EP3601688A1 - Method for operating a circulation system, and circulation system - Google Patents

Abstract

The invention relates to a method for operating a circulation system (10) comprising a cooling device (12, 14) with an input port (12a, 14a) and an output port (12b, 14b) for cooling water. Said method comprises the following steps; determining, in particular calculating, a change in the temperature of the water between the initial region and the end region according to a model of the axial change in temperature for the first partial section adjacent to the output port (12b, 14b), starting from a temperature start value TMA T_MA* < T_soll, and a volume flow start value V_z*, determining, in particular calculating, a change in the temperature of the water between the initial region and the end region for each further partial section according to the model of the temperature change, under the constraint that the water temperature in the initial region of the partial section is equal to the water temperature in the end region of the partial section, to which the given partial section is adjacent, and selecting the value Ta of the water temperature and the value Vz of the volume flow at the output port (12b, 14b) in such a way that in the end region of each partial section the water temperature is TME T_ME < T_soll and at the inlet port (12a, 14b) the water temperature T_b < T_soll with T_soll - T_b < Θ is set, wherein θ>0 is a predetermined value. The invention also relates to a circulation system for implementing said method.

Description

 description

Method for operating a circulation system and circulation system

The invention relates to a method for operating a circulation system and a circulation system, each according to the features of the preambles of the independent claims.

In order to prevent microbial growth in cold water networks, DIN EN 806, as well as VDI guideline 6023 for drinking water installations in buildings, requires a limitation of the temperature of the cold drinking water (PWC) in all lines of the installations to a maximum of + 25 ° C at all times. According to DIN EN 806-2.3.6, for cold water points the water temperature should not exceed + 25 ° C 30 seconds after the full opening of a sampling point. Furthermore, in order to avoid stagnation of the water, the cold water installation should be designed so that under normal operating conditions, the drinking water in all pipes of the installation is regularly renewed. Similarly, the VDI guideline 6023 contains the recommendation to keep the temperature of the drinking water as low as possible below + 25 ° C. It is understood that often for other water installations a temperature limitation of the water is considered necessary, for example, for installations of industrial process water.

The occurrence of high PWC temperatures is promoted by the sole or joint occurrence of different conditions, including:

 • high PWC temperatures already at the house connection,

 • thermal influence of the installation areas by z. B. the location and

 Alignment of the building or installation areas within the building,

• Insufficient insulation of the PWC pipes against heat input,

 • Installation of PWC piping in rooms and technical centers with

 Heat sources, in common installation areas such as in

 Shafts, channels, suspended ceilings and installation walls with heat-emitting media (eg heating pipes, domestic hot water (PWH) and domestic hot water - circulation systems (PWH-C), supply air and exhaust air ducts, lamps),

 Phases of stagnation in the aforementioned installation areas,

 • widely distributed PWC installations with associated large ones

 Investment volumes,

• oversized PWC piping. Preferred method in the attempt to meet the legal requirements in periods of stagnation, so far is the forced flushing of plants to imitate the intended operation in these phases.

In order to provide cold drinking water, various refrigerated circulation systems have already been proposed for the chilled water network.

From EP 1 626 034 A1 a cooled circulation system is already known in which a controlled addition of a disinfectant to the water is provided.

From DE 10 2014 013 464 A1 method for the operation of a circulation system with a heat storage, a circulation pump, a control unit and at least two strands and with otherwise unknown pipe network structure is known. The strands, each of which has a valve that can be adjusted by a motor drive, correspond to temperature sensors which are arranged between the strands before each mixing point. The motor drives and / or the circulation pump are connected for data exchange with the control unit wireless or wired. The control unit is designed to perform a thermal hydraulic balancing and a thermal disinfection by a stroke limitation of measured temperatures and / or an adjustment of the pump power as a function of a difference between a temperature actual value and temperature target value.

From DE 20 2015 007 277 U1 a drinking and service water supply device of a building with a house connection for cold water, which is connected to the public supply network known. The supply device comprises at least one circulation line, which is provided with a pump, and leads to at least one consumer. In the circulation line, a heat exchanger is provided which extracts heat from the water.

