Patents by Inventor Diana D. Brehob
Diana D. Brehob has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
-
Patent number: 10098509Abstract: It is well known that plastic shower curtains can develop mildew and/or mold where the curtain adheres to another surface and remains moist, such as the edge of a bathtub. A shower curtain with at least a portion of the surface being non-smooth is disclosed. In some embodiments, appendages extend outwardly from the surface of the curtain. The appendages prevent the surface of the curtain from adhering to another surface via surface tension of water. Furthermore, the appendages create an air gap that enables air to flow freely between the curtain and its adjacent surface. The appendages also reduce the surface area of the curtain in contact with the adjacent surface.Type: GrantFiled: January 28, 2016Date of Patent: October 16, 2018Inventors: Jonathan Haas, Ryan McGann, Diana D. Brehob
-
Publication number: 20160220076Abstract: It is well known that plastic shower curtains can develop mildew and/or mold where the curtain adheres to another surface and remains moist, such as the edge of a bathtub. A shower curtain with at least a portion of the surface being non-smooth is disclosed. In some embodiments, appendages extend outwardly from the surface of the curtain. The appendages prevent the surface of the curtain from adhering to another surface via surface tension of water. Furthermore, the appendages create an air gap that enables air to flow freely between the curtain and its adjacent surface. The appendages also reduce the surface area of the curtain in contact with the adjacent surface.Type: ApplicationFiled: January 28, 2016Publication date: August 4, 2016Inventors: Jonathan Haas, Ryan McGann, Diana D. Brehob
-
Patent number: 8191533Abstract: A method for operation of an engine fuel system includes initiating a mitigating action based on a fuel rail pressure response, the fuel rail pressure response occurring after an engine shut-down. The mitigating action includes disabling vehicle operation if fuel rail pressure drops below a threshold value after activation of one of the higher or lower pressure pumps, the activation occurring before a subsequent engine start. In this way, a distinction can be made between internal and external leaks, allowing the mitigating action taken to be adjusted accordingly.Type: GrantFiled: July 9, 2010Date of Patent: June 5, 2012Assignee: Ford Global Technologies, LLCInventors: Joseph Norman Ulrey, Ross Dykstra Pursifull, Diana D. Brehob
-
Patent number: 8181636Abstract: A method is disclosed for making a transition from fueling an engine with hydrogen to another fuel. That other fuel may be gasoline, a gasoline and alcohol mixture, or gaseous fuels, as examples. The other fuel has the capability of providing higher BMEP than the hydrogen because of better air utilization and because the other fuel occupies less volume of the combustion chamber. Because a desirable equivalence ratio to burn hydrogen is at 0.5 or less and a desirable equivalence ratio to burn other fuel is at 1.0, when a demand for BMEP that leads to a transition change from hydrogen fuel to the other fuel, the amount of air supplied to the engine is decreased to provide more torque and vice versa. During a transition in which liquid fuel supply is initiated, it may be desirable to continue to provide some hydrogen, not leaner than 0.1 hydrogen equivalence ratio.Type: GrantFiled: June 25, 2009Date of Patent: May 22, 2012Assignee: Ford Global Technologies LLCInventors: William Francis Stockhausen, Diana D. Brehob
-
Patent number: 8133842Abstract: A method of manufacturing an emissions treatment device for an internal combustion engine includes disposing washcoated fibers between layers of a porous substrate to form multiple substantially parallel layers with a first group of layers at least partially open along the entire length of the layer. The porous substrate may be a stainless steel mesh with the method further including washcoating the substrate prior to disposing the washcoated fibers between the layers.Type: GrantFiled: October 21, 2010Date of Patent: March 13, 2012Assignee: Ford Global Technologies, LLCInventors: Ray Willey, Bret A. Zimmerman, David J. Kubinski, Diana D. Brehob
-
Patent number: 8055437Abstract: A method and system for estimating CO2 produced by an internal combustion engine disposed in a vehicle and transmitting the CO2 produced to a display device within the vehicle are disclosed. Estimated CO2 produced is based on amount of fuel consumed and fuel composition, e.g., alcohol content in a gasoline-alcohol blend. The amount of fuel consumed is computed based on fuel pulse width commanded to fuel injectors disposed in the engine, the pressure drop across the fuel injectors, and fuel injector nozzle cross-section. Instantaneous CO2 produced and/or average CO2 produced can be computed and displayed. Instantaneous CO2 produced is averaged over a short interval with the display updated regularly. Average CO2 produced is averaged over a typically longer interval, being reset, in one embodiment, by an operator of the vehicle depressing a reset button.Type: GrantFiled: March 17, 2009Date of Patent: November 8, 2011Assignee: Ford Global Technologies, LLCInventors: John Proietty, Diana D. Brehob
