Jian Zhong Zheng, 5615 Monroe St, New York, NY 10002

7889674, Feb 15, 2011

Aug 8, 2005

11/198168

Jong-hun Park - Suwon-si, KR
Jian liang Zheng - New York NY, US
Myung-jong Lee - New York NY, US

Samsung Electronics Co., Ltd. - Suwon-si
City University of New York - New York NY

H04L 12/28

370254

An address assigning method in a ZigBee network environment formed of a plurality of devices (or nodes), includes: linking the plurality of nodes in a cluster-tree structure; requesting desirable address blocks from a lowest level to a second highest level of the tree ancestor nodes desirable address blocks, respectively; and assigning the desired address blocks to descendents using a top-down procedure.

8123835, Feb 28, 2012

Mar 10, 2008

12/529198

Jian Zheng - Williamsville NY, US
Steven John Pontonio - Eden NY, US
Neil Andrew Stephenson - East Amherst NY, US
Philip Alexander Barrett - Tonawanda NY, US

Praxair Technology, Inc. - Danbury CT

B01D 53/04
B01J 20/18
B01J 20/28

95 90, 95902, 502 79, 502411

High rate and high crush-strength adsorbent particles and collections of such particles, and particularly LiLSX particles, are provided. A binder is employed in the form of a colloidal solution during the method of manufacture. Suitable binders include various silica binders. The particles are made using the steps of mixing, agglomeration, calcination and in the case of certain adsorbents such as LiX and LiLSX, ion exchange and activation. When the adsorption rate is expressed in the form SCRR/ε(mmol mm/g s), desirable collections of adsorbent particles can have values of at least 4. 0 for the highly-exchanged Li (at least 90% Li exchanged) form of the collection of particles and can further be characterized by particles having average crush strengths of at least 0. 9 lbf for particles having an average diameter of at least about 1. 0 mm.

2008026, Oct 30, 2008

Jan 17, 2008

12/007983

Chunshan Song - State College PA, US
James J. Strohm - West Richland WA, US
Jian Zheng - Williamsville NY, US
Weidong Gu - Toronto, CA
Chao Xie - State College PA, US
Xiaoxing Wang - State College PA, US

The Penn State Research Foundation - University Park PA

B01J 21/04
C01B 3/26

252373, 502303, 502304, 502307, 502313, 502315, 502314, 502316, 502302, 502308, 423651, 502327, 502329, 502331, 502328

The invention relates to novel bimetallic and trimetallic catalysts, their manufacture and use in both steam reforming and oxidative steam reforming of liquid fuels such as jet fuels, diesel fuels and gasoline to produce synthesis gas and/or hydrogen for fuel cell applications. The invention further relates to manufacture of synthesis gas and/or hydrogen gas for chemicals synthesis and fuel processing. The catalysts have high sulfur tolerance and carbon resistance when used in steam reforming and/or oxidative steam reforming of heavy hydrocarbon fuels.

2013003, Feb 14, 2013

Aug 10, 2011

13/206773

JIAN ZHENG - Williamsville NY, US
Neil Andrew Stephenson - East Amherst NY, US
Philip Alexander Barrett - Tonawanda NY, US

B01D 53/04
B01D 53/047

95 26, 96115, 96153

The present invention relates generally to a composite adsorbent comprising at least a zeolite-containing COremoval adsorbent and 10% or more of a metal oxide having a heat capacity of at least 20 cal/mol- K (83.7 J/(molK). The composite is preferably used in a multi-layered adsorption system in a cyclic adsorption process. The adsorption system comprises two or more layers wherein the first layer is at least a water vapor removal adsorbent, such as activated alumina, and the second layer is the novel composite adsorbent. The adsorption system is preferably used in a PSA prepurification process prior to cryogenic air separation.

2018017, Jun 28, 2018

Dec 22, 2017

15/852042

Jian Zheng - Williamsville NY, US
Neil A. Stephenson - East Amherst NY, US
Steven J. Pontonio - Eden NY, US
Christopher D. Schotz - Sanborn NY, US
Philip A. Barrett - Tonawanda NY, US

B01D 53/047
B01J 20/18
B01J 20/28
B01J 20/32
F25J 3/04

The present invention relates generally to an attrition resistant core-in-shell composite adsorbent comprising at least a zeolite-containing COremoval adsorbent and a binder on an inert dense core. The attrition resistant core-in-shell composite adsorbent has an attrition loss of less than about 2 wt %. The core-in-shell composite adsorbent is preferably used in a multi-layered adsorption system in a cyclic adsorption process, preferably used in a PSA prepurification process prior to cryogenic air separation.