DE102008004126A1 - Heat source's heat cost regulating method for heat distribution system, involves forming regulating loop for compensating differential pressure at sensor from actual values of differential pressure and positions of pumps - Google Patents

Abstract

The method involves providing cost-guided regulation of usage of a set of heat sources (2-4) e.g. boiler, by assigning differential pressure reference values to pumps (6-8) of the heat sources. The reference values are cost-specifically shifted in relation to differential pressure basic reference values of the pumps. A regulating loop for compensating the differential pressure at a sensor (14) is formed from actual values of the differential pressure at the sensor in comparison with the respective shifted reference values of the pumps, and positions of the pumps.

Description

The The invention relates to a method of controlling costs in heat distribution systems with appropriate heat supply for the Heat utilization.

Heat distribution systems are in this sense plants that are made of heat sources, such as Boiler, heat storage, solar systems, heat pumps and waste heat, heat in the form of tempered volume flows take, summarize, transport and to the heat user to distribute.

In The heat distribution will be over the use of the Heat sources and about the operating regime of distribution the heat costs for the use of heat affected. The reason for this lies in the different ones Heat costs of the respective heat sources and in Heat losses in the heat distribution and depreciation and auxiliary power, this mostly electric energy.

So far Heat distributions are designed to be constant, time-dependent or by hand for a specified differential pressure of Heat distribution regulated. The operating state of the heat distribution it is set to be equal to or more than the minimum required differential pressure for heat utilization is held.

The The operating state is set according to strategies on the adjustment options of the heat output and depending on the quality of the controller on control options energetically favorable operating conditions of the heat distribution, tuned are.

Of the Operating state of the heat distribution is created by the active differential pressure generation via pumps in the heat sources and passive differential pressure reduction across the heating network and at the feeds for heat utilization. The differential pressure generation takes place via pump circuit or speed control of Pumps for a given differential pressure. The differential pressure measurement for This regulation can be done at different network points.

The different heat sources in the system are functionally dependent, time-dependent or manually switched on and off.

This happens by switching the pumps in the heat sources. For the possibility of using the heat sources is next to the heat output and the amount of heat nor the need orientation of the heat, especially the Temperature, decisive.

about Strategieschaltungen is trying to cost-effective heat sources preferably for use.

The two targets in heat distribution, namely the regulation of the differential pressure and the control of the heat sources, be independently controlled in all known applications or regulated. In particular, the important function of the most economical Use of heat sources is not subject to a control loop, but is about functional algorithms, timelines or controlled by hand.

Also the control circuit for the differential pressure of the heat distribution does not depend on demand-determining criteria, such as heat output, run, but usually operated constantly and rarely on timer changed.

The Parallel connection of heat sources with the goal, needs-based Heat regarding the flow temperature under use to achieve more cost-effective heat sources takes place only via manual or time switches on site or centrally.

In the paperback for Heating + air conditioning, Recknagel, Sprenger, Hönmann, issue 92/93 describes the control of pumps. Among other things, there is shown on page 667, paragraph 1, the regulation of the pump via the differential pressure. On page 670, 4th paragraph , the automatic pump circuit is shown as a function of the differential pressure.

D 070599 describes a heating system, the heat distribution over controls the return temperature and at the same time uses as a heat storage. This procedure improves the efficiency of the heat source, if a condensing boiler is used. On the differential pressure control of the system will not be received.

The Patent 10217172 describes a method for controlling the heat output in heating systems. On cost-specific use of heat sources and differential pressure control strategies will not be discussed.

DE 43 12 811 C1 describes a heating system with several feed points in the heat distribution. The goal is a low return temperature is sought. The means for this is the mixing of the different volume flows of the heat sources and the heat user. Differential pressures and heat costs of the sources are not described.

DE 195 06 628 describes a method where the heat distribution takes place via the regulation of the volume flows. Described is the method with a heat source. Differential pressure controls are not mentioned.

