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http://opendiscovery.org/rdf/FDP/P_1 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:narrower http://opendiscovery.org/rdf/FDP/P_1_2, http://opendiscovery.org/rdf/FDP/P_1_1
skos:prefLabel "Increase the positive effect of useful flows"@en
http://opendiscovery.org/rdf/FDP/P_1_1 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:narrower http://opendiscovery.org/rdf/FDP/P_1_1_13, http://opendiscovery.org/rdf/FDP/P_1_1_14, http://opendiscovery.org/rdf/FDP/P_1_1_11, http://opendiscovery.org/rdf/FDP/P_1_1_12, http://opendiscovery.org/rdf/FDP/P_1_1_09, http://opendiscovery.org/rdf/FDP/P_1_1_10, http://opendiscovery.org/rdf/FDP/P_1_1_07, http://opendiscovery.org/rdf/FDP/P_1_1_08, http://opendiscovery.org/rdf/FDP/P_1_1_05, http://opendiscovery.org/rdf/FDP/P_1_1_06, http://opendiscovery.org/rdf/FDP/P_1_1_03, http://opendiscovery.org/rdf/FDP/P_1_1_04, http://opendiscovery.org/rdf/FDP/P_1_1_01, http://opendiscovery.org/rdf/FDP/P_1_1_02
skos:prefLabel "Increase the conductivity of useful flows"@en
http://opendiscovery.org/rdf/FDP/P_1_1_01 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Reduction in the number of flow transformations"@en
skos:note "Usually, every transformation of a flo (transfer of substances from one state to another, the change of types of energy, the change in the way information is represented) is accompanied by losses and inhibition. Consequently, reducing the number of such transformations leads to an increase in conductivity. Ideally, there should be no transformations at all, and all components of flows should immediately have the form necessary for their final use."@en
http://opendiscovery.org/rdf/FDP/P_1_1_02 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Flow conversion"@en
skos:note "If there is considerable resistance to the flow, and the losses involved in its conversion are relatively small, the flow is converted to the most easily transferable form."@en
http://opendiscovery.org/rdf/FDP/P_1_1_03 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Reducing the length of the flow"@en
skos:note "Usually, many types of losses and resistances to a flow are proportional to its length. Consequently, flow length must be reduced in order to increase conductivity. Ideally, the flow should be zero-length, i.e. its components should appear immediately where they are used."@en
http://opendiscovery.org/rdf/FDP/P_1_1_04 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Elimination of 'grey zones'"@en
skos:note "Since flow behaviour in the grey zone cannot be predicted, the parameters of these areas are usually chosen empirically. It is not always possible to carry out a sufficient number of experiments and therefore these areas are usually not sufficiently optimised, resulting in increased losses and resistance. Consequently, the elimination of grey areas indirectly leads to an increase in conductivity through better optimisation."@en
http://opendiscovery.org/rdf/FDP/P_1_1_05 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Eliminating of 'bottle necks'"@en
skos:note "A 'bottle neck' is an area of the flow with sharply increased resistance. Obviously, eliminating such areas greatly increases conductivity."@en
http://opendiscovery.org/rdf/FDP/P_1_1_06 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Increasing the conductivity of individual flow paths"@en
skos:note "Since the flow resistance is strongly dependent on the characteristics of the conductors, improving them leads to an increase in conductivity. Ideally, the characteristics should correspond to the physical limit for a given conductor type."@en
http://opendiscovery.org/rdf/FDP/P_1_1_07 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Increasing the characteristics of a specific flow"@en
skos:note "Often the resistance to a flow is independent of the specific characteristics of the flow. Therefore, it is advantageous to reduce the volume of the flow while increasing its density in order to increase conductivity. As a result, more flow can be carried through the same conductor, or the cost of the conductor can be reduced for the same flow."@en
http://opendiscovery.org/rdf/FDP/P_1_1_08 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Give additional functions to the flow"@en
skos:note "If a flow additionally takes over the function of another flow, the second flow becomes unnecessary. Therefore, the total power of the flows in the system is reduced without affecting performance, and therefore, efficiency increases."@en
http://opendiscovery.org/rdf/FDP/P_1_1_09 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Useful influence of flows on each other"@en
http://opendiscovery.org/rdf/FDP/P_1_1_10 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Beneficial effect of the flow on the conductive path of another flow"@en
http://opendiscovery.org/rdf/FDP/P_1_1_11 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Using one flow as a carrier of the other"@en
skos:note "Flows of different nature can be used to carry each other: a flow of matter can carry different kinds of energy, a flow of energy can carry information, etc."@en
http://opendiscovery.org/rdf/FDP/P_1_1_12 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Transmission of several homogeneous flows in one channel"@en
http://opendiscovery.org/rdf/FDP/P_1_1_13 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Flow modification to increase conductivity"@en
skos:note "Sometimes it is possible to modify the flow in such a way that the resistance to it is reduced. Such modifications include various ways of reducing the viscosity of fluids, laminarisation/turbulisation of flows, use of 'transparency windows', etc."@en
