WILLIAM GEORGE GENSLER
Engineers in Tucson, AZ

License number
Pennsylvania PE014161E
Category
Engineers
Type
Professional Engineer
Address
Address 2
Tucson, AZ 85721
Pennsylvania

Professional information

William Gensler Photo 1

Method And Apparatus For Determining Plant Water Content

US Patent:
6870376, Mar 22, 2005
Filed:
Sep 20, 2003
Appl. No.:
10/664661
Inventors:
William G. Gensler - Tucson AZ, US
International Classification:
G01R027/26
US Classification:
324664, 324663
Abstract:
This invention is concerned with a method and plant-based apparatus to measure the water content within plants. A metallic surface is implanted in any orientation within the plant. The total area of this surface within the plant is measured with a mechanical caliper or equivalent. The wetted area of this surface is obtained by means of a measurement of electrical capacitance at the interface between the surface and water in the plant. Plant water content is equal to the ratio of measured capacitance to measured surface area within the plant. The apparatus functions as a “water dipstick” in the same manner as an “oil dipstick” in an automobile. The surface is normally implanted in the petiole in the early season and remains there until harvest. Water content readings are then used to set irrigation schedules. The full season chronology of water content readings can be extrapolated from site to site and season to season for optimization of agricultural practice.


William Gensler Photo 2

Method And Apparatus For Measuring Sucrose Transport Into The Fruit Of Plants

US Patent:
7229546, Jun 12, 2007
Filed:
Oct 27, 2005
Appl. No.:
11/260741
Inventors:
William George Gensler - Tucson AZ, US
International Classification:
G01N 27/327, G01N 27/403
US Classification:
205792, 205787
Abstract:
The method and apparatus are concerned with measurement of the onset and magnitude of sucrose transport between a petiole and fruit within a plant over extended time periods. Sensors are implanted in both the petiole and fruit. The electrical potential of each sensor is measured with respect to a common electrode in the soil. A difference potential is formed by subtracting the potential of the sensor in the fruit from the potential of the sensor in the petiole. Positive values of this difference determine the onset and magnitude of sucrose transport between the petiole and fruit. Cumulative values of positive difference potential over a multi-day period yield the contribution of the leaf and petiole to sugar buildup in the fruit. The cumulative positive difference potential is specific to the location of the sensors. This has the advantage that multiple sensors in petioles in the same stem yield a continuous measure of sucrose allocation, or non allocation, from the different petioles to the fruit.


William Gensler Photo 3

Method And Apparatus For Determination Of Plant Canopy Rehydration Rate And Magnitude Of Plant Canopy Water Storage

US Patent:
8111076, Feb 7, 2012
Filed:
Jan 19, 2010
Appl. No.:
12/657353
Inventors:
William G. Gensler - Tucson AZ, US
International Classification:
G01R 27/26
US Classification:
324679, 324 72, 324664, 324658, 47 49, 73 73, 73304 C, 73304 R, 239 71
Abstract:
This invention is concerned with a method for measuring the canopy rehydration pulse during the period of water application. During the rehydration process water leaks from the trunk xylem tubes into the sapwood extraxyllary region. A water content sensor in this region monitors the magnitude and timing of this leakage water thereby giving a measure of the magnitude and timing of the upward flow of water. The rehydration pulse is quantified by a sequence of measurements of sapwood water content: an initial measurement of water content just prior to water application, then measurement of water content during water application. The difference between the values obtained in the two measurements yields a measure of the leakage water in the extraxyllary region and, in turn, the magnitude and timing of the rehydration pulse. Determination of the onset and termination of the rehydration pulse is used to optimize the duration of water application.


William Gensler Photo 4

Method And Apparatus For Determination Of Ion Population And Type Of Ion Within Plants

US Patent:
8289035, Oct 16, 2012
Filed:
Apr 19, 2011
Appl. No.:
13/066592
Inventors:
William George Gensler - Tucson AZ, US
International Classification:
G01R 27/08
US Classification:
324692, 324 72
Abstract:
An unadjusted ion population is obtained by measurement of an unadjusted charge transfer due to an imposed electrical potential between two surfaces within a plant. An adjusted ion population is determined by dividing the unadjusted charge transfer by the wetted surface area through which the charge transfers occurs. Changes in wetted surface area are measured by changes in the electrical capacitance of the surface/liquid interface. The type of ion is identified by application of a sequence of potential values imposed on the two surfaces by a source which permits the potential of the electron emitting surface to take on a value set by the ion involved in the electron transfer. The ion is identified by the value of this potential.


William Gensler Photo 5

Method And Apparatus For Determining Soil Water Content

US Patent:
2010018, Jul 22, 2010
Filed:
Jan 20, 2009
Appl. No.:
12/321218
Inventors:
William G. Gensler - Tucson AZ, US
International Classification:
G01R 27/26, E02D 17/00
US Classification:
324664, 405303
Abstract:
This invention is concerned with a method and apparatus to measure soil water content. A sensor electrode assembly comprised of a sensor electrode fixed to a spherical shape is implanted in undisturbed soil at the bottom of a low narrow hole in the soil under evaluation. A second electrode is implanted in adjacent soil. Water is adsorbed on the surface of the sensor electrode in proportion to the water in the soil. Electrical charge layers are present at the sensor electrode/water interface due to dissolved oxygen in the adsorbed water. These charge layers result in an interfacial capacitance whose magnitude varies with the amount of water in the soil. Under the assumption that the capacitance of the second electrode/adjacent soil interface is constant, the change in capacitance across the two wires connected to the two electrodes give a measure of the change in soil water content. Energy flow during this measurement is unidirectional, that is, from the interfacial capacitance to the measuring device.


William Gensler Photo 6

Method And Apparatus For Electrically Determining Plant Water Status

US Patent:
3967198, Jun 29, 1976
Filed:
Sep 20, 1974
Appl. No.:
5/507789
Inventors:
William G. Gensler - Tucson AZ
International Classification:
G01R 1900, G01R 2722, G01R 1500
US Classification:
324 72
Abstract:
Method and apparatus for measuring the water status of a plant by measuring the long term variations in biological electrical potential developed by the plant. The electrical potential developed by the plant is measured by placing a first electrical probe in the root environment of the plant and a second electrical probe in the body of the plant and measuring the electrical potential between the probes with an electrometer or a high impedance voltmeter. The measured potential is amplified and displayed to provide an indication of the combined water status of the plant and its root environment. Several plants or several points on a single plant may be monitored over a period of time ranging from a few days to several months by utilizing a plurality of probes and sequentially measuring the potential developed between predetermined various ones of the probes.


William Gensler Photo 7

Gauge For Measuring Changes In The Length Of A Perimeter

US Patent:
6009631, Jan 4, 2000
Filed:
Feb 25, 1998
Appl. No.:
9/030199
Inventors:
William G. Gensler - Tucson AZ
International Classification:
G01B 508
US Classification:
335554
Abstract:
This gauge measures change in the length of the perimeter of stems and branches of trees and plants. The principal elements of the gauge are a band, concentric tubes, one mechanism to exert constant tension on the band and a second mechanism to press the gauge against the perimeter. The tubes are connected to the band such that changes in the length of the perimeter change the position of one tube with respect to the other. Readout of the position of the tubes is accomplished visually from scales located on the tubes or with a caliper inserted along a guide in the outer tube.