公开(公告)号：US20120006049A1

公开(公告)日：2012-01-12

申请号：US12961520

申请日：2010-12-07

申请人： Yu-Ming Sun ,  Ting-Kuan Li ,  Chao-Yu Chen ,  Chi-Bin Wu

发明人： Yu-Ming Sun ,  Ting-Kuan Li ,  Chao-Yu Chen ,  Chi-Bin Wu

IPC分类号： F25B17/08

CPC分类号： F25B17/08 ,  F25B2315/007 ,  F25B2500/18 ,  F28D7/00 ,  Y02A30/278 ,  Y02B30/64

摘要： A split solid adsorption cooling system is disclosed. The split solid adsorption cooling system includes a first adsorption unit, a second adsorption unit, and a shell-and-tube heat exchanger. The first and the second adsorption units are connected to each other via a first pipeline and a second pipeline of the shell-and-tube heat exchanger. While adsorption and desorption take place alternately in the first and the second adsorption units, the temperature of the first and the second pipelines is lowered, thereby decreasing the temperature of water flowing in the shell-and-tube heat exchanger. In addition, the manufacturing costs of the split solid adsorption cooling system can be lowered because the shell-and-tube heat exchanger need not be operated in a vacuum environment. Furthermore, as the shell-and-tube heat exchanger is separate from the first and the second adsorption units, the overall system volume is reduced.

摘要翻译： 公开了一种分体固体吸附冷却系统。 分体固体吸附冷却系统包括第一吸附单元，第二吸附单元和管壳式热交换器。 第一和第二吸附单元经由管壳式热交换器的第一管道和第二管道相互连接。 在第一吸附单元和第二吸附单元中交替地进行吸附和解吸附的同时，第一和第二管道的温度降低，从而降低管壳式热交换器中流动的水的温度。 此外，由于壳管式热交换器不需要在真空环境中操作，所以可以降低分体固体吸附冷却系统的制造成本。 此外，由于管壳式热交换器与第一吸附单元和第二吸附单元分离，所以整体系统体积减小。

公开(公告)号：US08450017B2

公开(公告)日：2013-05-28

申请号：US12961812

申请日：2010-12-07

申请人： To-Wei Huang ,  Ting-Kuan Li ,  Zhan-Yi Lin ,  Yu-Ming Sun ,  Chi-Bin Wu

发明人： To-Wei Huang ,  Ting-Kuan Li ,  Zhan-Yi Lin ,  Yu-Ming Sun ,  Chi-Bin Wu

IPC分类号： C01D7/00 ,  C01G21/14 ,  C01B31/32 ,  H04Q5/22 ,  G05B11/01

CPC分类号： H01M8/04029 ,  H01M8/04067 ,  H01M8/0432 ,  H01M8/0438 ,  H01M8/04701 ,  H01M8/04746 ,  H01M2250/10 ,  H01M2250/405 ,  H04Q2213/13095 ,  Y02B90/14 ,  Y02B90/16

摘要： The present invention discloses a fuel-cell-based cogeneration system with radio frequency identification (RFID) sensors. The fuel-cell-based cogeneration system with RFID sensors includes the fuel-cell-based cogeneration system and an RFID data processing system. The RFID data processing system captures data of the temperature and flow rate from the RFID sensors, while the system data are in turn converted into RFID signals. The RFID data processing system transmits a control signal generated from the RFID signal to control the operation of the fuel-cell-based cogeneration system. Since the RFID transmission technology, the sensor error caused by wires is consequently reduced. Furthermore, overall sensitivity and accuracy of the RFID sensors are increased, which leads to an accompanying increase in the stability of the operating system.

摘要翻译： 本发明公开了一种具有射频识别（RFID）传感器的基于燃料电池的热电联产系统。 具有RFID传感器的基于燃料电池的热电联产系统包括基于燃料电池的热电联产系统和RFID数据处理系统。 RFID数据处理系统捕获来自RFID传感器的温度和流速的数据，同时将系统数据转换成RFID信号。 RFID数据处理系统发送从RFID信号生成的控制信号，以控制基于燃料电池的热电联供系统的运行。 由于RFID传输技术，导线引起的传感器误差因此降低。 此外，RFID传感器的整体灵敏度和精度都增加，这导致操作系统的稳定性的相应增加。

公开(公告)号：US20120102988A1

公开(公告)日：2012-05-03

申请号：US12968644

申请日：2010-12-15

申请人： Zong-Ji Chen ,  Zhan-Yi Lin ,  Ting-Kuan Li ,  Yu-Ming Sun ,  Chi-Bin Wu

发明人： Zong-Ji Chen ,  Zhan-Yi Lin ,  Ting-Kuan Li ,  Yu-Ming Sun ,  Chi-Bin Wu

IPC分类号： F25B15/00

CPC分类号： F25B49/046

摘要： The present invention discloses a method for controlling an adsorption air conditioning equipment. To execute consecutive programs, the adsorption air conditioning equipment performs the steps of: selecting one of a plurality of operation programs according to an execution sequence such that the selected operation program acts as an executable operation program; enabling at least two adsorption beds to operate in response to an executed operation program; switching to the next operation program in the execution sequence according to the operation time of the executed operation program such that the next operation program acts as the next executable operation program; controlling the switching of a plurality of valves according to the executed operation program; enabling the adsorption beds to operate in response to the executed operation program; and switching and executing the operation programs repeatedly until all the operation programs in the execution sequence are completely executed.

