DE102008028375A1 - Delivery medium flow rate regulating method for e.g. hydraulic heating system, involves controlling flow rate of control unit by adjusting variable, which is formed from difference between actual value and reference value - Google Patents

Abstract

The method involves circulating a delivery medium between a warming and/or cooling supplier and a delivery component e.g. warming and/or cooling load unit, via a supply line and a return line. The flow rate of a control unit is controlled by an adjusting variable, which is formed from difference between an actual value and a reference value, where the actual value corresponds to the difference of the supply line temperature and the return line temperature, and the desired value is a function of the supply line-temperature. An independent claim is also included for a device for regulating flow rate of a delivery medium of a heating or cooling system.

Description

The Distribution of heating or cooling energy to transfer components such as radiators or component activation, etc. of a hydraulic Heating or cooling system via pumps.

The transfer component (eg radiator) gives off more energy, the higher the difference between the mean temperature of the transfer system (Tin + Tout) / 2 and the temperature of the receiver (eg. Room air) is.

Around to optimize the output of the transfer component, The flow rate of the pump, which is the transmission medium, is regulated distributed.

State of the art

• 1. In the simplest case, the pump is of its capacity designed for the heating / cooling circuit and connected without control.

Disadvantage:

It always flows the same volume flow. At high power output the transfer components do not reach the pump capacity and there is a high difference between the flow and return temperatures. This reduces the mean temperature of the transfer components, which compensates by increasing the flow temperature must become.

at low output power of the transfer components becomes consumes a lot of energy for the pump.

• 2. In der DE 23 58 754 wird die Förderleistung der Pumpe mit steigender Außentemperatur reduziert. Bei diesem Verfahren können keine internen Lasten oder solare Einträge berücksichtigt werden. Die tatsächliche Energieabgabe der Übergabekomponente(n) wird nicht berücksichtigt.
• 3. Um die Erhöhung des hydraulischen Widerstandes durch Abregeln von Übergabekomponenten durch Raumthermostate auszugleichen, werden druckgeregelte Pumpen ( DE 1 928 575 ) eingesetzt. Damit wird ein konstanter Druck erzeugt, der wiederum einen konstanten Volumenstrom in den einzelnen Übergabesystemen zur Folge hat.

A further disadvantage of this system is that, when regulating transfer components by room thermostats, the hydraulic resistance in the system is increased. This leads to an unnecessary increase in pressure in the system. The pump power could be reduced in this case. Since this does not happen, too much pump power is consumed here too.

• 2. In the DE 23 58 754 the delivery rate of the pump is reduced with increasing outside temperature. In this method, no internal loads or solar entries can be considered. The actual energy output of the transfer component (s) is not taken into account.
• 3. In order to compensate for the increase of the hydraulic resistance by adjusting transfer components by room thermostats, pressure-controlled pumps ( DE 1 928 575 ) used. Thus, a constant pressure is generated, which in turn has a constant volume flow in the individual transfer systems result.

There decreases with decreasing flow temperature, the energy output decreases the difference between Tin and Tout also decreases. That is, it turns out a similar characteristic, as in the dynamic temperature difference control.

Disadvantage:

• 4. Regelung der Pumpe auf eine konstante Temperaturdifferenz dT zwischen Vorlauf-Temperatur Tin und Rücklauf-Temperatur Tout.

Additional information (eg pressure sensors) is required for the control or the control is carried out by complex mechanical solutions.

• 4. Control of the pump to a constant temperature difference dT between flow temperature Tin and return temperature Tout.

The smaller the distance of Tin and the temperature of the receiver, the more the flow must be reduced in order to maintain the dT to be controlled. These relationships are illustrated 1 ,

Disadvantage:

No uniform temperature distribution at the transfer system. This is especially noticeable when T _{OUT is} in the range of the receiver temperature. This results in a high percentage difference in temperature between the flow T _IN and the return T _OUT . This leads, as it were, to a reduction in the area of the transfer medium, which must be compensated for by an increase in T _IN .

