WO2010078957A2 - Pressure-reducing element for splitting the recooling volume flow in sorption machines - Google Patents

Abstract

The invention relates to the use of a pressure-reducing element for splitting volume flows in a sorption machine, wherein a single volume flow from a recooling device is split into at least two volume flows. A first volume flow flows though at least one tube of a first tube section into a condenser and a second volume flow through at least one tube of a second tube section into an adsorber, at least one of the two tube sections leading away from the recooling device or at least one of the two tube sections leading back to the recooling device comprising at least one pressure-reducing element.

Description

 A pressure-reducing element for dividing the recooling volume flow in sorption machines

The invention relates to the use of a pressure-reducing element for dividing volume flows in a sorption machine as well as in an adsorption refrigerator and also to a method for dividing the volume flows in a sorption machine.

In the prior art chillers are described, which are generally used for heating and / or cooling of buildings. Chillers implement thermodynamic cycles, where, for example, heat is absorbed below the ambient temperature and released at a higher temperature. The thermodynamic cycles are similar to those of a heat pump. Known in the art refrigerators are z. As adsorption refrigeration systems, diffusion absorption refrigeration machines, adsorption refrigeration or Feststoffsorptionwärmepumpen and compression refrigeration systems.

The Adsorptionskältemaschine consists of an ad / Desorber unit, an evaporator, a condenser and / or a combined evaporator / condenser unit, which are housed in a common container or in separate containers, which then with pipes o. Ä. For the Refrigerant flow are interconnected. The advantage of sorption compared to conventional heat pump technology is that the expiration of the adsorption / desorption takes place solely by the temperature of the sorbent. Thus, the container of the adsorption machine can be hermetically sealed and gas-tight. When using, for example, water as a refrigerant, the adsorption chiller preferably operates in the vacuum range. Due to the very low density of the refrigerant in the vacuum range, this sometimes leads to very high flow velocities (for example 25 m / s-100 m / s or greater) of the vaporous refrigerant. Accordingly, the vapor flows within an adsorption machine must be carefully designed to avoid unnecessary pressure losses of the vapor flow. The adsorption taking place in an adsorption machine describes a physical process in which a gaseous refrigerant (for example water) attaches to a solid, energy being transferred from the refrigerant to the solid during the addition. The desorption of the refrigerant, that is, the dissolution of the refrigerant from the solid, again requires energy. In an adsorption chiller, the refrigerant, which absorbs heat at a low temperature and low pressure and releases heat at a higher temperature and pressure, is selected such that a change in state of aggregation is associated with the adsorption or desorption. As adsorbent materials are described in the prior art, which are finely porous and therefore have a very large inner surface. Advantageous materials are activated carbon, zeolites, alumina or silica gel, aluminum phosphates, silica-aluminum phosphates, metal-silica-aluminum phosphates, mesostructure silicates, metal-organic frameworks and / or microporous material comprising microporous polymers.

In the process of adsorption, the heat of adsorption and the heat of condensation must be removed from the plant. This is usually done via a flowing heat transfer medium that transports this heat to a heat sink, e.g. to a recooling plant, which releases the heat to the ambient air. However, if the heat of adsorption and / or the

Condensation heat is not or poorly dissipated, the temperatures and thus the pressures within the adsorption would rise and the adsorption process would come to a standstill. Thus, the efficiency of an adsorption machine can be significantly increased by improved heat transfer, which inevitably improves the efficiency of the system.

Different sorption machines are disclosed in the prior art, in which the heat transfer medium usually flows through a string with heat exchangers (adsorber or condenser), hydraulic piping, hydraulic components (eg valves). For example, DE 3207 435 A1 describes a control and regulating device for a sorption heat pump. The control and regulating device measures the temperature in the circuit of a consumer fluid and adjusts the volume flows depending on the temperature. The control of the currents via a known in the art 3-way valve. The document EP 0 152 931 discloses a generator absorption heat pump heating system and a method for operating a generator absorption heat pump heating system for space heating, hot water preparation and the like. In the absorption heat pump, a switching valve is integrated, whereby the heat transfer fluid is passed alternately to an adsorber and condenser.