摘要翻译： 本发明公开了一种吸附空调设备的控制方法。 为了执行连续的程序，吸附空气调节装置执行以下步骤：根据执行顺序选择多个操作程序中的一个，使得所选择的操作程序作为可执行操作程序; 使至少两个吸附床响应于执行的操作程序而操作; 根据执行的操作程序的操作时间切换到执行序列中的下一个操作程序，使得下一个操作程序充当下一个可执行操作程序; 根据执行的操作程序控制多个阀的切换; 使吸附床响应于执行的操作程序而操作; 并且重复地切换和执行操作程序，直到执行序列中的所有操作程序被完全执行。

公开(公告)号：US20120105206A1

公开(公告)日：2012-05-03

申请号：US12961812

申请日：2010-12-07

申请人： To-Wei Huang ,  Ting-Kuan Li ,  Zhan-Yi Lin ,  Yu-Ming Sun ,  Chi-Bin Wu

发明人： To-Wei Huang ,  Ting-Kuan Li ,  Zhan-Yi Lin ,  Yu-Ming Sun ,  Chi-Bin Wu

IPC分类号： H04Q5/22

CPC分类号： H01M8/04029 ,  H01M8/04067 ,  H01M8/0432 ,  H01M8/0438 ,  H01M8/04701 ,  H01M8/04746 ,  H01M2250/10 ,  H01M2250/405 ,  H04Q2213/13095 ,  Y02B90/14 ,  Y02B90/16

摘要： The present invention discloses a fuel-cell-based cogeneration system with radio frequency identification (RFID) sensors. The fuel-cell-based cogeneration system with RFID sensors includes the fuel-cell-based cogeneration system and an RFID data processing system. The RFID data processing system captures data of the temperature and flow rate from the RFID sensors, while the system data are in turn converted into RFID signals. The RFID data processing system transmits a control signal generated from the RFID signal to control the operation of the fuel-cell-based cogeneration system. Since the RFID transmission technology, the sensor error caused by wires is consequently reduced. Furthermore, overall sensitivity and accuracy of the RFID sensors are increased, which leads to an accompanying increase in the stability of the operating system.

摘要翻译： 本发明公开了一种具有射频识别（RFID）传感器的基于燃料电池的热电联产系统。 具有RFID传感器的基于燃料电池的热电联产系统包括基于燃料电池的热电联产系统和RFID数据处理系统。 RFID数据处理系统捕获来自RFID传感器的温度和流速的数据，同时将系统数据转换成RFID信号。 RFID数据处理系统发送从RFID信号生成的控制信号，以控制基于燃料电池的热电联供系统的运行。 由于RFID传输技术，导线引起的传感器误差因此降低。 此外，RFID传感器的整体灵敏度和精度都增加，这导致操作系统的稳定性的相应增加。

公开(公告)号：US20120102990A1

公开(公告)日：2012-05-03

申请号：US12965974

申请日：2010-12-13

申请人： Chao-Yu Chen ,  Yu-Ming Sun ,  Chi-Bin Wu

发明人： Chao-Yu Chen ,  Yu-Ming Sun ,  Chi-Bin Wu

IPC分类号： F25B49/00

CPC分类号： F25B49/046 ,  F25B17/083 ,  Y02A30/277 ,  Y02A30/278 ,  Y02B30/62 ,  Y02B30/64

摘要： The present invention discloses an adsorption type refrigerator that automatically determines the switchover point. The adsorption type refrigerator includes a first vacuum chamber, a second vacuum chamber, a third vacuum chamber and a waterway structure. The waterway structure is connected to a first adsorption bed in the first vacuum chamber and a second adsorption bed in the second vacuum chamber. The waterway structure simultaneously conveys hot water into the first adsorption bed and cold water into the second adsorption bed, or simultaneously conveys cold water into the first adsorption bed and hot water into the second adsorption bed so as to allow the first and the second adsorption beds to conduct adsorption and desorption alternatively. This alternation creates pressure variation in the three vacuum chambers, which is then utilized to automatically determine the switchover point at which the refrigerator can provide and maintain a cold, stable environment.