EP 3 159 457 A1 also describes a drinking and service water supply device of the type known from DE 20 2015 007 277 U1, the heat exchanger being formed by a latent heat accumulator and a motor-operated purge valve provided in the circulation line, which is connected to a control device in terms of control is has. The purge valve is disposed between the latent heat storage and a mouth of the house connection in the circulation line and downstream of the latent heat storage in the flow direction. In the known circulation systems with cooling of the water is partly not at all, or at least not effectively ensures that the water temperature remains below the desired temperature for all sections and for all times during the operation of the circulation system.

It is therefore an object of the present invention to achieve in an effective manner that the water temperature remains below the desired temperature for all sections and for all times during the operation of a circulation system.

The object is achieved with the features of the independent claims.

The method according to the invention relates to a circulation system having a cooling device with an inlet port and an outlet port for cooling water and with a line system having a plurality of strands which have one or more sub-sections with given heat coupling to an environment and connected by nodes one or more of the lines of the conduit system are designed as a supply line, at least one individual supply line connected to a removal point and at least one line designed as a circulation line is connected to the supply line (s).

The method according to the invention for operating the circulation system is characterized in that, starting from a temperature start value T _MA * <T _soll and a volume flow start value V _z ^* for the first partial path connected to the output port, a temperature change of the water between the starting region and end region correspondingly a model of the axial temperature change is determined, a change in temperature of the water between the start region and end region for any given further, connected to the first leg partial section is determined according to the model of the temperature change, under the boundary condition that the water temperature in the initial range of the given subsection equal to the water temperature is in the end of the leg to which the given section is connected in the flow direction of the water and the value T _{a of} the water temperature and the value V _{z of} the flow at the output port are chosen so that in the end of j For each branch of the circulation system, the water temperature T _MA * <T _soll is and at the input port the water temperature T _b <T _soll with T _soll - T _b <Q, where q> 0 is a predetermined value.

Preferably, the determining consists of calculating according to the model of the axial temperature change of the water between the starting region and the end region of the partial route, So the corresponding line piece, due to heat absorption from the environment of the leg. Starting with the first part section connected to the cooling device, this will successively pass through the entire system of the sections and therefore the temperature in the entire system will be calculated.

According to the invention, in the method, the value T _{a of} the water temperature and the value V _{z of} the volume flow at the output port, which is achieved in the end region of each section of the circulation system, the water temperature T _ME <T _soll and at the input port, the water temperature T _b <T _{should be determined} with T _soll - T _b <Q, where q> 0 is a predetermined value, by means of a modeling of temperature and flow rates of circulating in the pipe system water, preferably calculated. This is preferably done for a steady state Vz state.

The cooling device and, if necessary, a circulation pump of the circulation system are then adjusted so that the water temperature and the volume flow assume the determined values T _a and the value V _z .

It is proposed according to the invention that a temperature is set at an output port, temperature changes calculated on the basis thereof and used for modeling according to the specifications of the characterizing portion of claim 1.

The advantage of calculating is that no sensor is needed to measure something, and that one can evaluate and vary influencing variables and possibly even make predictions.

Compared to a two-point control and / or a subordinate floor control or string control, the calculation offers the advantage that fewer measuring points are required and the system as a whole is less susceptible to vibrations.

The regulation according to the invention therefore takes place in comparison with the prior art by means of a control intervention at the output port, whereby the controller design, however, is based on the entire water supply system with distributed parameters with a calculation of a multiplicity of temperatures TME. So there are basically only one controller, and only one temperature setting for providing the temperature Ta required.

A similar problem to a chilled water network exists in a hot water network. In this case, only the operating temperatures change, wherein instead of a cooling device, a memory or heater is used. The temperatures in the hot water network are between 60 ° C at the storage outlet and 55 ° C at the storage inlet. In contrast to the cold water network, where it to a temperature increase due to heat gains from the environment, heat losses lead to a decrease in temperature in the hot water network.

The following formula applies both to the temperature drop in a hot water network and to the rise in temperature in a cold water network.

 Therefore, the invention also includes the analogous case of a hot water network, wherein instead of a cooling device, a memory or heater is used.

Furthermore, the o.g. Formula is also valid in a chilled water network if the temperature of the water is higher than the ambient temperature.

In general, therefore, with appropriate adaptations of the formulas used for the calculation according to the model, the invention comprises the case where, instead of a cooling device, a heat exchanger is used which can heat or cool the water.

The term strand designates a line consisting of a partial route or several partial routes between two nodes between which there is no further node.

 The strands are connected via nodes.