In the sorption machines disclosed in the prior art, the total volume flow of the heat transfer medium coming from the recooler is usually divided into a volume flow passing through the adsorber and into a volume flow passing through the condenser. Depending on the volume flow distribution, different temperatures of the adsorber and the condenser can thus be adjusted in particular at the end of the recooling phases. However, it may be advantageous, depending on the operating point, operating mode, built-in components or system configuration, to cool the adsorber and / or condenser equally or unequally.

In order to achieve this, in the prior art, the heat transfer fluid coming from the recooler is divided between the adsorber and the condenser and passed in parallel through the adsorber and condenser, the total volume flow remaining constant. Depending on the pressure losses within the adsorber and condenser, as well as the associated pipe sections and hydraulic components (eg valves), the volume flow in the mold is distributed over both strands so that the same pressure loss is applied in both strands. With an interpretation of the pressure losses of the strands can always be made very inaccurate for a specific operating point adjustment - a desired fine tuning is not possible because, for example, commercial nominal pipe sizes or valve sizes are available only in increments with respect to the diameter. If both strands in the installation achieve exactly predetermined pressure losses, a change in the design volumetric flow rate is not possible without simultaneously influencing the level of the pressure losses. Those disclosed in the prior art

Sorption machines, do not allow targeted adaptation or optimization of the distribution of the volume flow, whereby no higher performance or better efficiency can be achieved. The object of the invention was accordingly to achieve a variable distribution of the volume flows between adsorber and condenser, whereby the disadvantages of the prior art do not arise and an improvement in the performance of sorption machines is achieved.

The object is surprisingly achieved by the features of the independent claims. Advantageous embodiments will be apparent from the dependent claims.

It was surprising that the use of a pressure-reducing element for dividing volume flows in a sorption machine can be provided and in the division not the disadvantages described in the prior art arise. For the purposes of the invention, a total volume flow coming from a recooling device is divided into at least two volume flows. A first volume flow flows through at least one pipe of a first pipe section into or through a condenser and a second volume flow through at least one pipe of a second pipe section into or through an adsorber. In this case, at least one of the two coming from the recooling device or the two returning to this pipe or pipe sections at least one pressure-reducing element. Advantageously, in this way, the two pipe sections or pipes essentially have different pressure loss coefficients. It is advantageous and surprising that the pressure-reducing element can influence the ratio of the pressure loss coefficients of both pipe sections; Thus, the pressure-reducing element can surprisingly adapt and / or set the pressure loss coefficients of the two pipe sections or paths. By using the pressure-reducing element, it is possible, depending on the operating point, mode of operation, built-in component or system configuration to divide the volume flows between adsorber or condenser or make an adjustment or tuning of the pressure loss coefficients of the pipe sections, without having to make a change in apparatus. It can be achieved as an apparatus simple and inexpensive distribution of the volume flows between preferably adsorber and condenser or a vote of the pressure loss coefficients in the pipe sections. The volume flows or the pressure loss coefficients can be adapted to different boundary conditions, operating phases and / or modes of operation or even adapted to built-in components. The pressure-reducing element enables a simple division of the volume flow ratio between preferably adsorber and condenser, whereby in particular a different cooling of adsorber and condenser is achieved. It is known to a person skilled in the art that the pressure loss designates the pressure difference resulting from wall friction and internal fluid friction in pipelines. This means that due to at least one pressure-reducing element, the pressure loss in the two strands coming from the recooler is preferably non-identical, that is, the pipe sections or the volume flows essentially have a different pressure loss or different pressure loss coefficients. The term "essentially" does not represent an unclear formulation for the skilled person with regard to the pressure loss, since he recognizes by the overall disclosure of the teaching according to the invention that the pressure loss is preferably different in the two volume flows and this formulation of course detects both small and large pressure losses alike. The different pressures can be determined, for example, by measuring methods described in the prior art The person skilled in the art is familiar with the concept of the pressure loss coefficient and knows how to relate it to the teaching according to the invention Advantageously, the pressure-reducing elements may also be incorporated into the tubes coming from the adsorber and / or condenser (leading to the recooler or recooling device) g returning pipes). This can be advantageous in particular in multi-chamber adsorption machines.

