| 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 | 一种带二次燃烧室的锅炉 | CN201511007175.6 | 2015-12-30 | CN105571123A | 2016-05-11 | 黄仪经 |
| 本发明公开了二次燃烧室的锅炉,其特征在于燃烧室上方设有二次燃烧室,燃烧室经二次燃烧室与首级换热室相连通,燃烧室和二次燃烧室经筒状出火管相连通,筒状出火管的进火口伸在燃烧室内,筒状出火管的出火口伸在换热室内,所述的筒状出火管的出火口端设有呈锥筒状的拢火罩,拢火罩大径端与二次燃烧室相连接并将伸在二次燃烧室内的筒状出火管笼在其中内,拢火罩与筒状出火管同轴线,拢火罩壁上设有出火口供风管,出火口供风管的一端与外部风源相连接,出火口供风管另一端伸出拢火罩内壁并朝向偏离拢火罩轴线方向,使筒状出火管出来的火焰进行旋转流动,在高温条件下使筒状出火管出来但没有燃烧的煤气进行二次燃烧,提高燃煤的燃烧效率。 | ||||||
| 2 | 垃圾燃气即热式热水锅炉装置及使用方法 | CN201610070061.4 | 2016-02-02 | CN105546813A | 2016-05-04 | 李观德 |
| 本发明公开了一种垃圾燃气即热式热水锅炉装置,包括炉体,炉体内自下而上依次设有落灰腔、一级燃烧腔和二级燃烧腔,所述落灰腔和一级燃烧腔之间设有水管炉排,一级燃烧腔和二级燃烧腔之间设有具有通孔的水管隔断模块,水管隔断模块上设有扣在通孔上方的挡灰罩机构,挡灰罩机构外设有反射蓄热罩,反射蓄热罩的下部侧壁上设有多个通气孔,所述落灰腔设有出灰口,所述一级燃烧腔连接有进料机构,所述二级燃烧腔内设有安装在反射蓄热罩外的水夹套机构。本发明不仅可以使垃圾更充分的燃烧,焚烧后能够对冷水进行快速加热,而且能进行水管的加热,提供热水资源,从而大幅减少环境污染和能量浪费。 | ||||||
| 3 | 用法高度灵活的热交换器 | CN201210023338.X | 2012-01-16 | CN102589317A | 2012-07-18 | G-L·安基奥利尼 |
| 一种用法高度灵活的热交换器(1a、1b、1c、1d),包括盒状本体(2a、2b、2c、2d),该盒状本体在其内界定至少一个热交换室(3、13、23)并具有用于供燃烧产物沿较佳路径穿过热交换室(3、13、23)的至少一个入口(4)和至少一个出口(5)。更具体地,盒状本体(2a、2b、2c、2d)在其侧壁内至少部分地限定用于馈送待加热流体的至少一个管道,在热交换室(3、13、23)内设有热交换构件(7),热交换构件(7)与供给管道关联以增加热交换器(1a、1b、1c、1d)的热效率。本发明的特性在于其包括相互互连以限定盒状本体(2a、2b、2c、2d)的多个不同的模块化构件(8a、8b、8c、8d、9a、9b、9c、9d)。有利地是,每个模块化构件(8a、8b、8c、8d、9a、9b、9c、9d)包括热交换构件(7)的至少一个部分、供给管道的至少一个部分以及热交换室(3、13、23)的至少一个部分,以根据要求获得不同尺寸和技术特性的热交换器(1)。 | ||||||
| 4 | 具有两个燃烧室的双燃料无管锅炉 | CN200580025221.3 | 2005-06-30 | CN101002055A | 2007-07-18 | 阿利·尼扎米·厄兹詹 |
| 使用作为本发明主题的新型锅炉来代替现有的固体、液体以及气体燃料的锅炉,特别地设计本发明的锅炉以高效地同时燃烧固体燃料和液体燃料或天然气,并且其构造与现有锅炉不同,本发明的锅炉具有改进的全自动化的由带有减速器的马达驱动的炉排系统,这使得煤可以连续地供给且渣块可连续地流动,具有自动化的、可根据煤中硫含量的比例来调节石灰供给的干式脱硫系统,具有用于燃烧液体和气体燃料的、与固体燃料燃烧室独立的特别燃烧室,以及具有特别的无管设计,其使得除了通过辐射传热之外还可以通过传导和诱导来传热,本发明的锅炉是一种新型的、具有特别的无管设计的双燃料锅炉,其通过全自动化的供给和极高的操作容易度且无烟地来燃烧煤,并且由于其干式脱硫系统而可以减少二氧化硫排放。 | ||||||
| 5 | 热水器 | CN200810186995.X | 2008-12-12 | CN101457978A | 2009-06-17 | 安藤正和 |
| 本发明提供一种经由排气管道将燃烧废气排出室外的室内设置型热水器。其解决的课题是:通过能力切换机构减少燃烧的燃烧器群的数量,降低燃烧能力时,可以防止通风力降低并提高热能效率。其解决方法是:送气室(81)被分隔为多个部分(82)、(83),该多个部分(82)、(83)与多个燃烧器群(51)、(52)相对应,并且,送气风机(84)供给的空气只向与燃烧中的燃烧器群相对应的送气室的部分提供。 | ||||||
| 6 | 燃焼装置およびそれを備えた燃焼装置システム | JP2016208833 | 2016-10-25 | JP2018071824A | 2018-05-10 | 岡本 真一; 武庫 隆雄 |
| 【課題】 複数の燃焼装置において排気経路を共通化している場合に、複数の燃焼装置間で通信不能状態が発生した際の各燃焼装置における燃焼禁止動作を適切に行うことができる燃焼装置およびそれを備えた燃焼装置システムを提供する。 【解決手段】 燃焼装置における燃焼の制御を行う燃焼制御部と、複数の燃焼装置の排気経路が共通化された共通排気状態か否かを設定する設定部と、燃焼制御部が通信接続された他の燃焼制御部との接続構成を記憶する記憶部と、を備え、燃焼制御部は、複数の燃焼装置に対する連係動作を制御する連係制御部または他の燃焼制御部との通信可否を判定し、連係制御部または少なくとも1つの他の燃焼制御部との通信が不能であると判定された場合かつ設定部において共通排気状態に設定されている場合に、当該燃焼制御部が属する燃焼装置の燃焼を禁止する。 【選択図】 図1 |
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| 7 | Combustion apparatus | JP2011166028 | 2011-07-28 | JP2013029254A | 2013-02-07 | OKAMOTO SHINICHI; DOYAMA MASATO |
| PROBLEM TO BE SOLVED: To provide a combustion apparatus appropriately performing safety control based on detection of exhaust gas temperature according to the actual combustion state determined by changing and switching combustion capacity.SOLUTION: Capacity control switching valves SV1, SV2, SV3 switching gas supply to three different combustion areas F1-F3 demarcated corresponding to a group of three combustion burners 21, a group of five combustion burners 21 and a group of nine combustion burners 21, are subjected to control over switching for selectively opening/closing according to the required quantity of heat by a controller. With this, the combustion areas F1, F2, F3 are selectively burned, and the combustion capacity is changed and switched to a plurality of combustion capacity levels. An exhaust gas temperature sensor 10 is installed to the vicinity of the inlet of an exhaust tube 2a; meanwhile, determination temperature corresponding to the combustion capacity level of each of the plurality of combustion capacity levels is set for determining abnormality of high temperature of exhaust gas. If the detected exhaust gas temperature exceeds the determination temperature corresponding to the number of the current combustion capacity level, abnormality is informed; meanwhile, forced combustion is stopped. | ||||||
