide one for those in heating systems usual transient operating conditions particularly suitable and precise absolute value determination the heating work and this with the local regulation of the heating surfaces using essentially the same components. The difficult one Mass flow measurement is carried out using the method known from DIN performance testing Relationships between mass flow, flow, return and room temperature on the Measurement of the three temperatures mentioned.

The method according to the invention for simultaneous regulation and consumption pressure of heating surfaces assumes a continuous measurement of the heating surface downward emission on the heating medium side off: The room temperature sensor (4) switches the valve to a heating surface depending on opened or closed at the moment when there is a demand for heat. By running as Bypass valves (6) or through throttle valves (5) in connection with a flow regulator (12) ensures that, regardless of the control status of the other heating surfaces on the network, the mass flow at the heating surface remains constant with the valve open. He is in stationary calibration operation under conditions for which the heat dissipation of the heating surface is known from the standard test measurements or can be calculated by measurement the flow and return temperature and the room temperature determined experimentally. This calibration operation can either be carried out once during the adjustment of the system or preferably in certain time intervals outside of the usual betting times, repeated automatically. Except for the number of simultaneous opening intervals of the control valves, the temperature difference between the flow and return is continuously detected, which - multiplied by the mass flow - results in a signal that of the respective EEårmegabe of the heating surface is directly proportional. For systems with throttle valves (5) the volumetric flow controller (12) can be dispensed with if this is the case of the mass flow compared to that in the calibration measurement through the solution of the Pressure difference at the open valve through the pressure sensors (14) and (15) or on Another fixed resistance through which the heating medium flow was measured and at the calculation of the heating work is taken into account. For two-pipe systems with bypass valves, where the flow temperature at all with unthrottled mass flows in the network Places is about the same, may only be possible the return temperature each radiator and the flow temperature can be determined centrally. In particular when using a central microcomputer for control (DDC control) and for recording and processing exposure values to determine consumption, the functions described with relatively little effort for wiring and with comparatively meet high accuracy. Every heating surface, every room or every piece of advice (e.g. Apartment) can be provided with an automatic timer, which can be either different Switches on the setpoints preselected on the controller (e.g. day / night) or only in between Selects operating modes "on" (valve position according to controller request) and "off". Particularly In residential buildings, it is advantageous to have an additional one that can be operated centrally for each apartment Switching option, which takes precedence over otherwise existing automatic time switches works and makes it possible, for example when leaving the apartment all heating surfaces, possibly for a preselectable period of time, to be taken out of service or to a reduced one To switch setpoint. It can be useful for holiday homes in particular additional switching option to be implemented in such a way that it is operated remotely from a central location via telephone can be.

In addition to the combination of local temperature control given here and a simultaneous measurement of heat consumption is offered by the method according to the invention the following advantages: The consumption measurement provides absolute values for every room. Because of The two-point characteristics of the actuators can make these particularly simple and measuring the heating work becomes its technically most difficult part traced back to a pulse counting particularly suitable for electronic evaluation. Problems of pollution and, if three-way valves are used, also of Noise generation does not occur. A particular advantage is that none load-dependent permanent target value deviations occur and still because of the short actuation times in connection with that which can be easily adapted to the control task programmed controller characteristics ensure very precise compliance with the set Setpoints is achievable. This advantage over systems with permanent setpoint deviation will gain particular importance in the future, as the heating surfaces of the rooms are carefully considered on neighboring rooms that may be heated to a limited extent increasingly larger than that EESrmeke must be designed accordingly for the rooms.

The correct operation of control systems with a permanent setpoint deviation by non-experts becomes significantly more difficult under these conditions.

Systems with temperature-related fixed adjustable setpoints without permanent Deviations from setpoint values such as the method according to the invention do not present any difficulties here. Another important advantage is that the process can also be used for Floor and ceiling heating is suitable. When using a central microcomputer for regulation and consumption recording it is also possible to use comparatively to assign a number of special functions to the system with little additional effort: Due to the continuous temperature measurement in all heated rooms, it is possible The differential heat flows between all rooms via a microcomputer of the building and to be taken into account when calculating consumption. the Identifying data (area and warehouse passage coe f iz ients) are the Microcomputer programmed once. In addition, by the microcomputer the heat supply to a heating surface can be interrupted if the temperature in falls faster than a programmed speed limit in a room, as is the case when opening windows. A corresponding intervention can also be triggered in a known manner via electrical contacts in the windows. at Blocking can be performed using the temperature change rate as a control variable the heating medium supply either generally by manual intervention or automatically a predetermined period of time when the minimum value of the room temperature (after closing the window) has increased again by a specified amount. It is advantageous to use the microcomputer for central control of the flow temperature depending on the outside temperature, if necessary with a separate time program switch, to use with. In this case it is possible to use the preset dependency between outside temperature and flow temperature (heating curve), which is known to be the Consumption of a heating system significantly influenced, optimally on the building or to adapt the respective operating conditions by gradually adjusting the heating curve is lowered until at least one of the connected heating surface control valves is permanently or a preprogrammed high amount of time in the "open" position. This ensures that the flow temperature is only increased that high as required by the room with the highest relative staff requirement. as well the microcomputer can be used to make measurements for each control loop heating and cooling curves, the associated specific thermal building data to determine and thus the optimal switching points for heating and Determine cooling, like this one with separate microcorrputers already is known (heating optimizer "). It is advantageous to carry out the circuit in such a way that that both the temperature difference between the flow and return and the opening times of the valves can be queried separately. The temperature difference between and return (tea temperature spread) provides for the water-side adjustment of the systems is a useful auxiliary variable. Long opening times that are out of the ordinary individual control valves can indicate unusual operating conditions (e.g. too small heating surfaces, insufficient heating medium flow). In both In cases, the entire building's heating coil may be riveted because of a single one Radiator or room are run up uneconomically.

