| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 一种基于连续可变一次风压力的锅炉负荷控制设计方法 | CN201610577230.3 | 2016-07-21 | CN106196161A | 2016-12-07 | 刘永红; 彭钢; 张洪涛; 高志存; 徐欣航 |
| 本发明公开了一种基于连续可变一次风压力的锅炉负荷控制设计方法,通过对双进双出磨煤机一次风压调整锅炉负荷影响参数的分析和计算,得出一次风压力和磨煤机容量风门的联合控制策略。本发明的基于连续可变一次风压力的锅炉负荷控制设计方法,可以降低锅炉的一次风机的出力水平达到节电目的;保证磨煤机始终在经济及安全的工作点运行,提高磨煤机的工作效率;可以极大的提高机组的变负荷速率,达到中储式机组的控制水平;可实现机组协调控制稳定投入加快机组的变负荷速率,以提高机组的安全运行水平。 | ||||||
| 2 | 器具监视设备 | CN200980118646.7 | 2009-02-27 | CN102037281B | 2012-11-21 | 本田刚司; 武智弘; 村濑孝治; 安田宪司; 难波三男; 久保和男; 斋藤尚 |
| 传统的器具监视设备仅处理使用的燃气量和用于燃气切断的情况的安全信息,并且不能解决想要获得关于燃气燃烧器具的使用对于地球环境的影响的信息的社会需要,所述影响例如是二氧化碳排出量。二氧化碳排出量计算单元(4)基于从器具确定单元(2)输出的客户使用的燃气器具、其燃气流量信号和在二氧化碳排出量数据存储单元(3)中存储的与燃气器具相关的二氧化碳排出量数据来计算二氧化碳排出量。因此,能够确定客户使用燃气器具产生的二氧化碳排出量。 | ||||||
| 3 | 器具监视设备 | CN200980118646.7 | 2009-02-27 | CN102037281A | 2011-04-27 | 本田刚司; 武智弘; 村濑孝治; 安田宪司; 难波三男; 久保和男; 斋藤尚 |
| 传统的器具监视设备仅处理使用的燃气量和用于燃气切断的情况的安全信息,并且不能解决想要获得关于燃气燃烧器具的使用对于地球环境的影响的信息的社会需要,所述影响例如是二氧化碳排出量。二氧化碳排出量计算单元(4)基于从器具确定单元(2)输出的客户使用的燃气器具、其燃气流量信号和在二氧化碳排出量数据存储单元(3)中存储的与燃气器具相关的二氧化碳排出量数据来计算二氧化碳排出量。因此,能够确定客户使用燃气器具产生的二氧化碳排出量。 | ||||||
| 4 | Appliance monitoring device | JP2008132129 | 2008-05-20 | JP2009281612A | 2009-12-03 | HONDA GOJI; TAKECHI HIROSHI; MURASE KOJI; YASUDA KENJI; NANBA MITSUO; KUBO KAZUO; SAITO TAKASHI |
| <P>PROBLEM TO BE SOLVED: To cope with social needs of the information relating to influence (for example, emission of CO2) on global environment by use of a gas burning appliance. <P>SOLUTION: A CO2 emission calculating section 4 calculates the emission of CO2 on the basis of the gas appliance used by a customer and its gas flow rate signal output from an appliance discriminating section 2, and the data on CO2 emission of the gas appliance memorized in a CO2 emission data memorizing section 3, so that CO2 emission generated when the customer uses the gas appliance can be determined. <P>COPYRIGHT: (C)2010,JPO&INPIT | ||||||
| 5 | HEATING APPLIANCE | EP96909924.0 | 1996-04-19 | EP0821777A1 | 1998-02-04 | JOYCE, John, Vincent; RICHARDS, David, Alexander |
| A gas heater is provided with a combustion status sensor that provides heater performance data to a controller that controls the heater according to the sensor data and stored calibration parameters optimised for the particular heater. | ||||||
| 6 | Heating system shut-off system using detector and existing safety switch or fuel valve | US719636 | 1991-06-24 | US5189392A | 1993-02-23 | Carl E. Kass; Arthur W. Little |
| A safety apparatus for shutting off a unit having a manually operated power interruption switch upon detecting a predetermined condition. In addition, to power interruption a fluid fuel supply to a combustion unit having a manually operated interruption valve arranged in the line is also interrupted. | ||||||
| 7 | Furnace protective device | US361429 | 1989-06-05 | US5024595A | 1991-06-18 | David B. Schumacher; Steven J. Bakowski |
| A burner control for a condensing furnace having a flame proving circuit that incorporates the flame at the burner to be closed and that opens upon absence of a flame to cause a gas valve to close and block the flow of gas to the burner. A short circuit shunting the flame proving circuit includes a probe that projects into the outlet manifold of the condensing furnace. If liquid level in the outlet manifold reaches the probe, a short circuit is closed between the probe and a ground on the manifold. The control to the valve is energized to close the valve in the same manner as if the flame had extinguished at the burner. Upon closing the gas valve, the burner is extinguished. | ||||||
| 8 | Modulating method and system for kiln firing | US122225 | 1987-11-18 | US4794870A | 1989-01-03 | Hosagrahar C. Visvesvaraya |
| The invention relates to a method and system for modulating the firing temperature in a rotary kiln. The method comprises determining the absolute content of one or more inorganic constituents present in the coal feed for determining the total ash content in the coal. In the event that the temperature in the kiln is different from the required temperature, then a sweetner fuel is fed to the burner with or without a change in the flow of coal. Alternatively, only the amount of flow of coal to the burner is reduced or increased. | ||||||
| 9 | Gas burner control system | US957110 | 1978-11-02 | US4245978A | 1981-01-20 | Leon del Valle |