It Object of the invention, an efficient control method and to create a corresponding facility that is relatively easy to implement.

These Task is solved by a method or a device with the features of the independent claims.

advantageous Embodiments are in the subclaims whose characteristics are also combined, as far as appropriate can be.

Based of diagrams, the invention will now be explained in more detail. The same reference numerals in different figures to corresponding parts and / or functions.

It show schematically:

1 : A diagram of the prior art,

2 : a first diagram of the invention,

3 : a diagram for an advantageous development of the invention,

4 : a control circuit diagram of an embodiment of the invention.

Around to eliminate the disadvantages of the known arrangements described above, the following scheme is proposed according to the invention:

T_IN:

Eintrittstemperatur

T_OUT:

Austrittstemperatur (Rücklauf-Temperatur)

dT = TIN – TOUT dT = f(TIN) The temperature difference dT between inlet and outlet of the transfer component is formed in dependence, ie as a function f of the inlet temperature (flow temperature).

T _IN:

inlet temperature

T _OUT :

Outlet temperature (return temperature)

dT = T IN - T OUT dT = f (T. IN )

f (T _IN ) can in the simplest case be a percentage straight line: dT = T _IN × X%

These relationships are in 2 indicated.

Advantages of this scheme:

• • Transfer components can be operated at the optimum operating point at all times.
• • The volumetric flow adjustment will be the lowest Energy expenditure carried out as an oversteer eliminated.
• • The pressure regulation of the pump can be omitted. With Abregeln of handover components through room thermostats is through the dT control automatically reduces the pump capacity.
• • The information required for control (T _IN , T _OUT ) is present. No additional information or mechanical components are needed to control the pressure.
• • The characteristic can be specified easily become.

Particularly advantageous embodiment of the invention can be realized when the features of claims 4 to 7 and 11 are realized. Because out 2 there is the following disadvantage:
If little heating or cooling energy is required (T _IN approaches the room temperature), dT control is no longer possible, since T _OUT can never fall below the room temperature in the case of heating (never exceed in cooling mode).

4 shows the conditions that can be realized with the features of claims 4 to 7 and 11. Where: dT = f (T. IN - Room set temperature) Heating case dT = f (room set temperature - T IN ) Cooling case

f (T _IN - room set temperature) can in the simplest case be a percentage straight line: dT = (T IN - room set temperature) · X%

Here the control takes place up to the room set temperature and thus covers the entire control range.

The two examples above show how a meaningful dependence on dT = f (T _IN ) can be achieved using simple equation equations.

Of course, the calculation of dT = f (T _IN ) can be carried out according to any desired characteristics and thus optimally adapted to the existing transfer system.

The essence of the invention is that dT is not a fixed value but depends on T _IN .

The The dynamic dT control described above can be taken for granted on almost all thermal consumers and heat generators apply that pass on energy via a hydraulic medium or consume.

All these systems have an inlet temperature (T _IN ) and an outlet temperature (T _OUT ) of the hydraulic medium. With the dynamic dT control, the operation of these systems can be optimized ecologically and economically.

Naturally can also be component-specific functions of the entry or outlet temperature come into play.

Further examples:

• • heat generators (eg boilers, Exhaust gas heat exchanger ...)
• • chillers (eg absorption / adsorption chillers, ...)
• • Thermal separation stations / transfer stations
• • Air heater / air cooler
• • Etc.

4 shows a control technical circuit example of the device according to the invention, namely a device for controlling the volume flow of a transfer medium of a heating or cooling system, in which between a heat or cold supplier L on the one hand and a transfer component (heat or cold consumer) U on the other hand via a flow V and a return R circulates a transfer medium that transports heat or cold.

in the Power of the transfer medium is a control unit of the volume flow RV provided, which can be fed to a manipulated variable St is.