DE 102 60 379 A1 describes a heating system with several heat sources as combined heat and power plants. The meaning lies in an optimized mode of operation with regard to the utilization of the entire system. For this purpose, the heat distribution is regulated centrally. This is done by influencing the operation of the individual heat sources under consideration of an optimized power production. Differential pressures are not included, different costs of the sources are ignored.

DE 103 26 263 A1 describes a complex heat distribution where heat sources and heat users are switched on and off. The method relates to the way this circuit is done. It does not concern the cost structure of the heat sources or the differential pressure state of the heat distribution.

DE 197 10 853 describes a method where multiple heat sources feed into a heat distribution. The control of the feed of the heat sources via the heat output required by the heat, recorded by the room temperature. The heat costs of the sources and the differential pressure state of the distribution are not discussed.

in the In the prior art, heat distributions are known in which the heat distribution with a differential pressure controlled Heating network takes place.

Also Heat distributions are known in which the heat sources cost-oriented to be integrated via circuits.

at All known methods are cost-based integration the heat sources via a controller. alternating Operating conditions, as usual in heat distributions, disadvantageously allow optimal utilization of the potential savings the heat sources with different heat costs not too.

The time-dependent or central control pulses occur in large intervals and thus run the changing Operating conditions behind, so are the possibilities limited to the reduction of heat distribution costs.

The constant, non-responsive management of the differential pressure for heat distribution, also with time-based changes the setpoints, usually causes differential pressure surplus and thus too high electric energy costs. In addition, before the heat users the differential pressure with appropriate Effort can be reduced to the necessary level.

From Based on this prior art, the invention has the object to create a solution that is significantly more economical in operation Heat energy distributed in heat distribution systems.

According to the invention this object is achieved by a method according to claim 1, below this method is based on the embodiment and the 1 and 2 be explained in more detail.

Of the basic idea of the solution according to the invention consists in that according to the prior art Practiced separation between the cost-optimized selection of Heat sources and the differential pressure-controlled driving to overcome the heat distribution. Furthermore should use the heat sources in a cost-managed Closed loop.

• – Die spezifischen Wärmekosten aus den Wärmequellen 2, 3, 4, wobei 2 die Wärmequelle mit den höchsten und 4 die Wärmequelle mit den niedrigsten Kosten abbildet
• – Den Istwert des Differenzdrucks zwischen Vorlauf 15 und Rücklauf 16 der Wärmeverteilung aus dem Sensor 14
• – Den Wärmeleistungsbedarf der Wärmeverteilung aus der Wärmenutzung 5 und dem Wärmemengenzähler 9
• – Die benötigte Vorlauftemperatur aus der Wärmenutzung 5
• – Die Vorlauftemperaturen der Wärmequellen aus den jeweiligen Sensoren 10, 11, 12
• – Die Vorlauftemperatur der Wärmeverteilung aus dem Sensor 13

In a concrete example 1 detects the heat distribution cost controller 1 the information necessary for its regulation as follows:

• - The specific heat costs from the heat sources 2 . 3 . 4 , in which 2 the heat source with the highest and 4 represents the heat source with the lowest cost
• - The actual value of the differential pressure between flow 15 and return 16 the heat distribution from the sensor 14
• - The heat output requirement of the heat distribution from the heat utilization 5 and the heat meter 9
• - The required flow temperature from the use of heat 5
• - The flow temperatures of the heat sources from the respective sensors 10 . 11 . 12
• - The flow temperature of the heat distribution from the sensor 13

A heat cost controller 1 calculated from the specific heat costs of the respective heat sources 2 . 3 . 4 a cost-specific offset to the differential pressure base setpoint for each heat source. The heat source 4 with the lowest heat cost gets the highest setpoint. This assignment is in 2 shown.

By means of a heat cost controller 1 is the speed of the pumps 6 . 7 . 8th the heat sources 2 . 3 . 4 placed so that the respective differential pressure setpoints are corrected. As a result, so the pump 8th the heat source 4 With the highest differential pressure setpoint, it is of primary importance to promote volume flow into the heat distribution.

