Thuya Aung

Aung Thuya

Schachspielerprofil from Thuya Aung: Thuya Aung files USPTO patents and grants patents. Aung Thuya - 6 public records found Aung Thuya has been living in Fort Wayne, Indiana. It was Thuya Aung who used to live in Lutherville Timonium, Maryland. Found a Thuya in Lutherville Timonium, Maryland 21093. That Thuya was ID'd in Lutherville Timonium, Maryland.

43 years old, Thuya Aung works in Derwood, Maryland 20855. and Thuya Aung used to live in Houston, Texas.

"Numeric ODE solutions receiving the first integrals" by Thuya Aung

Measuring the changes in power by a dynamic load is essential for the studies of dynamic mechanical engineering. Through the analysis of the Lagrange and Hamiltonic dynamic, the different fields of the Lagrange and Hamiltonic dynamic have arisen. Describing these schemes, this dissertation discussed and numeric approaches to a system of formulae of Lagrange, and First Integral Hhamiltonian integral solu-tions.

The Thuya Aung Inventions, Patents and Patents

Summary: A coil contains a section of coil for transferring warmth between a coolant and a coolant and a duct section. A first channel and a second channel for feeding the coolant to the coil section and an inlet channel for feeding the coolant to the first channel and the second channel.

Both the first pass and the second pass specify a first opening section and a second opening section that opens at one end of the inlet channel. There is a min. clearance between an opening of the first opening section and an inner face of the inlet duct which equals a min. clearance between an opening of the second opening section and the inner face of the inlet duct.

Summary: An evaporation device consists of an evaporation device that has been designed to vaporize a coolant and a capacitor that has been designed to uncompress the coolant. There are two long ends of the vaporizer connected to the vaporizer. There is at least one central section between the two long ends of the vaporizer tubes attached to the vaporizer by pressure contact with the vaporizer.

Summary: In an integral assembly with an evaporation device and an ejectors in a container of the evaporation device, a first oscillation -insulating sealing element and a second oscillation-insulating sealing element are arranged in a space between an external face of the ejection device and an internal face of the container. This is a first sealing element that isolates vibrations between a coolant outlet opening and a coolant intake opening of the ejectors in the lengthwise direction, and the second sealing element that isolates vibrations is between a coolant inflow of the ejectors and the coolant intake opening in the lengthwise direction. 2.

A vaporizer assembly comprises a first coil arranged to carry out thermal transfer between the coolant streaming therein from a coolant intake and ambient temperature, a by-pass duct through which the coolant streaming out of the coolant intake passes while the first coil is bypassed, characterized by a second coil arranged to carry out a thermal transfer between ambient temperature and premixed refrigerants in which the refrigerants are blended after pass through the first coil and the refrigerants after pass through the by-pass duct, and a rate setting section arranged to set a rate of the quantity of coolant through the first coil and a rate of the coolant streaming through the by-pass duct.

Accordingly, the first and second exchangers can be set up to have sections in which the coolant is dry in a temperature between 0.6 and 0.9. Summary: At least one vaporiser with an ejectors is incorporated in an integral refrigeration circuit equipment assembly, which has a section of nozzles for the decompression of refrigerating agent and a refrigerating agent inlet opening from which refrigerating agent is sucked in.

A push-in opening is provided in the integral assembly in a lengthwise end face of a container of the vaporiser so that the ejectors are pushed out of the push-in opening into the container and a stopper is provided to close the push-in opening. There is also a distance piece with a space between the stopper and the ejectors and a fastening element between the container's lengthwise end face and an expanding poppet for fastening the expanding poppet to the container's lengthwise end face.

At least one of the fastening elements, the dowels and the spacers in the integral assembly consists of a plastic inlay.

It comprises a variety of pipes that define coolant channels through which coolant passes, a reservoir located at one end of the pipes to distribute coolant into the pipes and collect coolant from the pipes. In addition, the end section has a perforated section for insertion of the ejectors, and the ejectors are placed from the perforated section into an interior of the shell.

Summary: A refrigeration circuit apparatus assembly comprises an ejectors having a jet portion that uncompresses refrigerating fluid and a refrigerating fluid intake connection from which refrigerating fluid is sucked in through a high-speed refrigerating fluid stream ejected from the jet portion, a first vaporizer coupled to the output of the ejectors, and a second vaporizer coupled to the refrigerating fluid intake connection of the ejectors.

Each of the first evaporators and the second evaporators has a shell construction containing a reservoir for the distribution of refrigerants in or collection of coolant from coolant ducts of a part of a heatsink. In it, the fuel cell has a first chamber through which the coolant escaping from the exhaust of the ejectors passes into a part of the first vaporizer and a second chamber through which the coolant to be sucked into the coolant intake connection passes into a part of the same.

Summary: An evaporation assembly consists of an ejectors, a windward side coil for evaporation of a pressure-side coolant streaming from the ejectors and a windward side coil for evaporation of a suction-side coolant sucked into the ejectors. It has a jet for the decompression of the coolant and a coolant inlet opening from which the coolant is sucked in by a stream of coolant rapidly escaping from the jet.