Preferably, the boundary condition that the water temperature in the initial region of the given sub-route is equal to the water temperature in the end region of the sub-route to which the given sub-route is connected relates only to the sub-sections of one line each.

The temperature and size of the volume flow leaving a node in a subsequent section depends on the temperatures and the sizes of the incoming sections Volume flows from. From the invention, these are preferably assumed as given by the design of the conduit system.

The distribution of the volume flows flowing out of a node to the various outgoing lines or partial lines is preferably assumed in the invention to be given by the design of the line system.

Preferably, mixing temperatures during strand combination and the temperatures during strand division are calculated on the basis of a percentage volume flow distribution.

In the method according to the invention, the line system is assumed to be given, it being understood that the line system is designed according to the specifications of DI N 1988-300 for the design of pipe networks, which in particular certain nominal widths of the PWC - (Potable Water Cold) lines and values thermal coupling of the circulating water with the environment are prescribed. It is understood that in general, the requirements of the piping network prescribed or recommended in other countries or regions can also be taken into account.

The maximum permissible value after the design of the line system is preferably chosen as the volume flow starting value V _z ^* . This value is reduced until the temperature of the circulating water is close to T _soll , because with decreasing volume flow the temperature of the circulating water increases and therefore the temperature rises at the inlet port.

Preferably, the value T _MA * is varied and the highest value T _{a of} the water temperature selected, at which at the input port the water temperature T _b <T _soll with T _soll - T _b <Q, where 0> 0 is a predetermined value.

The specification T _soll - T _b <Q ensures that the water temperature in the circulation system is not set too cold and the system is operated inefficiently in terms of energy. Typically, Q ranges between 1 ° C and 5 ° C, but may be in a different range.

The determination of the change in temperature of the water between the beginning and end of each leg can be done according to models that are known per se, for example by simulation calculations or even corresponding known formulas. The circulation system is preferably operated in carrying out the method according to the invention in a state in which no water removal and no water absorption, because in this state, a higher heating of the water is to be expected than in a state in which a water removal and thus when using the According to the method determined parameters T _a and V _z a safety distance to a state with undesirably high water temperature is ensured.

The parameters T _a and V _z determined by the method are advantageously used to model and operate a given circulation system in which the piping system is designed according to the legal requirements regarding nominal diameters and thermal coupling of the circulating water with the environment the legal requirements regarding the temperature of drinking water in the circulation system are met.

Simulations of the applicant for existing systems have shown that with the parameters set according to the invention a) the mentioned legal requirements are met and b) a higher energy efficiency of the operation of the system is achieved.

The determined by the method parameters T _a and V _z are advantageously used to the design of the cooling device in terms of their cooling performance in a given circulation system in which the piping system is designed according to the legal provisions regarding nominal diameters and thermal coupling of the circulating water with the environment determine. Furthermore, if necessary, the design of a circulation pump can be determined with regard to its pumping power.

The following terms are used in this text with a specific meaning, the definition being based on the standard DIN EN 806.

As the circulation line of the circulation system, a line downstream of a removal point in the circuit is referred to, in which water from the output port of a cooling device back to the input port of the cooling device runs, if no further removal point is connected to this line.

The term node is used for a line element to which lines are connected. Either at least two volumetric flows can flow into a node and exactly one volumetric flow expire or exactly one volumetric flow can flow in and at least two volumetric flows expire. A node corresponds to a branch. Preferably, exactly two volumetric flows flow into one node of the circulation system, and one volumetric flow or exactly one volumetric flow and exactly two volumetric flows, for example in the case of a T-piece.

For the nodes of the circulation system, the first Kirchhoff law applies in analogy to electrical circuits, according to which the sum of the inflowing volume flows is equal to the sum of the outflowing volume flows.

Preferably, at each node, the outflowing flows are divided into equal outgoing flow rates. It is understood that other divisions are possible.

