A Goal Method and a Target Method for Balancing Exhaust Ventilation Duct Systems with Dampers

Guffey, Steven E.

doi:10.1080/15459620601177503

Cited by 22 publications

(14 citation statements)

References 7 publications

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“…(3) When a damper on one branch is pushed in, the airflow in that branch decreases, the fan airflow increases by somewhat less, while the airflows in each of the other branches increase by differing amounts depending on their location in the system. As each succeeding damper is adjusted, the airflows through those branches already adjusted become increasingly greater than their value of Q br-goal .…”

Section: Goal Methodsmentioning

confidence: 99%

“…The Target Method (3) tested in this study is a proportional method designed to address the problems of inappropriate fan speed and shifting airflow among branches. Because the relative distribution of airflows among branches will change very little even if the fan airflow changes a great deal, (6,7) the Target Method is designed to allow adjustment of dampers to achieve branch airflow ratios equal to Q fan-final /Q fan-goal (Eq.…”

Section: Proportional Methodsmentioning

confidence: 99%

“…Instead, it uses target values that account for the problems of both inappropriate fan speed and shifting airflows among branches. (3) The desired levels of airflow are then achieved by adjusting the fan output after all dampers are adjusted. That is, like other proportionality methods, the Target Method does not aim to attain a specific airflow level in each branch but instead seeks to obtain a fraction of total airflow.…”

Section: Proportional Methodsmentioning

confidence: 99%

“…The system had seven branches designed to have diverse resistances to flow due to their different duct lengths, number of elbows, and types of hood transition (Figure 1, Table I). The 20-gauge, galvanized 3.00, 4.00, 5.00, and 6.00 inches) immediately before measurements were taken. The time average was set at 1 sec to measure velocity pressure and at 5 sec to measure static pressure.…”

Section: Apparatusmentioning

confidence: 99%

“…Increasing the resistance of a branch reduces its flow and increases the flows to other branches. (1) By accounting for this shift in airflow, the Target Method (3) aims to be less tedious and difficult.…”

Section: Introductionmentioning

confidence: 99%

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Experimental Validation of a Target Method for Balancing Exhaust Ventilation Duct Systems with Dampers

Dodrill

Guffey

2008

Journal of Occupational and Environmental Hygiene

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This study tested the "Target Method" for adjusting ventilation systems. The Target Method is based on target hood static pressures (SPh(target)) computed in a manner designed to take into account the estimated effects of dampers on the fan, the order of damper adjustments, and the ratio of the prebalancing branch airflows to their goals. It is aimed at achieving a desired relative distribution of airflows even if the fan output is far from ideal. The method assumes the fan output will be adjusted after the dampers are adjusted. The method is expected to produce lower fan pressure requirements than some commonly used methods. The method was tested on a working seven-branch, full-sized exhaust ventilation system in the West Virginia University Exposure Assessment Laboratory. Two radically different target distributions were tested with two replications apiece. Both target distributions of airflows were substantially different from the initial distribution, providing a high degree of challenge to the methodology. For each distribution, SPh(target) values were computed for the first round of adjustments. Each damper was adjusted until the observed value of the hood static pressure was nearly equal to that damper's computed SPh(target) value for that distribution. Each of the other branch dampers was adjusted similarly in turn. After the first round of adjustments, the median ratio of SPh to SPh(target) provided the targets for the partial second round of adjustments. Twenty-point Pitot traverses were used to determine the airflow in each branch duct both before and after employing the adjustment method, providing the basis to determine the success in reaching each of the two desired distributions. The percentage of excess airflow (assuming ideal adjustment of the fan speed) was below 2.2% for all experimental trials. An unpublished study by Vivek Balasubramanian showed that excess airflow was 4.8% to 8.5% in the same experimental system after two full rounds of adjustment using the customary Target Method. Under poor measurement conditions, the greater uncertainty of pressure measurements would likely produce somewhat higher excess airflows.

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Section: Goal Methodsmentioning

confidence: 99%