| 8 | Oogatashunkanshikyuwakashiki | JP18936784 | 1984-09-10 | JPH0239700B2 | 1990-09-06 | NISHI TAKAHIRO; WATANABE MITSUYOSHI; WATANABE TAISUKE |
| 9 | 給湯装置 | JP2015253769 | 2015-12-25 | JP2016205799A | 2016-12-08 | 西村 和裕; 廣津 誠 |
| 【課題】給湯動作再開時の給湯温度を安定させることが可能な給湯装置を提供する。 【解決手段】第1の伝熱管T1を有する1次熱交換器HE1と、第1の伝熱管T1に接続されて第1の伝熱管T1よりも高い位置に配されている第2の伝熱管T2を有する2次熱交換器HE2と、第2の伝熱管T2の入水側端部に接続された入水路2と第1の伝熱管T1の出湯側端部11bに接続された出湯路4との両者を接続するバイパス流路21と、を備えている、給湯装置WH1であって、出湯路4には、この出湯路4と第1の伝熱管T1の出湯側端部11bとの接続部Jまたはその近傍部分から上向き、または斜め上向きに起立した起立部41aが形成されていることにより、出湯側端部11bよりも高い位置にオフセットされたオフセット流路部41が設けられている。 【選択図】 図1 |
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| 10 | Water heater | JP2007320459 | 2007-12-12 | JP2009144948A | 2009-07-02 | ANDO MASAKAZU |
| PROBLEM TO BE SOLVED: To provide a water heater which prevents decrease in draft force, caused when the number of burner groups to be burned is reduced by a capacity changeover mechanism to decrease combustion capacity, and improves heat efficiency, in the indoor mounted water heater in which combustion exhaust gas is discharged to the outdoors via an exhaust duct. SOLUTION: An air supply chamber 81 is divided into a plurality of parts 82 and 83 corresponding to a plurality of burner groups 51 and 52. The air sent from an air supply fan 84 is supplied to only a part of the air supply chamber corresponding to the burning burner group. COPYRIGHT: (C)2009,JPO&INPIT | ||||||
| 11 | Composite hot water feeder | JP20710882 | 1982-11-25 | JPS5997453A | 1984-06-05 | WATANABE HIROAKI; FUJISHITA KAZUO |
| PURPOSE:To make the titled hot water feeder compact and small-sized and to improve the combustibility thereof by a method wherein exhaust gas passages which are independent of each other are provided. CONSTITUTION:Two kinds of combustion burners 19 and 20, combustion chambers 21 and 22 and heat exchangers 23 and 24 are provided in the body 18 of the hot water feeder. One of the heat exchangers 23 is in communication with an exhaust cylinder 25 whose top end confronts an exhaust top chamber 27 of an exhaust top 26 and the other heat exchanger 24 is in communication with an exhaust cylinder 30. Further, a fan 29 is provided midway in the exhaust cylinder 30 whose top end confronts an exhaust top chamber 31 of the exhaust top 26. In the subject hot water feeder, the fan 29 is used for a heat source giving a large amount of combustion and a natural supply and exhaust system is used for a heat source giving a small amount of combustion. Consequently, it is possible to make the hot water feeder small-sized and compact and to prevent the lowering of the stability of combustion and the thermal efficiency thereof bacause the hot water feeder is not influenced by the other heat exchanger. | ||||||
| 12 | Boiler | JP2047181 | 1981-02-14 | JPS57134645A | 1982-08-19 | IKEDA TOSHIO |
| PURPOSE:To facilitate the control of combustion of a solid fuel and enhance heating efficiency by a method wherein at least two furnaces are provided in a water chamber and air is supplied to each of the furnaces from above and below. CONSTITUTION:A tank part 18 is formed in the interior of a casing 10 by a partition plate 16, and two furnaces 12, 14 are placed in the tank part 18. The furnace 12, 14 consists of a lower cylinder 20 and an upper cylinder 22 which has a relatively smaller diameter. An upper part of the lower cylinder 20 is partitioned by a flange 24 to form a chamber 52, the side wall of the cylinder 20 is provided with a fuel charge port 26 and an ash raking-out port 28, and the upper cylinder 22 is communicated into