Add to ORKGApparently complex flow structures obey to scaling relations that enable to make it viable the study of their configuration and flow dynamics. This is the case of flow structures that exhibit several branching levels and are thought to perform optimally. Here we present scaling relations of diameters and lengths of branching cylindrical channels with pulsatile flows, and compare them with other relations published in the literature. It is shown that, under constant global volume of the flow tree, and for zero pulse frequency these scaling relations reduce to Murrays's law of consecutive diameters. Optimal scaling depends on pulse frequency, distensibility of the channel walls, and asymmetry of the daughter vessels. In case that in addition ...
Structure of the optimal rectangular microcirculatory cell of a leaf is investigated on the model o...
Diverse tree structures such as blood vessels, branches of a tree and river basins exist in nature. ...
This paper aims to contribute to the ongoing research on tree-shaped flow structures. Here, we focus...
Apparently complex flow structures obey to scaling relations that enable to make it viable the study...
Biological and engineering studies of Hess-Murray’s law are focused on assemblies of tubes with impe...
The branching of fluidic networks becomes a subject of great interest due to its importance in under...
Many natural systems and engineering processes occur in which a fluid invades a territory from one e...
When blood flows through small vessels, the two-phase nature of blood as a suspension of red cells (...
When applied to a branching network, Murray’s law states that the optimal branching of vascular netw...
AbstractAlthough the flow resistance of a single vessel segment is easy to compute, the equivalent r...
Branched networks are ubiquitous in living systems. The dimensions and the geometry of these branche...
Murray's law states that the volumetric flow rate is proportional to the cube of the radius in a cyl...
Structure of the optimal rectangular microcirculatory cell of a leaf is investigated on the model o...
Allometric scaling relations for how branching tubes deliver fluid are often based on the assumption...
We present a simple model for the arterial part of the cardiovascular system, based on Poiseuille fl...
Structure of the optimal rectangular microcirculatory cell of a leaf is investigated on the model o...
Diverse tree structures such as blood vessels, branches of a tree and river basins exist in nature. ...
This paper aims to contribute to the ongoing research on tree-shaped flow structures. Here, we focus...
Apparently complex flow structures obey to scaling relations that enable to make it viable the study...
Biological and engineering studies of Hess-Murray’s law are focused on assemblies of tubes with impe...
The branching of fluidic networks becomes a subject of great interest due to its importance in under...
Many natural systems and engineering processes occur in which a fluid invades a territory from one e...
When blood flows through small vessels, the two-phase nature of blood as a suspension of red cells (...
When applied to a branching network, Murray’s law states that the optimal branching of vascular netw...
AbstractAlthough the flow resistance of a single vessel segment is easy to compute, the equivalent r...
Branched networks are ubiquitous in living systems. The dimensions and the geometry of these branche...
Murray's law states that the volumetric flow rate is proportional to the cube of the radius in a cyl...
Structure of the optimal rectangular microcirculatory cell of a leaf is investigated on the model o...
Allometric scaling relations for how branching tubes deliver fluid are often based on the assumption...
We present a simple model for the arterial part of the cardiovascular system, based on Poiseuille fl...
Structure of the optimal rectangular microcirculatory cell of a leaf is investigated on the model o...
Diverse tree structures such as blood vessels, branches of a tree and river basins exist in nature. ...
This paper aims to contribute to the ongoing research on tree-shaped flow structures. Here, we focus...