DANIEL REICH
Pilots at Willow Crk Dr, Tucson, AZ

6782294, Aug 24, 2004

Feb 19, 2003

10/368829

Daniel Reich - Tucson AZ
Boris Kaplinsky - Sierra Madre CA
Vladi Reich - Tucson AZ
Yury Stolyarov - Moscow, RU

Arecont Intellectual Property Holdings, LLC - Tucson AZ

G05B 1101

700 19, 700 2, 700 3, 700 20, 700 83, 709217, 709218, 709202, 709203

In an Internet Based Distributed Control System, communication between one or more Clients and one or more controllers is managed by an Internet Hub. A small, inexpensive Web Server reduces the hardware and software resources required to remotely manage controllers through the Internet. One or more Internet Hubs maintain control of the human-machine interface of the systems controllers, increasing security and reducing system cost. Controllers only accept data packets from authorized Internet Hubs and send regular status update information to those Hubs. If alarms are generated, the system is capable of generating and transmitting human readable messages or alarms via e-mail, fax, SMS, or telephone. Controllers are grouped into Local Control Systems in either Peer-to-Peer networks or Master-Slave configurations.

2004023, Nov 25, 2004

May 19, 2003

10/440765

Daniel Reich - Tucson AZ, US
Vladi Reich - Tucson AZ, US
Boris Kaplinsky - Sierra Madre CA, US
Kiril Zuykov - Moscow rigion, RU
Aleksey Login - Tucson AZ, US

Arecont Intellectual Property Holdings, L.L.C.

H01J009/00

445/024000

In a Graphical Programming System, Users may develop algorithmic programs for Controllers or Controller Assemblies utilizes Programming Tools located on a Central Server. Users access the Central Server utilizing a Client connected by the Internet, an Intranet, or a Local Area Network (“LAN”). A programming Project resides on the Central Server but is displayed on the Client, allowing the User to modify the project from the Client. Actions are transmitted as XML, or similar, files which are processed by the Programming Tools. Multiple Users may access the Project simultaneously and a Project may be temporarily interrupted, only to be re-initiated from any Client connected to the Central Server. Additionally, the Graphical Programming System may be utilized to simulate real-world processes. Once a Project is completed, respective machine code may be transmitted to Controllers or Controller Assemblies connected to the Central Server.

7905110, Mar 15, 2011

Apr 2, 2009

12/384365

Daniel Reich - Tucson AZ, US
Michael Burdett - Tucson AZ, US
Vladimir Reich - Tucson AZ, US

F25D 16/00

62434, 62435, 62430, 165 10, 126400

The invention comprises a Thermal Energy Module comprising a tank adapted to hold water or other heat transfer medium (such as water), a water loop for introducing the heat transfer medium and removing the heat transfer medium, and a refrigeration loop comprising a heat exchanger further comprised of an inlet manifold, a heat transfer structure (such as a micro channel or pipe-in-plate panel) and an outlet manifold wherein the heat exchanger is adapted to transfer thermal energy between the heat transfer structure and the heat transfer medium. The Thermal energy Module may be utilized as a component of a heating and cooling system. Such a Thermal Energy Module may be used to store thermal energy during the day and return it during the evening. Additionally, such a Thermal Energy Module may be implemented as an array of such modules and such array of modules may be adapted to fit within the walls of a building or structure.

2011027, Nov 10, 2011

Jul 21, 2011

13/187762

Michael P. Burdett - Tucson AZ, US
Daniel Reich - Tucson AZ, US

Current Energy Controls, LP - Tucson AZ

F24C 15/20, F24F 7/007, G01J 5/10, B08B 15/02

454 67, 126299 D, 250353

An autonomous ventilation system includes a variable-speed exhaust fan, a controller, an exhaust hood, and an infrared radiation (“IR”) sensor. The exhaust fan removes air contaminants from an area. The controller is coupled to the exhaust fan and adjusts the speed of the exhaust fan. The exhaust hood is coupled to the exhaust fan and directs air contaminants to the exhaust fan. The IR sensor is coupled to the controller, detects changes in IR index in a zone below the exhaust hood, and communicates information relating to detected changes in IR index to the controller. The controller adjusts the speed of the exhaust fan in response to information relating to detected changes in IR index. The autonomous ventilation system also includes an alignment laser to indicate a point at which the IR sensor is aimed and a field-of-view (“FOV”) indicator to illuminate the zone in which the IR sensor detects changes in IR index.