an exhaust pipe 46 through an opening provided at its side wall. A blowing port of a blower 48, 50 is communicated into an air supply disk 34 provided at the bottom part of the furnace 12, 14 so as to supply air through a perforated plate at the upper surface of the disk 34, while a blowing pipe is branched and is connected to an air supply pipe 42 inserted into the furnace 12, 14 from the top part of the furnace. The lower end of the air supply pipe 42 is located to penetrate through an opening formed at the flange 24, and a plurality of holes 43 are formed in the peripheral wall of the air supply pipe 42. | ||||||
| 13 | Twoochamber type boiler | JP4124580 | 1980-04-01 | JPS55134201A | 1980-10-18 | ARUFUREETO FUOOKUTO |
| 14 | Water heater | US15079643 | 2016-03-24 | US10066852B2 | 2018-09-04 | Kazuhiro Nishimura; Makoto Hirotsu |
| A water heater has a primary heat exchanger having a first heat transfer tube, a secondary heat exchanger having a second heat transfer tube connected with the first heat transfer tube and being located higher than the first heat transfer tube, and an outflow path connected to an outflow-side end portion of the first heat transfer tube. The outflow path has an offset flow path portion including a rising portion which rises upward or obliquely upward from a connecting portion of the outflow path and the outflow-side end portion of the first heat transfer tube or from the vicinity of the connecting portion, the offset flow path portion being offset at a position higher than the outflow-side end portion. When hot water supply is temporally stopped, the water at high temperature in the first heat transfer tube flows into the offset flow path portion, thereby inhibiting such a disadvantage that water having a lower temperature than a target temperature is supplied because of a natural convection at the time of restarting hot water supply. | ||||||
| 15 | WATER HEATER | US15079643 | 2016-03-24 | US20160313027A1 | 2016-10-27 | Kazuhiro NISHIMURA; Makoto HIROTSU |
| A water heater has a primary heat exchanger having a first heat transfer tube, a secondary heat exchanger having a second heat transfer tube connected with the first heat transfer tube and being located higher than the first heat transfer tube, and an outflow path connected to an outflow-side end portion of the first heat transfer tube.The outflow path has an offset flow path portion including a rising portion which rises upward or obliquely upward from a connecting portion of the outflow path and the outflow-side end portion of the first heat transfer tube or from the vicinity of the connecting portion, the offset flow path portion being offset at a position higher than the outflow-side end portion. When hot water supply is temporally stopped, the water at high temperature in the first heat transfer tube flows into the offset flow path portion, thereby inhibiting such a disadvantage that water having a lower temperature than a target temperature is supplied because of a natural convection at the time of restarting hot water supply. | ||||||
| 16 | Combustion apparatus | US13554521 | 2012-07-20 | US09291364B2 | 2016-03-22 | Shinichi Okamoto; Masato Doyama |
| According to the required amount of heating, a controller of a combustion apparatus exercises selective on-off switching control on capacity control switching valves for the supplying of gas to three different combustion areas partitioned respectively by a group of three combustion burners, a group of five combustion burners and a group of nine combustion burners, whereby the three combustion areas can selectively be burned, thereby the combustion capacity is changed and switched to any of a plurality of combustion capacity levels. A combustion exhaust temperature sensor is disposed in the vicinity of the inlet of an exhaust stack. Judgment temperatures corresponding respectively to combustion capacity levels for combustion exhaust high-temperature abnormality judgment are set. If the detected combustion exhaust temperature exceeds the judgment temperature corresponding to a current combustion capacity level, this provides a notification indicative of the occurrence of an abnormality while combustion is forcibly stopped. | ||||||