The person skilled in the art knows that operating points may designate certain points in the characteristic diagram or on the characteristic curve of a technical device, preferably a sorption machine, particularly preferably an adsorption chiller or adsorption heat engine, which are adopted on the basis of the system properties and acting external influences and parameters. Examples include the temperatures of the heat sinks and sources or total volume flows in the recooling circuit in the evaporator or Desorberstrang. In particular, a volume flow is understood by the person skilled in the art to mean the volume of a medium which moves within a unit of time through a cross section, in particular of a pipe or a pipe section. Consequently, the total volume flow especially includes the entirety of the volume flows, preferably in one machine.

The mode of operation within the meaning of the invention preferably designates the mode of operation of the machine. Examples include the adaptation of the cycle times of the sorption, that is, by short cycle times, the performance of the machine can be increased, whereas longer cycle times lead to higher efficiency.

The built-in components may for example denote adsorber heat exchangers which are provided with the same pressure but different adsorption material. The adsorption material may advantageously be applied differently, that is, it may be a bed, a bond and / or crystallization. Due to these different types of application, the adsorption machine can be adapted to different requirements. So the machine can be adapted to the location or the refrigerant. In addition, the layer thickness of the adsorbent material is critical to the performance of the adsorbent material.

Within the meaning of the invention, the system configuration preferably designates the configuration of the machine, that is, for example, the internal hydraulic interconnection of the components of the machine, the internal cold connection of the components or the changed basic structure of the machine (eg number of adsorbers, operation of the evaporator) , the capacitor, etc.).

A recooler or a recooling device designates in the sense of the invention, in particular, a device in order to preferably cool the heat transfer fluid, that is, to dissipate the absorbed energy to another fluid or medium. A recooler may include, for example, a geothermal heat exchanger, a swimming pool, a well, or other device for cooling or absorbing the heat energy. The volume flow flowing through the machine is preferably a heat transfer fluid, that is a fluid that can absorb and release energy in the form of heat. Preferred heat transfer fluids include Water or brine. These are particularly environmentally friendly and cheap from the purchase. In addition, the performance characteristics of water and brine are optimal for a sorption machine. In addition, both designate a large heat storage, the heat can also be released quickly.

The pressure-reducing element can advantageously be regulated or adjusted so that, for example, at the beginning or end of an operating phase, a strand is preferably no longer flowed through and the entire volume flow flows into the remaining strand. Thus, a component or a component can be cooled quickly and efficiently, and the performance of the sorption machine is significantly improved. This represents a departure from the technical standard and opens up a new technical field, since by using the pressure-reducing element, no apparatus adaptations to different operating modes of a sorption machine, preferably an adsorption machine, are more necessary. This in turn leads to a reduction in manufacturing costs and a universal replaceability of the machines.

The pressure-reducing element is advantageously integrated into a tube in such a way that the cross-section of the flow is reduced and thus a variable adjustment of the volume flow is possible. Surprisingly, the pressure-reducing element produces a particularly high degree of efficiency, in particular in adsorption machines comprising adsorption heat engines and adsorption chillers. Particularly preferred are sorption machines in which the condenser and / or adsorber are heat exchangers. The heat exchanger is a device that transfers thermal energy preferably from one material stream to another.

Advantageously, the pressure-reducing element and for 1-chamber systems, for example with 2 adsorbers, but also for 2- or multi-chamber systems, each with only one adsorber of a sorption, for example, an adsorption machine can be used. In addition, it can be easily and quickly adapted to other types of sorption machines. Essentially, the machines do not have to be modified in terms of apparatus. The pressure-reducing element is preferably a throttle, a valve or a stopcock. The elements can be integrated into a tube and cause a local narrowing of the flow cross-section. Advantageously, different valves, which can be classified according to their geometric shape, be integrated into the tubes. In this case, valves comprising through valves, angle valves, angle seat valves and / or three-way valves can be used. By using the valves, the flow rates in the pipes can be accurately and precisely metered, as well as secure against the environment. The valves can advantageously be operated by hand, by medium, mechanically or electromagnetically and thus enable an exact and secure control of the volume flows. A throttle is in the context of the invention preferably a conical piece of pipe within a pipeline, concentric or eccentric reductions are also preferred.