摘要翻译： 本发明公开了一种自动确定切换点的吸附型冰箱。 吸附型冰箱包括第一真空室，第二真空室，第三真空室和水路结构。 水路结构连接到第一真空室中的第一吸附床和第二真空室中的第二吸附床。 水道结构同时将热水输送到第一吸附床和冷水进入第二吸附床，或同时将冷水输送到第一吸附床和热水进入第二吸附床，以允许第一和第二吸附床 交替进行吸附和解吸。 这种交替在三个真空室中产生压力变化，然后用于自动确定冰箱可以提供并保持冷，稳定环境的切换点。

公开(公告)号：US20120085111A1

公开(公告)日：2012-04-12

申请号：US12949840

申请日：2010-11-19

申请人： Chao-Yu Chen ,  Yu-Ming Sun ,  Chi-Bin Wu

发明人： Chao-Yu Chen ,  Yu-Ming Sun ,  Chi-Bin Wu

IPC分类号： F25B15/00

CPC分类号： F25B49/046

摘要： An adsorption type refrigerator with thermostatic control includes a first vacuum chamber, a second vacuum chamber, a third vacuum chamber, and a passage structure. The first vacuum chamber accommodates a first adsorption bed, a first condenser, and a first evaporator, and the second vacuum chamber accommodates a second adsorption bed, a second condenser, and a second evaporator. The third vacuum chamber contains a third evaporator. The passage structure guides hot water into the first adsorption bed and guides cold water into the second adsorption bed simultaneously, or guides the cold water into the first adsorption bed and guides the hot water into the second adsorption bed simultaneously. According to the ambient temperature or the temperature of ice water produced by the adsorption refrigerator, the cold water is stopped being guided into the first or the second adsorption bed timely, thereby ceasing the refrigeration temporarily and achieving the thermostatic control.

摘要翻译： 具有恒温控制的吸附型冰箱包括第一真空室，第二真空室，第三真空室和通道结构。 第一真空室容纳第一吸附床，第一冷凝器和第一蒸发器，第二真空室容纳第二吸附床，第二冷凝器和第二蒸发器。 第三真空室包含第三蒸发器。 通道结构将热水引导到第一吸附床中，同时将冷水引导到第二吸附床中，或者将冷水引导到第一吸附床中并将热水同时引导到第二吸附床中。 根据环境温度或吸附式冰箱产生的冰水的温度，停止冷水暂时被引导到第一吸附床或第二吸附床中，暂时停止制冷，实现恒温控制。

公开(公告)号：US20110156665A1

公开(公告)日：2011-06-30

申请号：US12777437

申请日：2010-05-11

申请人： Chen-Kun Chou ,  Zhan-Yi Lin ,  Ting-Kuan Li ,  Yu-Jen Chen ,  Chi-Bin Wu

发明人： Chen-Kun Chou ,  Zhan-Yi Lin ,  Ting-Kuan Li ,  Yu-Jen Chen ,  Chi-Bin Wu

IPC分类号： G05F1/10

CPC分类号： G05F1/575

摘要： A linear modulation voltage transformer circuitry includes a power stage unit, a voltage division unit, a linear modulation unit, an error amplifier, and a recursive controller. The power stage unit adapts an input voltage and outputs a first voltage to the voltage division unit, which outputs a divided voltage. The linear modulation unit receives the divided voltage, compares it with a control voltage, and outputs an error voltage signal to the error amplifier, which amplifies the error voltage signal as an error gain control signal. The recursive controller receives and modulates the error gain control signal and outputs the modulation error gain control signal to the power stage unit as a reference signal so as for the power stage unit to modulate the first voltage. Thus, the first voltage can be varied in real time via the linear modulation unit to meet load demands.

摘要翻译： 线性调制电压互感器电路包括功率级单元，分压单元，线性调制单元，误差放大器和递归控制器。 功率级单元适应输入电压，并向分压单元输出第一电压，分压单元输出分压。 线性调制单元接收分压，将其与控制电压进行比较，并将误差电压信号输出到误差放大器，该误差放大器将误差电压信号放大为误差增益控制信号。 递归控制器接收并调制误差增益控制信号，并将调制误差增益控制信号输出到功率级单元作为参考信号，以使功率级单元调制第一电压。 因此，可以经由线性调制单元实时地改变第一电压以满足负载需求。

公开(公告)号：US08310215B2

公开(公告)日：2012-11-13

申请号：US12777437

申请日：2010-05-11

申请人： Chen-Kun Chou ,  Zhan-Yi Lin ,  Ting-Kuan Li ,  Yu-Jen Chen ,  Chi-Bin Wu

发明人： Chen-Kun Chou ,  Zhan-Yi Lin ,  Ting-Kuan Li ,  Yu-Jen Chen ,  Chi-Bin Wu

IPC分类号： G05F1/70

CPC分类号： G05F1/575

摘要： A linear modulation voltage transformer circuitry includes a power stage unit, a voltage division unit, a linear modulation unit, an error amplifier, and a recursive controller. The power stage unit adapts an input voltage and outputs a first voltage to the voltage division unit, which outputs a divided voltage. The linear modulation unit receives the divided voltage, compares it with a control voltage, and outputs an error voltage signal to the error amplifier, which amplifies the error voltage signal as an error gain control signal. The recursive controller receives and modulates the error gain control signal and outputs the modulation error gain control signal to the power stage unit as a reference signal so as for the power stage unit to modulate the first voltage. Thus, the first voltage can be varied in real time via the linear modulation unit to meet load demands.