• – mit einer ersten Polarität „+” ein erster Anteil entsprechend der Vorlauf-Temperatur Tin,
• – mit der zweiten Polarität „–” ein zweiter Anteil entsprechend der Rücklauf-Temperatur Tout
• – mit der zweiten Polarität „–” ein dritter Anteil, der eine Funktion der Vorlauf-Temperatur Tin ist.

To form the manipulated variable ST, addition means Ad1, Ad2 are provided to which the following can be supplied as summands:

• With a first polarity "+" a first proportion corresponding to the flow temperature Tin,
• - With the second polarity "-" a second portion corresponding to the return temperature Tout
• - With the second polarity "-" a third portion, which is a function of the flow temperature Tin.

The Control unit of the volume flow RV is by the manipulated variable St controllable so that at a manipulated variable the first polarity "+" the volumetric flow increases and decreases at the second polarity.

Of the third portion tends to follow the flow temperature Tin by he for example, a percentage C of less than 100% of the flow temperature Tin corresponds.

The Addition means Ad1, Ad2 is "+" with the first polarity further proportion can be supplied, which tends to a desired room temperature Tsr corresponds. At room temperature Tsr to be that of a pilot space or zone, and it can come from a variety of premises or Zones that as a pilot room or zone automatically and dynamically selecting which is the highest Flow temperature required.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 2358754 [0006]
• - DE 1928575 [0006]

Claims (11)

Method for controlling the volume flow of a transfer medium a heating or cooling system where a heat or cold supplier (L) on the one hand and a transfer component (heat or refrigeration consumers) (U) on the other hand via a flow (V) and a return (R) a transfer medium circulates that transports heat or cold, With following features: a) a control unit of the volume flow (RV) is controlled by a manipulated variable (St), that is the difference between an actual value (dT) and a setpoint (Sw) is formed; b) the actual value corresponds to the difference from the flow temperature (Tin) and the return temperature (Tout); c) the setpoint (Sw) is a function of the flow temperature (Tin). Method according to claim 1, characterized in that that the desired value (Sw) has at least one component which tends to the course of the flow temperature (Tin) follows. Method according to claim 2, characterized in that that the percentage is less than 100% of the flow temperature (Tin) corresponds. Method according to one of the preceding claims, characterized in that the desired value (Sw) is an additive component which tends to correspond to a desired room temperature (Tsr). Method according to claim 4, characterized in that that the additive component is a percentage of a desired room temperature (Tsr) corresponds. Method according to claim 4 or 5, characterized that the room set temperature (Tsr) is the one of Pilot space or zone. Method according to Claim 6, characterized that of a plurality of premises or zones as pilot space or zone automatically and dynamically is selected, which is the highest flow temperature needed. Device for controlling the volume flow of a transfer medium a heating or cooling system where a heat or refrigeration suppliers on the one hand and a transfer component (heat on the other hand via a Flow (V) and a return (R) a transfer medium circulates that transports heat or cold, With following features: a) in the stream of the transfer medium a control unit of the volume flow (RV) is provided, the one Manipulated variable (St) can be supplied, b) to form the manipulated variable (ST) are addition agents (Ad1, Ad2), to which the following can be added as summands is: - with a first polarity (+) first proportion corresponding to the flow temperature (Tin), - With the second polarity (-) a second proportion accordingly the return temperature (Tout) - with the second polarity (-) a third part, the one Function of the flow temperature (Tin) is, c) the control unit the volume flow (RV) is determined by the manipulated variable (St) controllable such that at a manipulated variable the first polarity (+) increases the volume flow, Device according to claim 8, characterized in that that the third portion tends to be the flow temperature (Tin) follows. Device according to claim 9, characterized in that that the third share is a percentage (C) of less than 100% the flow temperature (Tin) corresponds. Device according to one of claims 8 to 10, characterized in that the addition agents (Ad1, Ad2) with the first polarity (+) can be fed to another part , which tends to correspond to a desired room temperature (Tsr).