Two phase releases following rapid vessel failure

Bettis, R. J.

January 1987

No description available.

621.69

High temperature crack growth in 2.25 Cr - 1 Mo steel

Tarafder, Soumitra

January 1990

No description available.

620.11223

Pressure vessel steels

The intestinal vasculature in health and in certain non-malignant diseases of the bowel

Carr, N. D.

January 1984

No description available.

610

Colon vessel lesions

Vascular actions of angiotensin and other compounds, in vitro and in vivo : role of the endothelium

Whalley, Helen

January 1988

No description available.

612

Blood vessel vasodilation

A computational approach to study the effect of multiple lymphangion coordination on lymph flow

Madabushi Venugopal, Arun

01 November 2005

The lymphatic system acts to return fluid from the interstitial space back into the blood circulation. In normal conditions, lymphangions, the segment of lymphatic vessel in between valves, cyclically contract and can pump lymph from low pressure tissues to the higher-pressure veins of the neck. With edema, however, this pressure gradient can reverse, and the role of contraction is less clear. Like ventricles, lymphangions are sensitive to both preload and afterload. Unlike ventricles, lymphangions are arranged in series, so that the outlet pressure of one lymphangion becomes the inlet pressure of another. Anything that alters the relative timing and frequency of adjacent lymphangions alters both preload and afterload of each lymphangion and thus mean lymph flow. To explore the effect of timing and frequency of contraction on lymph flow, we developed a computational model of a lymphatic vessel with lymphangions described by the classic description of time-varying elastance. When pumping up a pressure gradient, as in normal conditions, or when pumping down a pressure gradient, as in some cases of edema, we found that flow was optimized when the lymphangions in the vessel were pumping with a very short time delay between their cycles, and the flow was reduced when the time delay between the contractions was reduced to zero. However, a difference in frequency between adjacent lymphangions alters instantaneous flow but does not affect mean flow. These results suggest an important role for the timing of the contraction in optimizing lymph flow. However, a difference in frequencies between adjacent lymphangions has little effect on altering lymph flow, suggesting that tight control of lymphangion coordination may not be critical for lymphatic function.

Lymphatic vessel

coordination.

A computational approach to study the effect of multiple lymphangion coordination on lymph flow

Madabushi Venugopal, Arun

01 November 2005

The lymphatic system acts to return fluid from the interstitial space back into the blood circulation. In normal conditions, lymphangions, the segment of lymphatic vessel in between valves, cyclically contract and can pump lymph from low pressure tissues to the higher-pressure veins of the neck. With edema, however, this pressure gradient can reverse, and the role of contraction is less clear. Like ventricles, lymphangions are sensitive to both preload and afterload. Unlike ventricles, lymphangions are arranged in series, so that the outlet pressure of one lymphangion becomes the inlet pressure of another. Anything that alters the relative timing and frequency of adjacent lymphangions alters both preload and afterload of each lymphangion and thus mean lymph flow. To explore the effect of timing and frequency of contraction on lymph flow, we developed a computational model of a lymphatic vessel with lymphangions described by the classic description of time-varying elastance. When pumping up a pressure gradient, as in normal conditions, or when pumping down a pressure gradient, as in some cases of edema, we found that flow was optimized when the lymphangions in the vessel were pumping with a very short time delay between their cycles, and the flow was reduced when the time delay between the contractions was reduced to zero. However, a difference in frequency between adjacent lymphangions alters instantaneous flow but does not affect mean flow. These results suggest an important role for the timing of the contraction in optimizing lymph flow. However, a difference in frequencies between adjacent lymphangions has little effect on altering lymph flow, suggesting that tight control of lymphangion coordination may not be critical for lymphatic function.

Lymphatic vessel

coordination.

The experimental investigation and analysis of the dynamic behaviour of a cylindrical vessel with a torispherical head empty and partially filled with fluid

Villanueva, C.

January 1985

No description available.

621.69

Vessel resonance testing

Plastic limit analysis of pressure vessels with defects

Meng, Q.

January 1984

No description available.

621.69

Pressure vessel defect

Characterisation of two phase releases

Pettitt, Glenn Nigel

January 1990

No description available.

621.69

Pressure vessel safety

The case of the "Mercury" as typical of contraband trade on the California Coast, 1790-1820 ...

Boudinot, May Fidelia.

January 1915

Thesis (M.A.)--University of California, Dec. 1915. / Typewritten (carbon copy). Bibliography: p. 80-82.

Mercury (vessel) Smuggling. California