http://opendiscovery.org/rdf/FDP/P_1_1_14 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Total or partial flow out of the system"@en
skos:note "In some cases it is possible to pass the flow through a supersystem or environment. This allows the use of external paths with high conductivity, and also reduces the system requirements and costs of the intra-system path."@en
http://opendiscovery.org/rdf/FDP/P_1_2 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:narrower http://opendiscovery.org/rdf/FDP/P_1_2_08, http://opendiscovery.org/rdf/FDP/P_1_2_09, http://opendiscovery.org/rdf/FDP/P_1_2_06, http://opendiscovery.org/rdf/FDP/P_1_2_07, http://opendiscovery.org/rdf/FDP/P_1_2_10, http://opendiscovery.org/rdf/FDP/P_1_2_01, http://opendiscovery.org/rdf/FDP/P_1_2_04, http://opendiscovery.org/rdf/FDP/P_1_2_05, http://opendiscovery.org/rdf/FDP/P_1_2_02, http://opendiscovery.org/rdf/FDP/P_1_2_03
skos:prefLabel "Increasing the efficiency of useful flows"@en
http://opendiscovery.org/rdf/FDP/P_1_2_01 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Elimination of 'stagnation zones'"@en
skos:note "A 'stagnation zone' is an area of a flow where some part of it is for a long time or permanently stagnant. As a result, the effective flow capacity is reduced, as if there were leaks, although technically all of it remains in the system. Consequently, the elimination of 'stagnant zones' leads to an increase in the efficiency of useful flow by increasing the completeness of its utilisation without increasing the overall capacity."@en
http://opendiscovery.org/rdf/FDP/P_1_2_02 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Transition to impulse actions"@en
skos:note "Often the efficiency of a flow depends mainly on its amplitude value. Therefore, it is advantageous to switch to a pulsed flow in order to increase efficiency. The total power of such a flow can be small, because its effective value is small, but the efficiency is significant, because the pulse amplitude can be very high. However, larger amplitudes can be achieved more easily in pulsed mode by storing energy at pauses."@en
http://opendiscovery.org/rdf/FDP/P_1_2_03 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Use of resonance"@en
skos:note "In particular, the use of resonance allows selective high-intensity effects at low total power of the flow.<br/> In contrast to a conventional vibratory conveyor, it provides a significantly higher output for the same amount of energy and dimensions. This is because its moving part vibrates at its own vibration frequency, making maximum use of the drive energy."@en
http://opendiscovery.org/rdf/FDP/P_1_2_04 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Flow modulation"@en
http://opendiscovery.org/rdf/FDP/P_1_2_05 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "The use of gradients"@en
skos:note "Often, a high flow intensity is needed only in a certain area (operational zone), while costs are determined by the overall intensity. Therefore, it is advantageous to apply a flow with a gradient - high intensity in the operational zone and low intensity throughout the rest of the path to increase efficiency."@en
http://opendiscovery.org/rdf/FDP/P_1_2_06 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Mixing of several homogeneous flows"@en
skos:note "Several weak homogeneous flows can also be used to achieve a local concentration of flow, which are stacked in the operational zone. For flows having a wave nature, the phenomenon of interference can be used. Since the gain in total power is not achieved in this way, it is usually done in cases where several weak flows are easier to provide than one strong flow."@en
http://opendiscovery.org/rdf/FDP/P_1_2_07 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Multiple use of flow (adding a flow to itself)"@en
skos:note "The total power of the flow can be reduced by allowing a relatively weak flow to pass repeatedly through the operational zone. This is usually the case when the strong flow is difficult to create or cannot be fully used in one pass and the effect may be cumulative."@en
http://opendiscovery.org/rdf/FDP/P_1_2_08 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Using two heterogeneous flows to achieve a synergetic effect"@en
skos:note "Sometimes, instead of one strong flow, two weak heterogeneous flows can be used, which have a synergetic effect. This effect consists in the fact that the result of simultaneous impact of both flows is much greater than the sum of the results of their separate use. Due to this, weak flows provide high efficiency of the system at low losses."@en
http://opendiscovery.org/rdf/FDP/P_1_2_09 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Pre-saturation of the operative zone with substance, energy and information"@en
skos:note "Ideally, there should be no flows in the system at all, because any flow leads to losses and additional load on the system. Complete coagulation of flows can be achieved by pre-saturating the operational zone with substance, energy, and information of the required type and quantity. In doing so, a weak initiating signal is often sufficient to carry out the entire process. If it is not possible to fully saturate an operational area with everything it needs, partial saturation may be limited. In this case, it will be possible to switch to the use of weak streams."@en
http://opendiscovery.org/rdf/FDP/P_1_2_10 (EasyRdf\Resource)
rdf:type tc:FlowDevelopmentPattern
skos:prefLabel "Reducing the intensity of information flows by switching to self-regulating processes"@en
skos:note "Often the flow of information in the system is necessary to control the processes occurring in it. These flows can be reduced or eliminated altogether by using self-regulating processes."@en