-
Patent number: 8046153Abstract: A fuel compensation factor (FCF) is determined to account for the amount of oxygenated fuel blended in diesel fuel. In one embodiment, the FCF is based on an expected exhaust gas oxygen concentration compared to an actual exhaust gas oxygen concentration. The FCF is used to estimate an amount of oxygenated fuel in the blend. Such estimate can be used to adjust the exhaust temperature model, which is used at least in determining the temperature in aftertreatment devices, the fuel dilution model which affects oil change recommendations, and the diesel particulate filter loading model which affects regenerations. Biodiesels are more prone to waxing at lower temperatures. The estimated amount of biodiesel and the temperature in the injection system are used to prevent and/or delay starting when it is predicted that too much wax exists in the fuel system.Type: GrantFiled: July 20, 2010Date of Patent: October 25, 2011Assignee: Ford Global Technologies, LLCInventors: Eric Kurtz, Diana D. Brehob, Christian Winge Vigild, David Joseph Dronzkowski, Jonathan James Pilbeam, James Eric Anderson
-
Patent number: 7992388Abstract: A method for estimating the output temperature of the output compressor of a two-stage turbocharger. The method includes: storing a composite relationship relating temperature ratio across a pair of compressors of the two-stage turbocharger as a function of mass flow through such pair of compressors and pressure drop across the pair of the compressors; calculating the pressure ratio equal to the pressure at an input to the first one of the pair of compressors to the pressure at the output of the second one of the pair compressor; using the composite relationship and an output of a mass flow at the input to the first one of the pair of compressors and the calculated pressure ratio to determine the temperature ratio across the pair of compressors; and calculating the estimated output temperature of the second one of the pair of compressors by multiplying the determined temperature ratio across the pair of compressors by a temperature at the input of the first one of the pair of compressors.Type: GrantFiled: September 18, 2007Date of Patent: August 9, 2011Assignee: Ford Global Technologies, LLCInventors: Yong Shu, Michiel J. Van Nieuwstadt, Diana D. Brehob
-
Publication number: 20110166767Abstract: A fuel compensation factor (FCF) is determined to account for the amount of oxygenated fuel blended in diesel fuel. In one embodiment, the FCF is based on an expected exhaust gas oxygen concentration compared to an actual exhaust gas oxygen concentration. The FCF is used to estimate an amount of oxygenated fuel in the blend. Such estimate can be used to adjust the exhaust temperature model, which is used at least in determining the temperature in aftertreatment devices, the fuel dilution model which affects oil change recommendations, and the diesel particulate filter loading model which affects regenerations. Biodiesels are more prone to waxing at lower temperatures. The estimated amount of biodiesel and the temperature in the injection system are used to prevent and/or delay starting when it is predicted that too much wax exists in the fuel system.Type: ApplicationFiled: July 20, 2010Publication date: July 7, 2011Applicant: FORD GLOBAL TECHNOLOGIES, LLCInventors: Eric Kurtz, Diana D. Brehob, Christian Winge Vigild, David Joseph Dronzkowski, Jonathan James Pilbeam, James Eric Anderson
-
Publication number: 20110035941Abstract: A method of manufacturing an emissions treatment device for an internal combustion engine includes disposing washcoated fibers between layers of a porous substrate to form multiple substantially parallel layers with a first group of layers at least partially open along the entire length of the layer. The porous substrate may be a stainless steel mesh with the method further including washcoating the substrate prior to disposing the washcoated fibers between the layers.Type: ApplicationFiled: October 21, 2010Publication date: February 17, 2011Applicant: FORD GLOBAL TECHNOLOGIES, LLCInventors: Ray Willey, Bret A. Zimmerman, David J. Kubinski, Diana D. Brehob
-