摘要翻译： 线性调制电压互感器电路包括功率级单元，分压单元，线性调制单元，误差放大器和递归控制器。 功率级单元适应输入电压，并向分压单元输出第一电压，分压单元输出分压。 线性调制单元接收分压，将其与控制电压进行比较，并将误差电压信号输出到误差放大器，该误差放大器将误差电压信号放大为误差增益控制信号。 递归控制器接收并调制误差增益控制信号，并将调制误差增益控制信号输出到功率级单元作为参考信号，以使功率级单元调制第一电压。 因此，可以经由线性调制单元实时地改变第一电压以满足负载需求。

公开(公告)号：US20110265981A1

公开(公告)日：2011-11-03

申请号：US12792760

申请日：2010-06-03

申请人： Zong-Ji Chen ,  Ting-Kuan Li ,  Yu-Jen Chen ,  Zhan-Yi Lin ,  Chi-Bin Wu

发明人： Zong-Ji Chen ,  Ting-Kuan Li ,  Yu-Jen Chen ,  Zhan-Yi Lin ,  Chi-Bin Wu

IPC分类号： F28F27/00 ,  F28D15/00

CPC分类号： H01M8/04723 ,  H01M8/04029 ,  H01M2250/405 ,  Y02B90/16

摘要： The present invention discloses a system for recycling thermal energy generated from a fuel cell module. The system includes the fuel cell module, a thermal module, a heat-recycle module, and a control module. The thermal module includes a heat transfer apparatus. In addition, the thermal module connects with the fuel cell module, and the heat-recycle module connects with the heat transfer apparatus. The control module detects a starting signal of the fuel cell module and controls the thermal module and the heat-recycle module. Thereby, the thermal energy generated from the fuel cell module is transferred to the heat-recycle module.

摘要翻译： 本发明公开了一种用于再循环由燃料电池模块产生的热能的系统。 该系统包括燃料电池模块，热模块，热循环模块和控制模块。 热模块包括传热装置。 另外，热模块与燃料电池模块连接，热再循环模块与传热装置连接。 控制模块检测燃料电池模块的启动信号并控制热模块和热循环模块。 由此，从燃料电池模块产生的热能转移到热再循环模块。

公开(公告)号：US08390243B2

公开(公告)日：2013-03-05

申请号：US12965971

申请日：2010-12-13

申请人： Yueh-Lin Wu ,  Yu-Ming Sun ,  Chi-Bin Wu

发明人： Yueh-Lin Wu ,  Yu-Ming Sun ,  Chi-Bin Wu

IPC分类号： H02J7/00

CPC分类号： H02J7/34 ,  H02J9/062 ,  H02J2001/004 ,  Y02B90/14

摘要： A charge-controlling system and a method therefor are applicable to a backup power system having a fuel-cell-based power supply and a battery. The charge-controlling system includes a bidirectional converter, a feedback circuit, a voltage controller, a PWM generator, a switch unit and an over-charging protection circuit. The feedback circuit generates a feedback signal corresponding to an output voltage of the bidirectional converter. The voltage controller generates a control voltage according to the feedback signal and a constant voltage, such that the PWM generator generates a PWM signal based on the control voltage. The over-charging protection circuit controls operation of the switch unit according to the feedback signal and a saturation voltage of the battery. When the switch unit electrically connects the bidirectional converter and the PWM generator, the bidirectional converter charges the battery with the power generated by the fuel-cell-based power supply according to the PWM signal.

摘要翻译： 一种充电控制系统及其方法适用于具有基于燃料电池的电源和电池的备用电力系统。 充电控制系统包括双向转换器，反馈电路，电压控制器，PWM发生器，开关单元和过充电保护电路。 反馈电路产生对应于双向转换器的输出电压的反馈信号。 电压控制器根据反馈信号和恒定电压产生控制电压，使得PWM发生器基于控制电压产生PWM信号。 过充电保护电路根据反馈信号和电池的饱和电压来控制开关单元的操作。 当开关单元电连接双向转换器和PWM发生器时，双向转换器根据基于燃料电池的电源根据PWM信号产生的功率为电池充电。