In a further preferred embodiment, the pressure-reducing element is an aperture and / or a built-in component. A built-in part includes, for example, a reduced cross-section of a casing or parts of the casing of a strand, a T-piece with reduced outlet or a sleeve, aperture, fitting or measuring, control or control device with reduced cross-section. The specialist in rheology / fluid mechanics knows how such a built-in component can be integrated into a pipe. The pressure-reducing or cross-section-reducing elements can advantageously be integrated into one or more tubes, and it may be advantageous to make these adjustable and variable. This means that the pressure-reducing elements can be controllable or self-regulating, whereby preferably at any time and boundary condition, the optimal or preferred volume flow distribution can be adjusted, as the flowing through

Cross section of the tubes can be reduced or increased. It can be changed so easily but effectively the flowing through the pipe volume. The adjustability of the pressure-reducing element can be realized manually, for example by means of a manual tap. However, it may also be preferred that the adjustment of the pressure-reducing element and thus of the flow-through pipe cross-section is automatic and / or self-regulating. Here, the pressure-reducing element may be provided with measuring and control devices, for example, measure the pressure in the tube and based thereon, the Nominal diameter of the tube, that is to change the cross-section of the tube by the pressure-reducing element.

It may thus be preferred that the pressure-reducing element changes the nominal diameter of the pipes or of the pipe or the cross-section of the free flow such that the volume flows with different and / or same

Press in the heat exchanger, wherein the heat exchanger is preferably the adsorber or the condenser.

In a further preferred embodiment, at least one measuring and / or regulating device is installed between the recooler and the adsorber and / or condenser. The device measures in particular physical properties of the volume flow, including temperature, pressure and / or flow rate. The device is advantageously attached to at least one tube such that, for example, a measuring probe is present in the tube and is in contact with the fluid flowing through the tube. The measured quantities are digitized and output as data.

Advantageously, it is also possible to store the measured data and to use it for comparative experiments, whereby an optimization of the sorption machine is possible. It may be preferred that the measured data - the so-called actual values - are compared with predetermined target values and that a possibly existing difference leads to the fact that the

Control device preferably varies the pipe size or the cross section of the free flow over the pressure-reducing element. It is possible such a continuous and substantially trouble-free operation of the machine. In addition, the machine can be quickly and easily adapted to different modes of operation. For this purpose, the desired values preferably correspond to values which define a specific mode of operation.

The technical problem is also solved by the use of a pressure-reducing element, which is used for dividing volume flows in particular an adsorption machine. Here, a total volume flow, which comes from a recooling device, divided into at least two volume flows, wherein a first volume flow through at least one pipe of a first pipe section in a condenser and a second volume flow through at least one further pipe of a second pipe section in an adsorber flows. At least one of the two coming from the recooling or the two returning to this pipe or pipe sections, has at least one pressure-reducing element. Advantageously, the two pipe sections have a substantially different pressure loss coefficient. It was completely surprising that a pressure-reducing element which can divide the volume flows between adsorber and condenser into at least one pipe or a pipe section of an adsorption machine, preferably an adsorption chiller, very particularly preferably an adsorption heat machine, and thus the mode of operation of the machine easily and quickly to different Requirements is customizable. It has surprisingly been found that the pressure-reducing element having an adsorption machine is universally applicable and can be operated at different locations and at different outdoor temperatures. The pressure-reducing element preferably reduces the nominal diameter or the cross section of the free flow of at least one tube, wherein the element is self-regulating or can be regulated. It has also been shown that the element can be retrofitted into the adsorption machines and this results in low costs, ie the machine can advantageously be easily and inexpensively supplemented by one or more elements. In addition, it was surprising that due to the pressure-reducing element and the distribution of the volume flows, the components of the adsorption machine comprising adsorber or condenser less maintenance, since the components are used more efficiently and gently.

The invention further relates to a method for dividing volume flows in a sorption machine, wherein a total volume flow of a

Recooling coming, is divided into at least two flow rates, and a first volume flow through at least one pipe of a first pipe section flows into a condenser and a second flow through at least one pipe of a second pipe section in an adsorber, wherein at least one of the two coming from the recooling or the two pipe sections leading back to this has at least one pressure-reducing element and the two pipe sections have a substantially different pressure loss coefficient. By integrating a pressure-reducing element, the volume flows can be easily between preferably the adsorber and capacitor to be split. However, it may also be preferred that the pressure or pressure loss coefficients in both strands or pipes are identical. Advantageously, the volume flow between adsorber and condenser is divided such that the two volume flows or pipe sections have a substantially different pressure loss or

Have a pressure loss coefficient. It was completely surprising that by at least one pressure-reducing element, a division and influencing or adaptation or tuning of the volume flows and an adjustment or tuning of the pressure loss coefficients can be achieved and thereby the efficiency of the sorption, preferably the adsorption improved.

