Temperature response functions (G-functions) for single pile heat exchangers

Transient analysis helps us to predict the behavior of heat exchangers subjected to various operational disturbances due to sudden change in temperature or flow rates of the working fluids. The present experimental analysis deals with the effect of flow distribution on the transient temperature response for U-type and Z-type plate heat exchangers. The experiments have been carried out with uniform and nonuniform flow distributions for various flow rates. The temperature responses are analyzed for various transient characteristics, such as initial delay and time constant. It is also possible to observe the steady state characteristics after the responses reach asymptotic values. The experimental observations indicate that the Z-type flow configuration is more strongly affected by flow maldistribution compared to the U-type in both transient and steady state regimes. The comparison of the experimental results with numerical solution indicates that it is necessary to treat the flow maldistribution separately from axial thermal dispersion during modeling of plate heat exchanger dynamics.

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High-temperature response functions and the non-Abelian Kubo formula

Physical Review D ◽

10.1103/physrevd.48.4991 ◽

1993 ◽

Vol 48 (10) ◽

pp. 4991-4998 ◽

Cited By ~ 62

Author(s):

R. Jackiw ◽

V. P. Nair

Keyword(s):

High Temperature ◽

Temperature Response ◽

Response Functions ◽

Kubo Formula

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Aspects of maize modelling in eastern Canada

Canadian Journal of Soil Science ◽

10.4141/s97-095 ◽

1998 ◽

Vol 78 (3) ◽

pp. 421-429 ◽

Cited By ~ 1

Author(s):

D. W. Stewart ◽

L. M. Dwyer ◽

L. M. Reid

Keyword(s):

Fungal Infection ◽

Fusarium Species ◽

Temperature Response ◽

Leaf Angle ◽

Infection Model ◽

Response Functions ◽

Eastern Canada ◽

Heat Unit ◽

Model Calculations ◽

Vegetative Period

Maize (Zea mays L.) is a crop of growing importance in Eastern Canada. Modelling the temperature effects on phenological development, crop architecture and disease infection in maize contributes to the development of well-adapted, early-maturing varieties. Details of modelling these three aspects of maize growth were presented. The first focussed on quantifying the effect of air or soil temperature on maize phenological development. Crop growth was divided into two periods: vegetative (planting to silking) and grain filling (silking to maturity). A third period (planting to emergence) was separated within the vegetative period. Heat unit systems based on daily temperature response functions were developed to produce the most consistent heat unit sums for each period. The best fits of these functions were determined by minimizing standard deviations and coefficients of variation of these sums for each thermal period over locations and years. Calculated temperature response functions estimated thermal periods more consistently than growing degree days (GDD) for all three periods. The largest improvement was made in the silking to maturity period.The second aspect was a study of crop architecture. Methods were developed to mathematically characterize the structure of a canopy in terms of leaf area and leaf angle distributions with crop height and across the row. These calculations, in turn, were input to a soil–plant–atmosphere model to calculate interception of photosynthetically active radiation (PAR). Model calculations of PAR interception compared well with measurements for a range of plant types and plant population densities (R2 = 0.76).The third aspect was quantifying growth of Fusarium in maize. Differential equations were used to relate Fusarium rates of growth in maize ears to air temperature, relative humidity and precipitation. Integration of these equations over time produced quantitative estimates of fungal infection. Model calculations were compared to visual ratings of fungal infection for two Fusarium species over three years (R2 = 0.92).In each of the three aspects of this study, modelling tested our understanding of the processes involved and the dominant factors controlling these processes. Thus, modelling was an integral part of the scientific approach, synthesizing experimental data in a quantitative conceptual framework and identifying dominant factors and parameters which required additional focussed experimental evaluation. Key words: Phenological development, crop architecture, Fusarium infection

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Temperature response functions introduce high uncertainty in modelled carbon stocks in cold temperature regimes

Biogeosciences ◽

10.5194/bg-7-3669-2010 ◽

2010 ◽

Vol 7 (11) ◽

pp. 3669-3684 ◽

Cited By ~ 15

Author(s):

H. Portner ◽

H. Bugmann ◽

A. Wolf

Keyword(s):