With the method according to the invention it is also possible to apply disturbance values to limit the maximum proportional opening time of the control valves.

This allows the control behavior, for example, for the purpose of rapid heating oversized heating surfaces can be improved. The advantage here is in this to see that without impairing the control behavior in normal operation a room by room Rapid heating is possible.

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Claims (14)

PATENT CLAIM E "Procedures and devices for local regulation heating surfaces through which liquid flows and for measuring the heating work 1. Procedure for local regulation of heating surfaces through which liquid flows and for continuous Measurement of the heating work, characterized in that a room temperature sensor (4) controlled regulating valve (5) or (6) only in the working positions "open" or "closed" is operated, with the "on" position the heating medium mass flow from a Calibration measurement is known and kept constant or its anchoring via the measurement a characteristic pressure difference is measured, and that the respective heating medium temperatures in the flow (7) and return (8) or their difference with the help of temperature sensors (9) and (10) as well as the room temperature measured periodically and for the purpose of Determination of heating work with the water value of the heating medium flow known from a calibration measurement and multiplied by the associated time intervals in which the valve is open will. 2. The method according to claim 1, characterized in that the calibration measurement to determine the constant heating medium flow with a known dependency between the power of the heating surface, the heating medium mass flow and the flow and return temperatures and the room temperature (travel map) only from a compression of the mentioned TeNperatures at a given flow temperature, preferably the design temperature, exists and is repeated as often as required. 3. The method according to claim 1 and 2, characterized in that a Heating medium flow changed during operation compared to the calibration measurement via the measurement a pressure difference that depends on the flow of heating medium during calibration and determined in the heating work measurement during operation and taken into account in the evaluation will. 4. The method according to response 1 and 2 or 3, characterized in that that with oversized heating surfaces (e.g. for the purpose of rapid room heating) In normal operation, the maximum proportional opening time of the valves is limited in such a way that that the output corresponds at most to that of a non-dimen-shaped heating surface. 5. Device for performing the method according to the claims 1, 2 and 3, characterized in that the measurement, control and evaluation in in a manner known per se (DDC control; direct digital control) via a microcomputer (1) takes place via an electrical double line (2) and, if necessary, for simplification the addressing is connected to the measuring sensors via a central decoder (3). 6. The method according to claims 1, 2 and 3, characterized in that that in two-pipe systems, the flow temperature in the entire network of a heating zone is about the same, omitting the flow temperature sensor on each control valve the flow temperature is only measured centrally at one point in the heating zone. 7. The method according to claims 1, 2 and 3, characterized in that that in a known manner from the temperature difference between neighboring Broaching when the product of the area and the heat transfer coefficient of the interface is known the heat flow is continuously determined and used as a correction variable for the heat consumption of the two rooms is summed up. 8. The method according to claims 1, 2 and 3, characterized in that that when a disturbance variable which rapidly drops the room temperature occurs, e.g. when opening windows, close the valves of the associated room heating surfaces, when the temperature is faster than when the heating medium supply is interrupted by comparing the temperature drop with a programmed reference value will. The cancellation of this control signal can either after a varprogrammed Time or after the room temperature has increased from its minimum value by one specified value has risen. 9. Device according to claim 4, characterized in that the microcortputer (1) works centrally for the entire supply area of a central heating system, where the temperature sensors (4), (9), (10), the actuators (11), if necessary, the pressure sensors (14) and (15) or, if applicable, the decoders (3) of all rooms of the supply area to the electrical Double line (2) are connected. 10. Device according to claim 4 and 5, characterized in that the microcomputer (1) described in claim 1 proportional to the heating work Products and the correction values according to; Claim 6 summed up per heating surface or room, saves and at any time via a corresponding electrical output outputs for evaluation. 11. Device according to claim 4 and 5, characterized in that the evaluation of the heating work-proportional products described in claim 1 and the correction values according to claim 6 are made by the microcomputer (1) and the heating work for the measurement period by heating surface, room or room group (e.g. apartment-wise) is displayed in a manner known per se via counter. 12. Device according to claim 4 and 5, characterized in that the calibration measurement at programmable time intervals automatically by the microcomputer (1) is done, which - preferably at night - all control valves (5), (6) in moves to the "open" position and at a preprogrammed flow temperature, preferably the interpretation stertperatur, the temperature measurements described in claim 2 continues until these are constant over time within a predetermined framework, so that with the programmed performance maps of the heating surfaces, the mass flow determination can be vargensmmen by the Mlkrooomputer. 13. Device according to claim 4 and 5, characterized in that the temperature differences between pre-and The return flow on the micro-computer (1) can be queried separately so that the water-side Adjustment of the system can then be made. 14. Device for the method according to claims 1, 2 and 3, characterized in that the proportional opening time of the control valves (5), (6) can be queried separately on the microcomputer in order to determine such heating surfaces and, if necessary, automatically display which is too small or too little of heating medium are flowed through, so that the centrally controlled heating curve is unnecessarily high must be driven.