In the case of a node with precisely one outflowing volume flow with different temperatures and exactly one incoming flow rate, it is preferably assumed that the temperature t _m and the mass flow m _{m of} the mixing water of the outgoing volumetric flow have the following relationship with temperature t _k and mass flow m k of the colder or temperature tw and mass flow mw of warmer flow together:

 † m = temperature mixed water (° C)

 tk = temperature colder water (° C)

t _w = temperature warmer water (° C)

rrim = mass / volume (-ström) mixed water (kg, m ³ , kg / h, m ³ / h or%)

mk = mass / volume (-ström) Cold water (kg m ^3; kg / h m ³ / h or%)

m _w = mass / volume (-ström) hot water (kg, m ³ , kg / h, m ³ / h or%)

To determine the change in temperature of the water between the beginning and end of a section, the following parameters are preferably used in addition to the length of the section

Advantageously, a temperature change of the water between its initial region and its end region can be determined for each segment of the circulation system at a stationary volume flow, the water temperature in the end region of a given subsection being equal to the water temperature in the initial region of the subsection connected next to the given subsection in the direction of flow of the circulating water is selected. Therefore, for each leg of the circulation system, based on the temperature in the initial region, the temperature of the water in the end region of the respective leg can be determined.

Advantageously, starting from a temperature at the output port at a steady-state volume flow for each section, the temperature of the circulating water can be determined, ie a value T _{a of} the water temperature at the exit port can be determined as the starting temperature of the sub-section adjoining the output port, in which case for the end regions of all Sections the water temperature T _ME <T _{is supposed to be} .

In a further embodiment of the invention, it is provided that the values T _a and V _{z are determined} in an iterative approximation method, starting from a temperature start value T _MA ^* <T _S0 n and a volume flow starting value V _z ^* for the first at the output port connected part of the route, for each given part of the water temperature T _{ME is} calculated in its end, wherein the water temperature in the initial region of the next connected subsection equal to the water temperature T _ME in the end region of the given subsection, than is selected.

In a further embodiment of the invention, it is provided that the sections are formed axially uniform over the length between their initial region and its end region with respect to their heat - coupling with the environment, thus does not change axially. This allows a simplification of the calculations.

In a further embodiment of the invention, it is provided that in the end region of at least one partial section of length L, the water temperature T _{ME is determined} by means of the formula

is determined, where

 This formula allows a good approximation of the temperature change for uniform sections.

In a further embodiment of the invention it is provided that the heat transfer coefficient of the sections according to the formula

is determined, where

and

The following will be In order to determine the temperature changes and heat gain in the water due to the difference in temperature with the environment, equations 1-4 are used below.

For this purpose, equation 1 is used for the thermal resistance in equation 2 and thus the heat transfer resistance is determined. With the reciprocal of equation 2, the heat transfer coefficient equation 3 is calculated.

Thermal resistance of a pipeline incl. Insulation

Equation 1, see VDI 2055, 2008

Thermal resistance of the insulated pipeline

Equation 2, see VDI 2055, 2008

Heat transfer coefficient U _{R of} the insulated pipeline

 The heat transfer coefficient is a central component of equation 4 for calculating a temperature at the end of a section.

With the help of equation 4, the respective initial and final temperatures of the cold water are determined for all relevant sections. The derivation of the formula for the axial heating of water in a pipeline begins with Equation 5:

Equation 5, see VDI 2055, 2008

insert from and then summarize.

 An iterative calculation by incremental / incremental increase of the volume flow, the volume flow is sought, which operates the cold water installation, with a desired / predetermined spread of, for example, 5 K (15 ° C / 20 ° C).

With the help of this approach, in addition to the determination of a volume flow of the circulation system in the foreground, a water temperature can also be determined for any point in the considered pipe network.

Preferably, the iterative approximation method is the per se known Excel target value search; see Excel and VBA: Introduction to practical applications in the natural sciences by Franz Josef Mehr, Maria Teresa Mehr, Wiesbaden 2015, section 8.1.

According to the invention, key data of the line system, including the above-mentioned parameters of the sections, are entered into the program and the volume flow V _{z is} determined by means of the target value search, at which the target drinking water temperature T _{b is} reached; for example, as follows 3.1 .1 Sfoffwerfe water

3.1 .2 heat transfer coefficients

3.1 .3 ambient temperatures

3.1 .4 Insulation

3.1 .5 pipe materials

In this example, the calculated volumetric flow V _z , at which, with an inlet temperature T _a of 15 ° C, a target temperature Tb of 20 ° is reached, is indicated in the line MT4.

In a further embodiment of the invention it is provided that in the circulation system, a circulation pump is integrated, whereby a desired volume flow can be adjusted.

It is understood that several cooling devices and / or circulation pumps can be provided.

In the following, embodiments are described with line structures, as they are typically used in drinking water installations in buildings.

