Christopher J Hintz, Age 521420 Walthour Rd, Savannah, GA 31410

8349614, Jan 8, 2013

Feb 17, 2010

12/707529

Christopher Hintz - Wilmington Island GA, US
Kenneth J. Hintz - Fairfax Station VA, US

George Mason Intellectual Properties, Inc. - Fairfax VA
University of South Carolina - Columbia SC

G01N 31/18
G01N 31/00
G01N 25/00
G01N 25/20
G01N 31/16

436147, 436163, 422 75, 422 77

Alkalinity determination, including an alkalinity determination process and/or alkalinity determinator. An alkalinity determination process may include providing a known value of volume of an acidic fluid, forming a titration system by providing one or more additions of a known value of volume of a relatively alkaline fluid to an acidic fluid, determining a pH value and/or a temperature value for one or more additions and/or determining an alkalinity value of a system by calculating a transformation including one or more determined pH values and/or temperature values of one or more additions. An alkalinity determination process may include modeling, such that an informed determination may be made with reference to relevant and/or irrelevant factors, as well as parameters to maximize likelihood of alkalinity determination. In embodiments, an alkalinity determinator may include one or more titration cells, one or more sensors and/or one or more alkalinity value determinators.

2009032, Dec 31, 2009

Apr 27, 2009

12/430467

Christopher J. Hintz - Savannah GA, US

University of South Carolina - Columbia SC

B01D 47/10
B01D 53/18

95185, 96275

Scrubbing systems and methods for removing carbon dioxide from a gas are provided. The scrubbing system can include a scrubber defining a vertically oriented tubing assembly, a gas inlet and a gas outlet. The tubing assembly has a tank section, a reduced diameter section, and an expansion section such that the expansion section is positioned above the reduced diameter section and the reduced diameter section is positioned above the tank section. An aqueous liquid-phase scrubbing media is contained within the tank section. The scrubbing system can further include a water bath configured to receive the CO-free gas exiting the scrubber.

2012012, May 24, 2012

Nov 21, 2011

13/300883

Christopher Hintz - Savannah GA, US
Amber Wilkinson - Savannah GA, US

B01D 35/00
B01D 11/04

210511, 210634

An apparatus may include a separator and/or a discharger. A separator may include a separator channel, an influent portion configured to allow the passage of a first fluid into a separator channel, an effluent portion disposed above an influent portion and/or a fluid-lift portion between an influent portion and an effluent portion. A discharger may be disposed below a fluid-lift portion and/or may include a portion external to a separator channel, which may include a downward angle relative to an effluent portion and/or may be configured to minimize the passage of a second fluid into a discharger as the second fluid buoyantly travels in a separator channel from an influent portion to an effluent portion. A second fluid may have a density that is less than the density of a first and/or may be configured to lift a first fluid to a fluid-lift portion.

2022029, Sep 15, 2022

Mar 14, 2022

17/693461

Kenneth James Hintz - Savannah GA, US
Christopher James Hintz - Savannah GA, US
David Grossman - Vienna VA, US

H04N 17/02
H04N 9/04
G01J 3/36

A calibration device receives at least a first multispectral measurement of: a first monochromatic signal taken at a first pixel location; a second multispectral measurement of a second monochromatic signal taken at a second pixel location; and a multiplicity of third multispectral measurements of a spatially distributed wide bandwidth dispersed spectrum, of a wide bandwidth signal, taken at a multiplicity of third pixel locations. The device relates known pixel values of wavelengths to pixel values of measured wavelengths. The device outputs spectrum wavelength and power calibration values for the multispectral imaging system, comprising at least a relation of: a first third pixel location to a first known wavelength; and a second third pixel location to a second known wavelength.

2023001, Jan 19, 2023

Sep 16, 2022

17/946314

Kenneth James Hintz - Savannah GA, US
Christopher James Hintz - Savannah GA, US
David Grossman - Vienna VA, US

G01J 3/36
H04N 9/04
G01J 3/28

An apparatus comprises: a first narrow bandwidth electromagnetic wave filter, a second narrow bandwidth electromagnetic wave filter, and an electromagnetic wave dispersive filter. The first narrow bandwidth electromagnetic wave filter is configured to: convert a wide bandwidth signal to a first monochromatic signal; and direct the first monochromatic signal to at least one first pixel. The second narrow bandwidth electromagnetic wave filter is configured to: convert the wide bandwidth signal to a second monochromatic signal; and direct the second monochromatic signal to at least one second pixel. The electromagnetic wave dispersive filter is configured to: convert the wide bandwidth signal to a spatially distributed wide bandwidth spectrum; and direct the spatially distributed wide bandwidth spectrum to third pixels.

2019021, Jul 18, 2019

Jan 16, 2019

16/248817

Christopher James Hintz - Savannah GA, US

A01G 33/00
A01K 61/10
C12N 1/12
A23K 50/80
A01K 61/50

The present embodiments relate to selectively growing microalgae of a size suitable for the culturing of planktivorous finfish such as sardines, menhaden, herring, anchovy or shellfish such as oysters, clams, mussels, scallops, and sessile invertebrates such as sponges, coral, sea jellies, and other Cnidaria, or sedentary polychaete or bristle worms. A nitrogen to phosphorous content ratio of a nutrient medium may be measured. Nitrogen and/or phosphorous may be added to adjust the nitrogen to phosphorous content ratio in the nutrient medium to a ratio of 100:1 or higher. Microalgae may be grown in the adjusted nutrient medium. The environment may be controlled to produce microalgae with a predetermined diameter.

2018022, Aug 9, 2018

Jan 17, 2018

15/873847

Christopher James Hintz - Savannah GA, US
Kenneth J. Hintz - Fairfax Station VA, US

G01N 1/28
G01N 21/3577

Embodiments of the present disclosure demonstrate cavitating measuring devices. A liquid sample is cavitated to generate bubbles of gas. A frequency-specific radiation is emitted and passes through at least one bubble of gas. The frequency-specific radiation emerges from the bubble of gas as an absorption signal comprising the frequency-specific radiation. The absorption signal is detected and communicated to a system processor. The system processor analyzes the absorption signal data and determines the chemical components present in the liquid sample. Embodiments of the present disclosure describe both static and dynamic liquid samples. The liquid samples can be measured at the sample site.

2016019, Jul 14, 2016

Dec 20, 2015

14/975814

Christopher James Hintz - Savannah GA, US
Tausha Lynn Hintz - Savannah GA, US

A43C 7/08
A41F 9/02
A43C 9/00

A cord tensioning device allows for a cord to be tightened around an object in a quick and easy-to-use manner. The cord tensioning device comprises a body having a front side, a back side, a left edge, a right edge, a top edge, and a bottom edge. At least two apertures are disposed through said body and at least one recessed slot is disposed in said body. At least one recessed slot extends from any of said edges.