| An improved gas burner control system which eliminates the need for a pilot light for operation of a gas burner, including a pair of gapped electrical conductors forming a set of ignition points disposed adjacent to a gas burner, a sensor for detecting the presence of the gas to be burned via the gas burner adjacent to the gas burner, means for electrically coupling the sensor means to a relay, the relay controlling the delivery of electrical current to a second relay, the second relay operable in an alternating fashion, means for electrically interconnecting the points of the alternating relay to the pair of ignition points, means for electrically controlling the flow of gas to the gas burner concurrently with the sensing of the existence of gas flowing out of the gas burner by the gas sensor, the alternating relay being operable upon the detection by the sensor means of the flow of gas from the gas burner, remote means for visually indicating if the electrically controlled valve is open, and means for indicating temperature. | ||||||
| 10 | Method and device for controlling a delayed coker system | US827078 | 1986-02-07 | US4698313A | 1987-10-06 | William S. Stewart |
| A delayed coker control system wherein the hydrocarbon feed flows to the coker furnace is automatically limited to the lowest of the maximum allowable flows to avoid furnace zone flooding, an air-limited furnace and overfilling of the coke drum in the cycle time. Flows among the separate furance zones are adjusted to balance heat loads on each stream and to redistribute excess flow to non-flooding zones. | ||||||
| 11 | Fuel level indicator | US143762 | 1980-04-25 | US4339998A | 1982-07-20 | James Finch |
| The present invention relates to a fuel level indicator for a heating unit, such as a stove or furnace. In particular, the invention relates to an indicator for a wood burning heating unit with a grate which is slightly elevated when there is insufficient wood causing an electrical signal which may be used with a light or buzzer to indicate the need for fuel or with a conveyor automatically to feed fuel into the heating unit. | ||||||
| 12 | INTEGRATED FLARE COMBUSTION CONTROL | US15633204 | 2017-06-26 | US20170370579A1 | 2017-12-28 | Daniel Robert Johnson; Chong Tao; Joshua Daniel Brooks; Randy Scott Pfenninger; Lei Sui |
| A system for flare combustion control includes a sound speed measurement device for measuring sound speed in a flare vent gas, and a flare combustion controller including a memory and a processor. The processor is configured to receive the measured sound speed and determine, based on the measured sound speed, a molecular weight of the flare vent gas. The processor is further configured to determine, based on the determined molecular weight, a net heating value of the flare vent gas, and adjust the net heating value of the flare vent gas by regulating an amount of a supplemental fuel gas in the flare vent gas. | ||||||
| 13 | Method of Co-Firing Coal or Oil with a Gaseous Fuel in a Furnace | US14617127 | 2015-02-09 | US20150226421A1 | 2015-08-13 | Chetan Chothani; Charles Lockert; Bernard P. Breen; Alan DePaoli |
| Methods for co-firing a fuel containing coal or oil that is injected into a burner in a furnace by injecting a gaseous fuel are disclosed. The gaseous fuel is injected in a manner so as not to consume air that would otherwise combine with the coal or oil in the primary flame. This can be accomplished by injecting the gaseous fuel at a higher or lower velocity than the coal or oil and combustion air are being injected. This can also be accomplished by directing the gaseous fuel being injected away from the primary flame created when the coal or oil burns. | ||||||
| 14 | APPLIANCE MONITORING APPARATUS | US12993667 | 2009-02-27 | US20110077874A1 | 2011-03-31 | Tsuyoshi Honda; Hiroshi Takechi; Kouji Murase; Kenji Yasuda; Mitsuo Namba; Kazuo Kubo; Hisashi Saito |
| A conventional appliance monitoring apparatus handles only the amount of gas used and security information for the case of a gas cutoff and can not address social needs for a desire to obtain information about influence (e.g., an amount of CO2 emission) of use of the gas combustion appliance on a terrestrial environment.A CO2 emission calculation unit 4 calculates an amount of CO2 emission based on a gas appliance used by a client output from an appliance determination unit 2, a gas flow signal thereof, and CO2 emission data pertaining to the gas appliance stored in a CO2 emission data storage unit 3. Thus, it is possible to determine the amount of CO2 emission produced by using the gas appliance by the client. | ||||||
| 15 | Gas fueled heating appliance | US751742 | 1996-11-18 | US5984663A | 1999-11-16 | John V. Joyce |