2011026, Nov 3, 2011

Jul 13, 2011

13/182304

Michael P. BURDETT - Tucson AZ, US
Daniel Reich - Tucson AZ, US

Current Energy Controls, LP - Tucson AZ

B08B 15/00

454 49

An autonomous ventilation system includes a variable-speed exhaust fan, a controller, an exhaust hood, and a spillage sensor. The exhaust fan removes air contaminants from an area. The controller is coupled to the exhaust fan and adjusts the speed of the exhaust fan. The exhaust hood is coupled to the exhaust fan and directs air contaminants to the exhaust fan. The spillage sensor is coupled to the controller, detects changes in an environmental parameter in a spillage zone adjacent to the exhaust hood, and communicates information relating to detected changes in the environmental parameter to the controller. The controller adjusts the speed of the exhaust fan in response to information relating to detected changes in the environmental parameter.

7832217, Nov 16, 2010

May 7, 2009

12/387776

Daniel Reich - Tucson AZ, US
Michael Burdett - Tucson AZ, US
Vladimir Reich - Tucson AZ, US

F25D 3/02

62 59, 62139

A control system measures the pressure/temperature of the refrigerant within a Thermal Energy Module having a heat exchanger and calculates the thickness of ice within the Thermal Energy Module. A controller calculates an integral starting from the moment when ice accumulation begins: I(t)=∫Tr(τ)*dτ where Tr is the refrigerant saturation temperature changing with time t. The thickness of the ice on one side of the heat exchanger can be calculated using the following formula: X=√(2*I*K*Ui/ρi/ci) where Ui is the thermal conductance of ice ρi is the density of the ice Ci is the latent heat of the ice K is a correction coefficient associated with the type of the heat exchanger.

2009006, Mar 5, 2009

Nov 30, 2007

11/947924

Michael P. Burdett - Tucson AZ, US
Daniel Reich - Tucson AZ, US

Current Energy Controls, LP - Tucson AZ

F24C 15/20, F24F 7/007

454 61, 454341

An autonomous ventilation system includes a variable-speed exhaust fan, a controller, an exhaust hood, and an infrared radiation (“IR”) sensor. The exhaust fan removes air contaminants from an area. The controller is coupled to the exhaust fan and adjusts the speed of the exhaust fan. The exhaust hood is coupled to the exhaust fan and directs air contaminants to the exhaust fan. The IR sensor is coupled to the controller, detects changes in IR index in a zone below the exhaust hood, and communicates information relating to detected changes in IR index to the controller. The controller adjusts the speed of the exhaust fan in response to information relating to detected changes in IR index. The autonomous ventilation system also includes an alignment laser to indicate a point at which the IR sensor is aimed and a field-of-view (“FOV”) indicator to illuminate the zone in which the IR sensor detects changes in IR index.

7711515, May 4, 2010

Oct 16, 2007

11/872756

Michael P. Burdett - Tucson AZ, US
Daniel Reich - Tucson AZ, US
Stolyarov Yury Sergeyevich - Reutov, RU

Current Energy Controls, LP - Tucson AZ

G01K 17/00, G08B 17/00

702136, 340584

In accordance with the present invention, a method for automated parameter measurement includes strategically positioning an identifier tag at a location proximate a first object. The identifier tag stores location-specific information associated with the first object. A sensor in communications with the identifier tag receives the location-specific information from the identifier tag. Additionally, the sensor is used to collect quantitative data associated with a first parameter from the first object. The location-specific information received from the first identifier tag is used to process the quantitative data.

2008027, Nov 6, 2008

Mar 18, 2008

12/050473

Michael P. Burdett - Tucson AZ, US
Daniel Reich - Tucson AZ, US

Current Energy Controls, LP - Tucson AZ

F24C 15/20

454 61

An autonomous ventilation system includes a variable-speed exhaust fan, a controller, an exhaust hood, and a spillage sensor. The exhaust fan removes air contaminants from an area. The controller is coupled to the exhaust fan and adjusts the speed of the exhaust fan. The exhaust hood is coupled to the exhaust fan and directs air contaminants to the exhaust fan. The spillage sensor is coupled to the controller, detects changes in an environmental parameter in a spillage zone adjacent to the exhaust hood, and communicates information relating to detected changes in the environmental parameter to the controller. The controller adjusts the speed of the exhaust fan in response to information relating to detected changes in the environmental parameter.