On the windward side, the coil has a coolant overheating surface displaced by a coolant overheating surface of the windward coil in a vertical plane to an amount of coolant. Summary: A coil contains a section of coil for transferring warmth between a coolant and a coolant and a duct section.

A first channel and a second channel for feeding the coolant to the exchanger section and an inlet channel for feeding the coolant to the first channel and the second channel. Both the first pass and the second pass specify a first opening section and a second opening section that opens at one end of the inlet channel.

There is a min. clearance between an opening of the first opening section and an inner face of the inlet duct which equals a min. clearance between an opening of the second opening section and the inner face of the inlet duct.

There are two long ends of the vaporizer connected to the vaporizer. There is at least one central section between the two long ends of the vaporizer tubes attached to the vaporizer by pressure contact with the vaporizer. A vaporizer assembly comprises a first coil arranged to carry out thermal transfer between the coolant streaming therein from a coolant intake and ambient temperature, a by-pass duct through which the coolant streaming out of the coolant intake is passed while the first coil is bypassed,

characterized by a second coil arranged to carry out a thermal transfer between ambient temperature and premixed refrigerants in which the refrigerants are blended after pass through the first coil and the refrigerants after pass through the by-pass duct, and a rate setting section arranged to set a rate of the quantity of coolant through the first coil and a rate of the coolant streaming through the by-pass duct.

Accordingly, the first and second exchangers can be set up to have sections in which the coolant is dry in a temperature between 0.6 and 0.9. Summary: In an integral assembly with an evaporation device and an ejectors in a container of the evaporation device, a first oscillation -insulating sealing element and a second oscillation-insulating sealing element are arranged in a space between an external face of the ejection device and an internal face of the container.

This is a first sealing element that isolates vibrations between a coolant outlet opening and a coolant intake opening of the ejectors in the lengthwise direction, and the second sealing element that isolates vibrations is between a coolant inflow of the ejectors and the coolant intake opening in the lengthwise direction. 2. Summary: At least one vaporiser with an ejectors is incorporated in an integral refrigeration circuit equipment assembly, which has a section of nozzles for the decompression of refrigerating agent and a refrigerating agent intake opening from which refrigerating agent is sucked in.

A push-in bore is provided in the integral assembly in a lengthwise end face of a container of the vaporiser, so that the injector is introduced from the push-in bore into the container and a stopper is provided for closing the push-in bore. There is also a distance piece with a space between the stopper and the ejectors and a fastening element between the container's lengthwise end face and an expanding poppet for fastening the expanding poppet to the container's lengthwise end face.

At least one of the fastening elements, the dowels and the spacers in the integral assembly consists of a plastic inlay. Summary: A recuperator comprises a multiplicity of fluids channels through which a coolant enters with a coolant through which a coolant flows, a container arranged over the intake parts of the fluids channels to distribute a stream of coolant to the fluids channels, and a retaining member arranged over the intake parts within the container to buffer the coolant in the container.

As an example, the recuperator can be used as an evaporation plant for a coolant circulation system with ejectors. Summary: A refrigeration circuit apparatus assembly comprises an ejectors having a jet portion that uncompresses refrigerating fluid and a refrigerating fluid intake connection from which refrigerating fluid is sucked in through a high-speed refrigerating fluid stream ejected from the jet portion, a first vaporizer coupled to the output of the ejectors, and a second vaporizer coupled to the refrigerating fluid intake connection of the ejectors.

Each of the first evaporators and the second evaporators has a shell construction containing a reservoir for the distribution of refrigerants in or collection of coolant from coolant ducts of a part of a heatsink. In it, the fuel cell has a first chamber through which the coolant escaping from the exhaust of the ejectors passes into a part of the first vaporizer and a second chamber through which the coolant to be sucked into the coolant intake connection passes into a part of the same.

Summary: An integral refrigeration circuit apparatus assembly comprises an ejectors having a jet portion for the decompression of refrigerating agent and an evaporation apparatus arranged to vaporize the refrigerating agent sucked into a refrigerating inlet of the ejectors or the refrigerating agent escaping from an exhaust of the ejectors. It comprises a variety of pipes that define coolant channels through which coolant passes, a reservoir arranged at one end of the pipes to distribute coolant into the pipes and collect coolant from the pipes.

In addition, the end section has a perforated section for insertion of the ejectors, and the ejectors are placed from the perforated section into an interior of the shell. Summary: An evaporation assembly consists of an ejectors, a windward side coil for evaporation of a pressure-side coolant streaming from the ejectors and a windward side coil for evaporation of a suction-side coolant sucked into the ejectors.

It has a jet for the decompression of the coolant and a coolant inlet opening from which the coolant is sucked in by a stream of coolant rapidly escaping from the jet. On the windward side, the coil has a coolant overheating surface displaced by a coolant overheating surface of the windward coil in a vertical plane to an amount of cooling current.

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