| A gas heater is provided with a combustion status sensor that provides heater performance data to a controller that controls the heater according to the sensor data and stored calibration parameters optimized for the particular heater. | ||||||
| 16 | DEVICE FOR MONITORING APPLIANCE | EP09750305.6 | 2009-02-27 | EP2306088B1 | 2018-11-21 | HONDA, Tsuyoshi; TAKECHI, Hiroshi; MURASE, Kouji; YASUDA, Kenji; NAMBA, Mitsuo; KUBO, Kazuo; SAITO, Hisashi |
| A conventional appliance monitoring apparatus handles only the amount of gas used and security information for the case of a gas cutoff and can not address social needs for a desire to obtain information about influence (e.g., an amount of CO 2 emission) of use of the gas combustion appliance on a terrestrial environment. A CO 2 emission calculation unit 4 calculates an amount of CO 2 emission based on a gas appliance used by a client output from an appliance determination unit 2, a gas flow signal thereof, and CO 2 emission data pertaining to the gas appliance stored in a CO 2 emission data storage unit 3. Thus, it is possible to determine the amount of CO 2 emission produced by using the gas appliance by the client. | ||||||
| 17 | REMOTE BURNER MONITORING SYSTEM AND METHOD | EP15001291.2 | 2015-04-30 | EP2940388A1 | 2015-11-04 | Immer, Jeremy Glen; Zhao, Yan; Ward, Christopher Alan; Hendershot, Reed Jacob; Slavejkov, Aleksandar Georgi; Lee, Thomas David Matthew; Gallagher, Michael J. |
A remote burner monitoring system including one or more burners (10) each including integrated sensors (102, 110, 112, 114, 116, 128), a data collector (60) corresponding to each of the burners for receiving and aggregating data from the sensors of the corresponding burner, and a local transmitter (62) corresponding to each of the data collectors for transmitting the data, a data center (200) configured and programmed to receive the data from the local transmitters corresponding to the one or more burners, and a server (84) configured and programmed to store at least a portion of the data, to convert the data into a display format, and to provide connectivity to enable receipt and transmission of data and the display format via a network including at least one of a wired network, a cellular network, and a Wi-Fi network.
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| 18 | DEVICE FOR MONITORING APPLIANCE | EP09750305 | 2009-02-27 | EP2306088A4 | 2013-12-11 | HONDA TSUYOSHI; TAKECHI HIROSHI; MURASE KOUJI; YASUDA KENJI; NAMBA MITSUO; KUBO KAZUO; SAITO HISASHI |
| A conventional appliance monitoring apparatus handles only the amount of gas used and security information for the case of a gas cutoff and can not address social needs for a desire to obtain information about influence (e.g., an amount of CO 2 emission) of use of the gas combustion appliance on a terrestrial environment. A CO 2 emission calculation unit 4 calculates an amount of CO 2 emission based on a gas appliance used by a client output from an appliance determination unit 2, a gas flow signal thereof, and CO 2 emission data pertaining to the gas appliance stored in a CO 2 emission data storage unit 3. Thus, it is possible to determine the amount of CO 2 emission produced by using the gas appliance by the client. | ||||||
| 19 | DEVICE FOR MONITORING APPLIANCE | EP09750305.6 | 2009-02-27 | EP2306088A1 | 2011-04-06 | HONDA, Tsuyoshi; TAKECHI, Hiroshi; MURASE, Kouji; YASUDA, Kenji; NAMBA, Mitsuo; KUBO, Kazuo; SAITO, Hisashi |
A conventional appliance monitoring apparatus handles only the amount of gas used and security information for the case of a gas cutoff and can not address social needs for a desire to obtain information about influence (e.g., an amount of CO2 emission) of use of the gas combustion appliance on a terrestrial environment. A CO2 emission calculation unit 4 calculates an amount of CO2 emission based on a gas appliance used by a client output from an appliance determination unit 2, a gas flow signal thereof, and CO2 emission data pertaining to the gas appliance stored in a CO2 emission data storage unit 3. Thus, it is possible to determine the amount of CO2 emission produced by using the gas appliance by the client. |
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| 20 | HEATING APPLIANCE | EP96909924 | 1996-04-19 | EP0821777A4 | 2000-04-12 | JOYCE JOHN VINCENT; RICHARDS DAVID ALEXANDER |
| A gas heater is provided with a combustion status sensor that provides heater performance data to a controller that controls the heater according to the sensor data and stored calibration parameters optimised for the particular heater. | ||||||
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