A connection line is a line between a supply line and a drinking water installation or the circulation system. A consumption line is a line that places water from the main shut-off valve to the extraction ports and, if necessary, directs it into equipment. A common supply line is a horizontal supply line between the main shut-off valve and a riser. A riser leads from floor to floor and from which the floor ducts or single ducts branch off. A floor duct is the duct which branches off from the riser (trunk) duct within a floor and branches off from the individual ducts. A single supply line is the leading to a sampling point line.

In one embodiment of the invention it is provided that at least one flow line is connected to at least one ring line.

In a further embodiment of the invention, it is provided that at least one branch of the circulation line goes off from the at least one feed line.

In a further embodiment of the invention, it is provided that at least one branch of the at least one circulation line leaves from the at least one ring line.

In a further embodiment of the invention it is provided that the at least one flow line comprises at least one riser and / or a floor duct.

In a further embodiment of the invention it is provided that the at least one flow line comprises a common supply line, which is connected to a connection to a water supply network.

In a further embodiment of the invention it is provided that the connection is connected to at least one connecting line and / or at least one consumption line.

In a further embodiment of the invention, it is provided that at least one static or dynamic flow divider is arranged in the at least one feed line and / or the at least one ring line, with which preferably a discharge point for water is connected. Preferably, a percentage distribution of the volume flows 95% at the outlet and 5% at the passage.

In a further embodiment of the invention it is provided that by means of the cooling device for cooling the circulating water thermal energy is transferred from the circulating water to another stream, preferably by means of a heat exchanger, thereby optimizing the cooling process suitable choice of the other material stream, for example propane, and a reduction in the energy required to operate the cooling device can be achieved.

In a further embodiment of the invention, it is provided that the cooling device is thermally coupled to a cold generator, preferably a heat pump, a chiller or a cold supply network, whereby also a reduction of the energy required for the cooling process can be achieved.

In a further embodiment of the invention, determining a consumption characteristic of the circulation pump as a function of the delivered volume flow of the circulation pump and determining a consumption characteristic of the cooling device as a function of a water temperature at the output port and setting a volume flow V _z and a water temperature T _a at the output port, so that the power consumption of the circulation pump and the cooling device assumes a relative or absolute minimum value, which improves the energy efficiency of the method.

In a further embodiment of the invention, it is expediently provided that a value of 20 ° C. +/- 5 ° C. is chosen for the temperature T _soll and a value of 15 ° C. +/- 5 ° C. is selected for the water temperature T _a at the outlet port becomes.

In a further embodiment of the invention, it is provided that at least part of the line system is designed as an outer circulation line, since external circulation lines are usually installed in already existing circulation systems.

In a further embodiment of the invention, it is provided that at least one partial section is designed as an inliner circulation line, since these are frequently installed in newer or new circulation systems.

Further advantages emerge from the following description of the drawing.

In the drawings, embodiments are shown in the description. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations.

They show by way of example:

Figure 1: a schematic representation of an inventive circulation system Figure 2: another embodiment of a circulation system according to the invention Figure 3: a further embodiment of an inventive circulation system, wherein a further heat exchanger is provided

 FIG. 4: a further embodiment of a circulation system according to the invention FIG. 5: a further embodiment of a circulation system according to the invention FIG. 6: a further embodiment of a circulation system according to the invention FIG. 7: a further embodiment of a circulation system according to the invention FIG. 8: a further embodiment of a circulation system according to the invention

The circulation systems illustrated in FIGS. 1 to 8 are only examples, without the invention being restricted to these systems. In all the systems shown, exactly one volume flow flows into a node, and one volume flow, or exactly one volume flow flows in and precisely two volume flows, for example in the case of a T-piece. However, the invention is not limited to systems with such nodes. Basically, all the lines shown between nodes and between nodes and input port and node and output port consist of one or more legs, as defined above.

Similar components are provided with the same reference numerals.

In the circulation system shown in FIG. 1, a node K1 is over one

Flow line 4a connected to an output port 12b of a cooling device 12. The cooling device 12 has cold-circuit-side connections as well as a cold-circuit-side pump 13.

At node K1, a branch to a manifold 4, a connection line to a connection 1 to a water supply network and a consumption line 3 is provided, the latter and the connection line not belonging to the circulation system. At node K1, therefore, no volume flow distribution takes place.