Soil Carbon ◽

Elevation Gradient ◽

Temperature Response ◽

Terrestrial Ecosystems ◽

Ecosystem Model ◽

Carbon Stocks ◽

Carbon Pools ◽

Parameter Estimates ◽

Response Functions ◽

Data Set

Abstract. Models of carbon cycling in terrestrial ecosystems contain formulations for the dependence of respiration on temperature, but the sensitivity of predicted carbon pools and fluxes to these formulations and their parameterization is not well understood. Thus, we performed an uncertainty analysis of soil organic matter decomposition with respect to its temperature dependency using the ecosystem model LPJ-GUESS. We used five temperature response functions (Exponential, Arrhenius, Lloyd-Taylor, Gaussian, Van't Hoff). We determined the parameter confidence ranges of the formulations by nonlinear regression analysis based on eight experimental datasets from Northern Hemisphere ecosystems. We sampled over the confidence ranges of the parameters and ran simulations for each pair of temperature response function and calibration site. We analyzed both the long-term and the short-term heterotrophic soil carbon dynamics over a virtual elevation gradient in southern Switzerland. The temperature relationship of Lloyd-Taylor fitted the overall data set best as the other functions either resulted in poor fits (Exponential, Arrhenius) or were not applicable for all datasets (Gaussian, Van't Hoff). There were two main sources of uncertainty for model simulations: (1) the lack of confidence in the parameter estimates of the temperature response, which increased with increasing temperature, and (2) the size of the simulated soil carbon pools, which increased with elevation, as slower turn-over times lead to higher carbon stocks and higher associated uncertainties. Our results therefore indicate that such projections are more uncertain for higher elevations and hence also higher latitudes, which are of key importance for the global terrestrial carbon budget.

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Improved temperature response functions for models of Rubisco-limited photosynthesis

Plant Cell & Environment ◽

10.1111/j.1365-3040.2001.00668.x ◽

2001 ◽

Vol 24 (2) ◽

pp. 253-259 ◽

Cited By ~ 677

Author(s):

C. J. Bernacchi ◽

E. L. Singsaas ◽

C. Pimentel ◽

A. R. Portis Jr ◽

S. P. Long

Keyword(s):

Temperature Response ◽

Response Functions

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Uncertainty in remaining carbon budgets increases with less ambitious targets

10.5194/egusphere-egu2020-15062 ◽

2020 ◽

Author(s):

Endre Falck Mentzoni ◽

Andreas Johansen ◽

Andreas Rostrup Martinsen ◽

Kristoffer Rypdal ◽

Martin Rypdal

Keyword(s):

Radiative Forcing ◽

Carbon Budget ◽

Climate Models ◽

Temperature Response ◽

Impulse Response Functions ◽

Response Functions ◽

Carbon Budgets ◽

Cumulative Emission ◽

Internal Climate Variability ◽

Earth System Models

<blockquote> <div dir="ltr"> <div> <p><span lang="en-US">In this work, we present estimates and uncertainties of the remaining carbon budget for a range of different global temperature targets. To model how atmospheric CO2 and methane concentrations depend on emissions, we use impulse response functions estimated from emission-pulse experiments in Earth System Models (ESMs). We use box-model ESM emulators to model the temperature response to radiative forcing and analyze a range of emission scenarios from Integrated Assessment Models. Taking into account uncertainties in the approximately linear relationship between cumulative emission and peak temperature, as well as internal climate variability and uncertainties in the carbon and climate models, we estimate the remaining carbon budgets for varying targets. The results show that the carbon-budget-uncertainties increase significantly with less ambitious targets.</span></p> </div> </div> </blockquote>

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Some characteristics of core temperature signals in the conscious goat

AJP Regulatory Integrative and Comparative Physiology ◽

10.1152/ajpregu.1984.247.3.r456 ◽

1984 ◽

Vol 247 (3) ◽

pp. R456-R464 ◽

Cited By ~ 8

Author(s):

C. Jessen ◽

G. Feistkorn

Keyword(s):

Heat Loss ◽

Core Temperature ◽

Temperature Difference ◽

Heat Production ◽

Heat Exchangers ◽

Response Curve ◽

Temperature Response ◽

Warm Receptors ◽

Core Sensors Of Temperature ◽

Head Temperature

In three conscious goats, head and trunk temperatures were altered independently of each other by means of extracorporeal carotid heat exchangers and intravascular heat exchangers in the trunk veins. In 35 experiments heat production and heat loss were measured while head temperature was varied between 35.4 and 42.2 degrees C and trunk temperature between 34.5 and 42.4 degrees C. The largest temperature difference between head and trunk amounted to 6.6 degrees C. Head and trunk generated approximately equal fractions of the total core temperature input to the controller. The distribution of combinations of head and trunk temperatures resulting in constant levels of heat production and heat loss was consistent with the hypothesis that the total core temperature input to the controller equaled the sum of two identical inputs, both rising exponentially with temperature. The hypothesis implies that the input generated by core sensors of temperature in head and trunk is a continuum and conforms with the temperature-response curve of warm receptors.

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