The invention will be explained in the following with reference to figures by way of example, but without being limited to these. Show it:

Fig. 1 Rückkühlstränge an adsorption heat pump

Fig. 2 pressure reducing elements in the Rückkühlsträngen

Fig. 3 pressure reducing elements in the Rückkühlsträngen below

Consideration of the heat source string

FIG. 1 shows, by way of example, the recooling strands of an adsorption heat pump disclosed in the prior art. The Rückkühlstränge denote the coming of the recooler 11 tubes 9 or strands or pipe sections and the arrows shown represent the preferred flow direction of the heat transfer fluid. After the adsorption of the refrigerant, energy is transferred in the form of heat from the refrigerant to the heat transfer fluid, such as water. The heated heat transfer fluid must then be cooled, otherwise the thermodynamic process of heat transfer would come to a standstill and thus the refrigerant is difficult to adsorb. The cooling of the heat carrier can be done for example in a recooler 11 in which the heat of the heat carrier is transferred to another heat receiver. For example, air (an air stream 10) or water (dry or wet cooling technology) can serve as potential heat receivers. The cooled heat carrier flows from the recooler 11 through the tubes 9 or pipe sections (through two strands) in parallel into the adsorber 13 and the condenser 14, wherein the volume flow of the heat carrier is divided, but the total volume flow remains constant. Furthermore, a heat source 12 can be connected to the heat carrier circuit. The connection of the heat source 12 is optionally shown in the form of dashed lines. The dashed lines represent, like the uninterrupted lines, pipes 9, or pipe strands. The heat carrier, after it has absorbed heat in the adsorber 13, preferably flows into the heat source 12, where it can release the heat. The heat can be used for example for air conditioning. Depending on the pressure losses occurring within the adsorber 13 and the condenser 14, as well as the associated pipe sections and hydraulic components (eg valves) 16, the volume flow in the mold is distributed over both strands, that is in both strands, ie in adsorber 13 and condenser 14, the same pressure loss is applied. The volume flow can consequently be divided by the pressure losses between the adsorber 13 and the condenser 14. However, this is a very inaccurate method that can only be optimized empirically. In addition, with the interpretation of the pressure losses of the strands only an insufficient adjustment of

Volumes are made to a specific operating point - a desired fine tuning is not possible because, for example, commercially available pipe sizes or valve sizes are available only in increments with respect to the diameter. It can not be achieved by this optimal distribution of the flow rate.

Fig. 2 shows an integration of pressure-reducing elements in the Rückkühlstränge. After cooling the heat transfer fluid in the recooler 11 by preferably an air stream 10, the heat transfer medium flows into the adsorber 13 and the condenser 14. In the adsorber 13, the heat transfer medium preferably absorbs heat from the adsorbed refrigerant and thus accelerates its adsorption. In the condenser 14, the heat carrier can catalyze the condensation of the refrigerant and also absorb heat from it. In order to adapt the volume flows of the heat carrier from the recooler 11 to preferably the mode of operation of the sorption machine, in particular adsorption machine is at least one pressure-reducing element 15 integrated into one or more tubes 9 or pipe sections, whereby the pipe sections have different pressure loss coefficients. Preference is given to the installation of at least one element 15 in at least one of the recooler 11 coming pipe 9 or pipe run or pipe strands, and it may also be advantageous to install each a pressure-reducing element 15 in both pipe strands or more pressure-reducing elements 15 in the strands, the come from the adsorber 13 and capacitor 14 to install. As a result, the volume flow flowing into the adsorber 13 and into the condenser 14 can be varied. This means that the adsorber 13 and the condenser 14 can preferably be adapted to the mode of operation of the sorption machine or adsorption machine and consequently be cooled differently. Through this simple but effective adjustment of the flow rates, the efficiency can be significantly improved. Due to the integration of the pressure-reducing elements 15, the volume flows which flow into the adsorber 13 and the condenser 14 have a substantially different pressure loss. The pressure-reducing elements 15 can advantageously be integrated into each tube 9 of a Soptionsmaschine, in particular adsorption.