The collective supply line 4 is connected to a riser 5, which opens into a node K2. The node K2 branches into a floor duct 6 and a riser 5, which opens into a node K3 and at which a branch to a floor duct 6 and a riser 5 takes place, is connected to a floor duct 6, which opens into a node K4. The node K2 is connected via a floor duct 6 to a node K6.

The node K3 is connected via a floor duct 6 to a node K5. Two subsections TS1 and TS2 explicitly identified as such are connected via the node K4, TS1 subsection of the floor line 6 and TS2 representing a circulation line.

At node K4 also takes place a branch via a single feed line 7 to a

Outlet 9 takes place. For simplicity, the individual feeders and tapping points connected to the nodes K2 and K3 are not provided with reference numerals. Since that

The circulation system according to the invention for carrying out the method according to the invention is operated in a state in which no water extraction takes place, in the following such nodes which are assigned to sampling points are excluded from consideration and, with the exception of node K4, are not included in the drawings

Provided with reference numerals.

The section TS2 is shot at a vertical circulation line 10a, which opens into the node K5. The node K5 is connected to a circulation line 10a, which opens into the node K6. The node K6 is connected to a vertical circulation pipe 10a which is connected to a horizontal circulation pipe 10a, which in turn is connected to the circulation pump 10b via a vertical circulation pipe.

The circulation system shown in Figure 2 has an analogous structure, as the system of Figure 1, but 6 ring lines are provided in the floor ducts, with a reference numeral 8 is used for simplicity only in the uppermost ring line shown in Figure 2. The ring line 8 is associated with an optional flow divider 8a.

Ring lines are assigned to nodes K21 to K32. It is understood that even those systems in which only one loop is present, are included in the invention.

FIG. 3 shows another system with nodes K31 to K34, in which, however, the circulation lines 10a leading into the nodes K34 and K35 are guided parallel to the floor lines 6 emanating from the nodes K32 and K33.

Furthermore, an optional decentralized cooling device 14 with an input port 14a and an output port 14b is arranged in the uppermost floor duct 6, with existing connections of a cold-side circuit as well as a connection for simplifying the illustration

corresponding pump are not shown.

Analogously, further decentralized cooling devices can be arranged in the other floor ducts. In a further embodiment analogous to Figure 3, the heat exchanger 12 may be omitted, in which case a cooling device 14 or more

Cooling devices 14 are mandatory.

3, cooling devices can be provided in the riser ducts 5 or the floor duct of the embodiments of FIGS. 1, 2 and 4 to 8.

Figure 4 shows a system with nodes K41 to K51 as in Figure 3, but in the

Floor ducts 8 ring lines are provided.

FIG. 5 shows a system with nodes K51 to K55, in which circulation lines 10 are guided parallel to the risers 5 connected to the nodes K52, K53.

FIG. 6 shows a system with the nodes K61 to K69b, wherein ring lines are provided between the nodes K63, K64, K66, K67 and K68, K69.

Figure 7 shows a system with the nodes K71 to K75, wherein risers 5 are connected to the nodes K72 and K73.

FIG. 8 shows a system with nodes K81 to K89b analogous to FIG. 7 but with ring lines arranged between nodes K89a, K89b, K88, K89 and K84 and K85.

The embodiments shown in the pure drawings under FIGS. 1, 3, 5, 7 can also circulate only partial areas. So the sections can also z. B. represent installations in homes that may not mitzirkulieren due to various requirements (billing of water consumption). A water exchange to maintain the desired temperature was possible here by automatic dishwashers.

The method according to the invention is carried out in the systems of FIGS. 1 to 8 in the manner described above, starting from a temperature start value T _MA * <T _soi , and a volume flow starting value V _z ^* for the first to the output port (12b). connected sub-section a temperature change of the water between initial area and end area is determined according to a model of the temperature change.

Further, a change in the temperature of the water between the start region and the end region for any given further part of the distance becomes according to the model of the temperature change determines, under the boundary condition, that the water temperature in the initial region of the given sub-route is equal to the water temperature in the end region of the sub-route to which the given sub-route is connected.

Preferably, the above-described model of the axial temperature change is used, whereafter, in the end region of a segment of length L, the water temperature T _{ME is determined} by means of the formula

calculated.

The value T _{a of} the water temperature and the value V _{z of} the volumetric flow at the outlet port 12b are selected such that the water temperature T _ME <T _soll in the end region of each section of the circulation system and the water temperature T _b <T _soll at the input port 12a _Let - T _b <Q, where q> 0 is a given value.