Patent number: 7833495Abstract: An emissions treatment device includes a substrate having multiple parallel channels/layers of a porous material, the channels/layers including a first group of channels/layers at least partially open along their length from an upstream end to a downstream end, and a second group of channels/layers that are at least partially open at the downstream end and may be substantially blocked at an upstream end, the parallel channels having complementary geometries and/or sizes. Coated metallic fibers or fleece facilitates flow of exhaust through walls of the first group into the second group of channels. Flow diverters or scoops may be formed in the walls between the first and second groups of channels to divert exhaust flow from the first group to the second group of channels. Catalyzed mesh sheets may be supported by perforated stainless steel sheets containing small passages and/or scoops to complement the useful wallflow by structure and flow design.Type: GrantFiled: February 2, 2007Date of Patent: November 16, 2010Assignee: Ford Global Technologies, LLCInventors: Ray Willey, Bret A. Zimmerman, David J. Kubinski, Diana D. Brehob
-
Publication number: 20100275880Abstract: A method for operation of a fuel delivery system in an internal combustion engine including a lower pressure pump, a higher pressure pump fluidly coupled downstream of the lower pressure pump, and a fuel rail fluidly coupled downstream of the high pressure pump. The method including initiating a mitigating action based on a fuel rail pressure response, the fuel rail pressure response occurring after an engine shut-down, where the mitigating action includes disabling vehicle operation if fuel rail pressure drops below a threshold value after activation of one of the pumps, the activation occurring before a subsequent engine start, the subsequent engine start occurring after the engine shut-down, and where the mitigating action includes adjusting operation of one of the pumps during the subsequent engine start if fuel rail pressure achieves at least the threshold value after or during the activation.Type: ApplicationFiled: July 9, 2010Publication date: November 4, 2010Applicant: FORD GLOBAL TECHNOLOGIES, LLCInventors: Joseph Norman Ulrey, Ross Dykstra Pursifull, Diana D. Brehob
-
Publication number: 20100241339Abstract: A method and system for estimating CO2 produced by an internal combustion engine disposed in a vehicle and transmitting the CO2 produced to a display device within the vehicle are disclosed. Estimated CO2 produced is based on amount of fuel consumed and fuel composition, e.g., alcohol content in a gasoline-alcohol blend. The amount of fuel consumed is computed based on fuel pulse width commanded to fuel injectors disposed in the engine, the pressure drop across the fuel injectors, and fuel injector nozzle cross-section. Instantaneous CO2 produced and/or average CO2 produced can be computed and displayed. Instantaneous CO2 produced is averaged over a short interval with the display updated regularly. Average CO2 produced is averaged over a typically longer interval, being reset, in one embodiment, by an operator of the vehicle depressing a reset button.Type: ApplicationFiled: March 17, 2009Publication date: September 23, 2010Applicant: FORD GLOBAL TECHNOLOGIES, LLCInventors: John Proietty, Diana D. Brehob
-
Patent number: 7762234Abstract: A method for operation of a fuel delivery system in an internal combustion engine including a lower pressure pump, a higher pressure pump fluidly coupled downstream of the lower pressure pump, and a fuel rail fluidly coupled downstream of the high pressure pump. The method including initiating a mitigating action based on a fuel rail pressure response, the fuel rail pressure response occurring after an engine shut-down, where the mitigating action includes disabling vehicle operation if fuel rail pressure drops below a threshold value after activation of one of the pumps, the activation occurring before a subsequent engine start, the subsequent engine start occurring after the engine shut-down, and where the mitigating action includes adjusting operation of one of the pumps during the subsequent engine start if fuel rail pressure achieves at least the threshold value after or during the activation.Type: GrantFiled: April 22, 2008Date of Patent: July 27, 2010Assignee: Ford Global Technologies, LLCInventors: Joseph Norman Ulrey, Ross Dykstra Pursifull, Diana D. Brehob
-
Patent number: 7685996Abstract: An engine system and method are disclosed for controlling pre-ignition of an alcohol fuel. In one embodiment, the fuel injection timing is adjusted to cause the fuel to avoid combustion chamber surfaces. In another embodiment, the fuel injection timing is adjusted to spray the fuel directly onto the piston surface to cool the piston. Also disclosed is a cylinder cleaning cycle in which engine knock is purposely caused for one to hundreds of engine cycles by adjusting the fuel content away from alcohol toward gasoline. Further measures to cause knock which are disclosed: adjusting spark timing, intake boost, exhaust gas fraction in the cylinder, cam timing, and transmission gear ratio.Type: GrantFiled: January 17, 2007Date of Patent: March 30, 2010Assignee: Ford Global Technologies, LLCInventor: Diana D. Brehob