Fig. 3 shows pressure-reducing elements in the Rückkühlsträngen taking into account the heat source strand. The heat transfer fluid flows after cooling in the recooler 11 by preferably an air flow 10 through the tubes 9 in the adsorber 13 and capacitor 14. Adsorber 13 and capacitor 14 are preferably connected in parallel, but may also be connected in series. The cooled heat transfer fluid absorbs heat from a refrigerant in the adsorber 13 and condenser 14 and is subsequently cooled by the recooler 11 by discharging the absorbed heat to a heat receiver. However, it may also be preferred that the heated heat transfer fluid is passed after heat absorption in a heat source 12 and there emits the heat. The heat source 12, that is, the heat emitted, can be used for example for air conditioning buildings. Advantageously, the heat source 12 is separated via hydraulic components 16 from the circulation of the heat transfer fluid and can be switched on when needed. Hydraulic components include valves, ball valves or pumps. It is thus possible, the heated heat transfer fluid either in the recooler 11 or the To conduct heat source 12. However, it may also be advantageous to conduct only the heated heat transfer fluid from the adsorber 13 and not from the condenser 14 into the heat source 12. Pressure-reducing elements 15 can advantageously be integrated into the train from the recooler 11 before the adsorber 13 and / or condenser 14. Advantageously, the heat transfer fluid does not flow through the pressure reducing elements 15 after passage of the heat source 12, that is, the hydraulic component 16 is preferably arranged such that the heat transfer fluid coming from the heat source 12 flows directly into the adsorber 13. Furthermore, it may be preferable to incorporate pressure-reducing elements 15 into the strand (s) coming from the adsorber 13 and / or condenser 14.

LIST OF REFERENCE NUMBERS

9 tubes

10 airflow 11 recooler

12 heat source

13 adsorbers

14 capacitor

15 pressure-reducing element 16 hydraulic components

Claims

claims

1. Use of a pressure-reducing element for dividing volume flows in a sorption machine, characterized in that a total volume flow coming from a recooling, is divided into at least two volume flows, wherein a first volume flow through at least one pipe of a first pipe section in a condenser and a second volume flow through at least one tube of a second tube section flows into an adsorber, wherein at least one of the two coming from the recooling or the two returning to this tube has at least one pressure-reducing element.

2. .Use of a pressure-reducing element according to claim 1, characterized in that the two pipe sections have substantially different pressure loss coefficients.

3. Use of a pressure-reducing element according to claim 1 or 2, characterized in that the condenser and adsorber are heat exchangers.

4. Use of a pressure-reducing element according to one or more of the preceding claims, characterized in that the volume flow is a heat transfer fluid comprising water.

5. Use of a pressure-reducing element according to one or more of the preceding claims, characterized in that the pressure-reducing element is a throttle, a valve or a stopcock.

6. Use of a pressure-reducing element according to one or more of the preceding claims, characterized in that the pressure-reducing element is a diaphragm and / or a built-in part.

7. Use of a pressure-reducing element according to one or more of the preceding claims, characterized in that the pressure-reducing element is adjustable and variable.

8. Use of a pressure-reducing element according to one or more of the preceding claims, characterized in that the pressure-reducing element changes the cross-section of the free flow such that the volume flows are present at different and / or equal pressures in the heat exchanger.

9. Use of a pressure-reducing element according to one or more of the preceding claims, characterized in that the at least one measuring and / or regulating device is installed between the recooler and adsorber and / or condenser.

10. Use of a pressure-reducing element according to one or more of the preceding claims for dividing volume flows in particular an adsorption machine, characterized in that a total volume flow coming from a recooling, is divided into at least two volume flows, wherein a first

Volumetric flow through at least one pipe of a first pipe section flows into a condenser and a second volume flow through at least one pipe of a second pipe section in an adsorber, wherein at least one of the two coming from the recooling or the two returning to this pipe having at least one pressure-reducing element.

11. Use according to claim 10, characterized in that the two pipe sections have substantially different pressure loss coefficients.

12. A method for dividing volume flows in a sorption, characterized in that a total volume flow coming from a recooling, is divided into at least two volume flows, wherein a first volume flow through at least one pipe of a first pipe section in a condenser and a second volume flow through at least one Tube of a second tube section flows into an adsorber, wherein at least one of the two coming from the recooling or the two returning to this tube having at least one pressure-reducing element, whereby the ratio of the pressure loss coefficients of the two pipe sections can be influenced.