It is understood that the circulation pump 10b is not always operated with a constant volume flow, that is, regardless of whether the port inlet temperature 12a has exactly the set value or even lower.

If the Porteingangstemperatur 12a for various reasons z. B. at 17 ° C, z. B. max. 20 ° C are given, the delivery flow rate of the circulation pump 10b could be reduced. This can be done, for example, temperature-controlled automatically. The result would be energy savings.

Likewise, in such a case, the delivery volume flow of the pump 13 can be reduced in temperature-controlled manner.

If the Porteingangstemperatur for various reasons z. B. at 17 ° C are (for example, maximum 20 ° C are given), could also be adapted to the flow temperature in the refrigeration cycle. The result would be energy savings.

LIST OF REFERENCE NUMBERS

Connection to a water supply network

connecting cable

 consumption line

 collecting supply

 Climb (fall) line

 Floor line

 Single supply

 loop

a static or dynamic flow division

 sampling point

0 circulation system

0a circulation line

0b circulation pump

2 cooling device

2a input port

2b output port

4 heat exchangers

4a input port

4b output port

Claims

claims

1. A method for operating a circulation system (10) with a cooling device (12,

 14) having an input port (12a, 14a) and an output port (12b, 14b) for cooling water and having a manifold having a plurality of strands which have one or more portions of given heat coupled to an environment and connected by nodes, wherein one or more of the lines of the line system are designed as a feed line (4, 5, 6), at least one individual feed line (7) connected to a removal point (9) and at least one line designed as a circulation line (10a) with the feed line (s) (4 , 5, 6), with the steps

Setting a water temperature at the output port (12b, 14b) to a value T _a by means of the cooling device (12, 14)

Setting a volume flow at the input port (12a) to a value V _z characterized by the following steps

Determining, in particular, a temperature change of the water between the starting region and the end region according to a model of the axial temperature change for the first partial path connected to the output port (12b, 14b), starting from a temperature start value T _MA * <T _soi , and a volume flow Start value V _z ^* ,

Determining, in particular, calculating a temperature change of the water between the starting region and the end region for each further given sub-route according to the model of the temperature change, under the condition that the water temperature in the initial region of the given sub-route is equal to the water temperature in the end region of the sub-route to which the given sub-route is connected and

Selecting the value T _{a of} the water temperature and the value V _{z of} the volume flow at the output port (12b, 14b) such that in the end region of each leg the water temperature T _ME <T _soll and is at the input port (12a, 14b) sets the water temperature T _b <T _soll with T _soll - T _b <Q, where q> 0 is a predetermined value.

2. Method according to claim 1, characterized in that the values T _a and V _{z are determined} in an iterative approximation method in which, based on a temperature start value T _MA * <T _soll and a volume flow start value V _z ^* for the first at the output port (12b, 14b) connected to the sub-section, the temperature change of the water between the starting region and end region is calculated under the boundary condition that the water temperature in the starting region of the given sub-section is equal to the water temperature in the end region of the sub-section the given leg is connected.

3. The method according to claim 1 or 2, characterized in that the sections are formed over the length between their initial area and its end with respect to their heat - coupling with the environment uniform.

4. The method according to claim 3, characterized in that in the end region of at least one section of length L, the water - temperature T _ME by means of the formula

 is determined, where

5. The method according to claim 4, characterized in that the heat transfer coefficient of the sections according to the formula

 is determined, where

and

6. The method according to any one of the preceding claims, characterized in that in the circulation system (10), a circulation pump (10b) is integrated.

7. The method according to any one of the preceding claims, characterized in that by means of the cooling device (12, 14) for cooling the circulating water thermal energy is transferred from the circulating water to another stream, preferably by means of a heat exchanger.

8. The method according to claim 7, characterized in that the cooling device (12,

 14) is thermally coupled to a cold generator, preferably a heat pump, a chiller or a refrigeration network.

9. The method according to any one of claims 6 to 8, characterized by

Determining a consumption characteristic of the circulation pump (10b) as a function of the delivered volume flow of the circulation pump (10b) Determining a consumption characteristic of the cooling device (12, 14) as a function of a water temperature at the output port (12b, 14b)

Adjusting a volumetric flow V _z and a water temperature T _a at the output port (12b, 14b) such that the power consumption of the circulation pump (10b) and the cooling device (12, 14) assumes a relative or absolute minimum value.

