Tod A. Stansfield - Elm Grove WI Wilfred L. Ayala - Oak Creek WI Stephen R. Wilkinson - Grafton WI Brian W. Huibregtse - Menomonee Falls WI Todd L. Anderson - Menomonee Falls WI Hyunjae Park - Franklin WI
Assignee:
Aqua-Chem, Inc. - Milwaukee WI
International Classification:
F22D 100
US Classification:
122 7R, 122 311, 165166
Abstract:
An exhaust gas heat recuperation system for use with a boiler is disclosed. The heat recuperation system includes a plate-type heat exchanger for exhaust gas heat recovery for exchanging heat between an exhaust gas and a charge gas. The heat exchanger preferably includes a series of exhaust gas plates stacked alternately with, and parallel to, a series of charge gas plates. Each of the exhaust gas plates and charge gas plates have raised contained ridges to form a substantially sinusoidal path for directing the respective gas therealong. The shape of the path reduces exhaust gas particulate deposition. The charge gas flows in a countercurrent to the exhaust gas to facilitate maximum heat transfer. The heat exchange is particularly useful in laminar flow conditions. In one embodiment, the heat exchanger is connected to exhaust gas inlet and outlet conduits, change gas inlet and outlet conduits, and a condensate collection changer as part of an exhaust gas heat recuperation system, for use particularly in steam or hot water boiler applications.
System And Method Of Controlling Condensing And Non-Condensing Boiler Firing Rates
Boris M. Tynkov - Bayside WI, US Brian Huibregtse - Mequon WI, US John Sutphen - Menomonee Falls WI, US
Assignee:
CLEAVER-BROOKS, INC. - Milwaukee WI
International Classification:
F24D 19/10 G05D 23/00 F24D 3/02
US Classification:
237 8 A, 1224483, 237 81, 700300
Abstract:
Hydronic heating systems, controllers for such systems, and methods of using/operating same are disclosed herein. In one example embodiment, such a system includes at least one condensing boiler and at least one non-condensing boiler, and at least one controller configured for utilizing at least one PID control program to generate at least one signal for controlling firing rates of one or more of the boilers based upon sensed water temperature and temperature setpoint inputs. Depending upon the mode of operation, the at least one PID control program is a first PID control program dedicated to controlling only the at least one condensing boiler, or is a second PID control program dedicated to controlling only the at least one non-condensing boiler, or includes both the first and second PID control programs. Also, outside air temperature serves as a basis for generating the temperature setpoint inputs.
Plate Type Heat Exchanger For Exhaust Gas Heat Recovery
Tod A. Stansfield - Elm Grove WI Wilfred L. Ayala - Oak Creek WI Stephen R. Wilkinson - Grafton WI Brian W. Huibregtse - Menomonee Falls WI Todd L. Anderson - Menomonee Falls WI Hyunjae Park - Franklin WI
Assignee:
Aqua-Chem, Inc. - Milwaukee WI
International Classification:
F22D 100
US Classification:
122 7R, 165166
Abstract:
An exhaust gas heat recuperation system for use with a boiler is disclosed. The heat recuperation system includes a plate-type heat exchanger for exhaust gas heat recovery for exchanging heat between an exhaust gas and a charge gas. The heat exchanger preferably includes a series of exhaust gas plates stacked alternately with, and parallel to, a series of charge gas plates. Each of the exhaust gas plates and charge gas plates have raised contained ridges to form a substantially sinusoidal path for directing the respective gas therealong. The shape of the path reduces exhaust gas particulate deposition. The charge gas flows in a countercurrent to the exhaust gas to facilitate maximum heat transfer. The heat exchange is particularly useful in laminar flow conditions. In one embodiment, the heat exchanger is connected to exhaust gas inlet and outlet conduits, change gas inlet and outlet conduits, and a condensate collection changer as part of an exhaust gas heat recuperation system, for use particularly in steam or hot water boiler applications.
System And Method Of Controlling Condensing And Non-Condensing Boiler Firing Rates
- Milwaukee WI, US Boris M. Tynkov - Bayside WI, US Brian Huibregtse - Mequon WI, US John Sutphen - Menomonee Falls WI, US
International Classification:
F24D 19/10 F24D 12/02 F24H 8/00 F24D 3/02
Abstract:
Hydronic heating systems, controllers for such systems, and methods of using/operating same are disclosed herein. In one example embodiment, such a system includes at least one condensing boiler and at least one non-condensing boiler, and at least one controller configured for utilizing at least one PID control program to generate at least one signal for controlling firing rates of one or more of the boilers based upon sensed water temperature and temperature setpoint inputs. Depending upon the mode of operation, the at least one PID control program is a first PID control program dedicated to controlling only the at least one condensing boiler, or is a second PID control program dedicated to controlling only the at least one non-condensing boiler, or includes both the first and second PID control programs. Also, outside air temperature serves as a basis for generating the temperature setpoint inputs.
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