If this volume flow is insufficient, the differential pressure at the sensor 14 To maintain, the differential pressure decreases and reaches the setpoint of the heat source 3 ,

Upon reaching the setpoint of the heat source 3 becomes the pump 7 switched on and it is by means of this pump 7 then in addition to the pump 8th Volume flow introduced into the heat distribution and compensated for the differential pressure.

If this volume flow also reaches the critical range in which the differential pressure can no longer be maintained, this differential pressure continues to drop to the desired value of the heat source 2 , Accordingly, then promotes the pump 6 additional volume flow in the heat distribution and regulates the differential pressure.

When the heat requirement in the heat recovery decreases, the pumps switch off 6 starting over 7 to 8th again.

advantageously, be with changing specific heat costs the heat sources the differential pressure setpoints in the control loop dynamically adjusted. So it's always the heat source primarily used, currently the most cost-effective heat the heat distribution provides.

The basic setpoint of the differential pressure is calculated by the heat cost controller 1 via a function of the heat demand of heat utilization 5 over the heat meter 9 and further individual usage requirements.

The heat cost controller limits the amount of heat needed to provide adequate heat 1 the volume flows of the heat sources 2 . 3 . 4 when the flow temperatures at the sensors 10 . 11 and 12 become smaller than the flow temperature required by the use of heat.

The heat cost controller 1 regulates by the parallel connection of volume flows with different flow temperatures at the sensors 6 . 7 . 8th from the heat sources, a volume flow with demand-based flow temperature at the sensor 13 , This makes it possible to utilize the heat potential of heat sources with lower flow temperatures required in heat utilization by mixing volume flows from heat sources with higher flow temperatures.

The heat distribution cost controller 1 fulfills further control and limitation tasks that are not relevant to the procedure to be explained.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• - DE 4312811 C1 [0016]
• - DE 19506628 [0017]
• - DE 10260379 A1 [0018]
• - DE 10326263 A1 [0019]
• - DE 19710853 [0020]

Cited non-patent literature

• - Heating + air conditioning, Recknagel, Sprenger, Hönmann, issue 92/93 describes the control of pumps. Among other things, there is shown on page 667, paragraph 1, the regulation of the pump via the differential pressure. On page 670, 4th paragraph [0013]

Claims (5)

Method for controlling the costs in heat distribution systems with demand-based provision of heat for heat utilization, characterized by a cost-controlled regulation of the use of several heat sources ( 2 . 3 . 4 , ...) via the assignment of differential pressure setpoint values, which are cost-specifically offset with respect to a differential pressure base setpoint, to pumps associated with the heat sources ( 6 . 7 . 8th , ...) of the respective heat sources ( 2 . 3 . 4 , ...), wherein the control loop is formed from the actual value of the differential pressure at at least one sensor ( 14 ) in comparison with the respective, cost-offset differential pressure setpoints of the pumps ( 6 . 7 . 8th ...) of the respective heat sources ( 2 . 3 . 4 , ...) and the location of the pumps ( 6 . 7 . 8th , ...) for regulating the differential pressure at the sensor ( 14 ). Method according to claim 1, characterized in that the specific cost of the heat from the heat sources ( 2 . 3 . 4 , ...) are read out. A method according to claim 1, characterized by the management of the basic setpoint of the differential pressure via a functional relationship with the heat demand on a sensor ( 9 ) of heat utilization ( 5 ). Method according to Claim 1, characterized by the volume flow limitation of the heat sources ( 2 . 3 . 4 , ...) about the flow temperature at the heat sources ( 2 . 3 . 4 , ...) and pumps ( 6 . 7 . 8th , ...) assigned sensors ( 10 . 11 . 12 , ...). Method according to Claim 1, characterized by the parallel connection of volume flows from the pumps ( 6 . 7 . 8th , ...) from the heat sources ( 2 . 3 . 4 , ...) with different flow temperatures at the respectively assigned sensors ( 10 . 11 . 12 , ...) to a volume flow in the heat distribution via the flow ( 15 ) with demand-based flow temperature, which is determined by means of a separate sensor ( 13 ).