10. The method according to any one of the preceding claims, characterized in that for the temperature T, a value of 20 ° C +/- 5 ° C _to selected and for the water temperature T _a at the output port (12b, 14b), a value of 15 ° C +/- 5 ° C is selected.

11. Circulation system with a cooling device (12, 14) having an input port (12a,

 14a) and an outlet port (12b, 14b) for cooling water and having a conduit system with a plurality of strands which have one or more sub - sections with given heat coupling to an environment and are coupled by means of nodes, wherein for a given division of the out of the nodes outgoing flow rates a mixed water temperature of the outflowing out of the node volume flows in dependence on the incoming into the node flow rates can be determined, wherein one or more of the lines of the conduit system as a flow line (4, 5, 6) are formed, at least one with a removal point (9) connected single feed line (7) and at least one as a circulation line (10a) formed line with the one or more flow lines (4, 5, 6) is connected, with

Means for adjusting the water temperature at the outlet port (12b, 14b) to a value T _a by means of the cooling device (12, 14)

Means for adjusting a steady-state volume flow of circulating water at the input port (12a, 14a) to a value V _z characterized by Device means for determining a change in temperature of the water between the starting area and end of each section under the boundary condition that the water temperature is selected in the end of a given sub-section equal to the water temperature in the initial range of connected in the flow direction of the circulating water to the given sub-section and

Device means for selecting the value T _{a of} the water temperature and the value V _{z of} the volumetric flow at the output port (12b, 14b), such that in the end region of each subsection the water temperature T _ME <T _soll and at the input port (12a, 14a) the water temperature T _b <T _{is set} with T _soll - T _b <Q, where 0> 0 is a predetermined value.

12. Circulation system according to claim 1, characterized in that device means are provided for determining the values T _a and V _z in an iterative approximation method, starting from a temperature start value T _MA * <T _soll and a volume flow starting value V _z ^* for the first section connected to the output port (12b), for each given section the water temperature T _{ME is} calculated in its end zone, the water temperature T _MA 'in the initial section of the next connected section being equal to the water temperature TME is selected in the end of the given leg.

Circulation system according to claim 11 or 12, characterized in that the sections are formed uniformly over the length between their initial region and their end region with respect to their heat coupling with the environment.

14. Circulation system according to claims 1 1 to 13, characterized in that in the circulation system (10) a circulation pump (7) is integrated.

15. Circulation system according to one of the preceding claims, characterized in that at least one flow line (4, 5, 6) with at least one ring line (8) is connected.

16. Circulation system according to one of the preceding claims, characterized in that at least one line of the circulation line (10a) from the at least one flow line (4, 5, 6) goes off.

17. Circulation system according to one of the preceding claims, characterized in that at least one line of the at least one circulation line (10a) leaves the at least one ring line (8).

18. Circulation system according to one of the preceding claims, characterized in that the at least one flow line (4, 5, 6) comprises at least one riser (5) and / or a floor duct (6).

19. Circulation system according to one of the preceding claims, characterized in that the at least one flow line (4, 5, 6) comprises a collecting feed line (4) with a connection (1) to a

Water supply network is connected.

20. Circulation system according to one of the preceding claims, characterized in that the connection (1) is connected to at least one connecting line (2) and / or at least one consumption line (3).

21. Circulation system according to one of the preceding claims, characterized in that in the at least one flow line (4, 5, 6) and / or the at least one ring line (8) at least one static or dynamic flow divider (8a) is arranged.

22. Circulation system according to one of the preceding claims, characterized in that by means of the cooling device (12, 14) thermal energy is transferred from the circulating water to another stream, preferably by means of a heat exchanger.

23. Circulation system according to claim 22, characterized in that the

 Cooling device (12, 14) thermally coupled to a cold generator, preferably a heat pump, a chiller or a refrigeration network.

24. Circulation system according to claim 23, characterized in that at least a part of the line system is designed as an outer - circulation line.

25. Circulation system according to claim 24, characterized in that at least one partial section is formed as an inliner circulation line.

26. Circulation system according to one of claims 1 1 to 25, characterized in that the cooling device (12) is connected with its output port (12b) to a flow line (4a) and with its input port (12a) to a vertical circulation line.

27. Circulation system according to one of claims 1 1 to 26, characterized in that the cooling device (14) in a riser (5) and / or a floor duct (6) is integrated.