-
Publication number: 20090260606Abstract: A method is disclosed for making a transition from fueling an engine with hydrogen to another fuel. That other fuel may be gasoline, a gasoline and alcohol mixture, or gaseous fuels, as examples. The other fuel has the capability of providing higher BMEP than the hydrogen because of better air utilization and because the other fuel occupies less volume of the combustion chamber. Because a desirable equivalence ratio to burn hydrogen is at 0.5 or less and a desirable equivalence ratio to burn other fuel is at 1.0, when a demand for BMEP that leads to a transition change from hydrogen fuel to the other fuel, the amount of air supplied to the engine is decreased to provide more torque and vice versa. During a transition in which liquid fuel supply is initiated, it may be desirable to continue to provide some hydrogen, not leaner than 0.1 hydrogen equivalence ratio.Type: ApplicationFiled: June 25, 2009Publication date: October 22, 2009Applicant: FORD GLOBAL TECHNOLOGIES, LLCInventors: William Francis Stockhausen, Diana D. Brehob
-
Publication number: 20090260601Abstract: A method for operation of a fuel delivery system in an internal combustion engine including a lower pressure pump, a higher pressure pump fluidly coupled downstream of the lower pressure pump, and a fuel rail fluidly coupled downstream of the high pressure pump. The method including initiating a mitigating action based on a fuel rail pressure response, the fuel rail pressure response occurring after an engine shut-down, where the mitigating action includes disabling vehicle operation if fuel rail pressure drops below a threshold value after activation of one of the pumps, the activation occurring before a subsequent engine start, the subsequent engine start occurring after the engine shut-down, and where the mitigating action includes adjusting operation of one of the pumps during the subsequent engine start if fuel rail pressure achieves at least the threshold value after or during the activation.Type: ApplicationFiled: April 22, 2008Publication date: October 22, 2009Applicant: FORD GLOBAL TECHNOLOGIES, LLCInventors: Joseph Norman Ulrey, Ross Dykstra Pursifull, Diana D. Brehob
-
Publication number: 20090101111Abstract: An engine system and method are disclosed for controlling pre-ignition of an alcohol fuel. In one embodiment, the fuel injection timing is adjusted to cause the fuel to avoid combustion chamber surfaces. In another embodiment, the fuel injection timing is adjusted to spray the fuel directly onto the piston surface to cool the piston. Also disclosed is a cylinder cleaning cycle in which engine knock is purposely caused for one to hundreds of engine cycles by adjusting the fuel content away from alcohol toward gasoline. Further measures to cause knock which are disclosed: adjusting spark timing, intake boost, exhaust gas fraction in the cylinder, cam timing, and transmission gear ratio.Type: ApplicationFiled: January 17, 2007Publication date: April 23, 2009Inventor: Diana D. Brehob
-
Publication number: 20090090332Abstract: In an internal combustion engine having both a port injector and a direct injector supplying fuel to a cylinder of the engine, a method is disclosed for avoiding deposit formation on and/or inside the tip of the direct injector. The tip temperature is estimated. When the tip temperature exceeds a threshold temperature at which deposits are formed, the amount of fuel delivered by the direct injector is increase.Type: ApplicationFiled: October 3, 2007Publication date: April 9, 2009Inventor: Diana D. Brehob
-
Publication number: 20090071148Abstract: A method for estimating output compressor output temperature for a two-stage turbocharger. The method includes: storing a composite relationship relating temperature ratio across a pair of compressors of the two-stage turbocharger as a function of mass flow through such pair of compressors and pressure drop across the pair of the compressors; calculating the pressure ratio equal to the pressure at an input to the first one of the pair of compressors to the pressure at the output of the second one of the pair compressor; using the composite relationship and an output of a mass flow at the input to the first one of the pair of compressors and the calculated pressure ratio to determine the temperature ratio across the pair of compressors; and calculating the estimated output temperature of the second one of the pair of compressors by multiplying the determined temperature ratio across the pair of compressors by a temperature at the input of the first one of the pair of compressors.Type: ApplicationFiled: September 18, 2007Publication date: March 19, 2009Inventors: Yong Shu, Michiel J. Van Nieuwstadt, Diana D. Brehob