| 17 | LATENT HEAT EXCHANGER AND WATER HEATER | US13990962 | 2011-11-18 | US20130264037A1 | 2013-10-10 | Shinya Otsubo; Hidekatsu Naruse; Yoichi Kojima |
| A latent heat exchanger (1) has a casing (2), a heat-absorbing tube (50) accommodated in the casing (2), an inlet header (60), and an outlet header (70). The casing (2) has a casing main body (10) and a top plate (40) closing an upper opening (16) of the casing main body (10). The back wall (11), the front wall (12), the bottom wall (13), one side wall (14), and the other side wall (15) of the casing main body (10) are formed integrally by draw-processing a single metal plate. | ||||||
| 18 | Condensation heat exchanger including 2 primary bundles and a secondary bundle | US12072913 | 2008-02-28 | US07909005B2 | 2011-03-22 | Joseph Le Mer; Rocco Giannoni |
| This exchanger comprises a pair of primary tubular bundles (5a, 5b) surrounding a fuel or gas burner (4a, 4b), and a secondary tubular bundle (6) on which condensation of the steam contained in the burned gases discharged from the primary bundles occurs, wherein the three bundles (5a, 5b, 6) are mounted parallel, side-by-side inside a gas-tight casing (10), and communicate with one another, with means being provided in order to circulate the water to be heated, between the tubes forming the secondary bundle (6) and the tubes forming the primary bundles (5a, 5b); the casing (10) is subdivided at the level of the secondary bundle (6) by a partition (7-70) that extends both inside and outside said bundle (6), with the arrangement being such that a only a circumferential section of the latter is capable of being contacted and traversed by the hot gases coming from one of the two primary bundles (5a), and its remaining section being capable of being contacted and traversed only by the hot gases coming from the other primary bundle (5b).Household or industrial heating installation with high efficiency and low bulk. | ||||||
| 19 | Heating apparatus | US10593350 | 2005-03-23 | US07647897B2 | 2010-01-19 | Ichiro Ootomo; Hiroshi Asakura; Toshihiro Hori; Nobuhiro Takeda; Kazuhiro Kimura; Akira Tsutsumi; Takayasu Fujita; Masakuni Morikawa |
| A heating apparatus 1 includes a shell 2, a primary heat exchanger (sensible heat exchanger) 3, a burner (combustion means) 5, and a fan 6. A secondary heat exchanger (latent heat exchanger) 7 has a plurality of heat receiving tubes 18 arranged in parallel between a pair of headers 16 and 17, the heat receiving tubes 18 being fixed to tube plates 20. The heat receiving tubes 18 are bare tubes without fins and are arranged across flow of combustion gas. The number of the tubes 18 arranged vertically is less than the number of the tubes 18 arranged horizontally. | ||||||
| 20 | WATER HEATER | US12330913 | 2008-12-09 | US20090151654A1 | 2009-06-18 | Masakazu Ando |
| There is provided an indoor mounting water heater in which combustion exhaust gas is discharged to the outdoors via an exhaust duct, wherein a decrease in draft force caused when the number of burner groups to be burned is reduced by a capacity changeover mechanism to decrease the combustion capacity can be prevented, and the heat efficiency can be improved. An air supply chamber 81 is divided into a plurality of parts 82 and 83 corresponding to a plurality of burner groups 51 and 52. The air sent from an air supply fan 84 is supplied to only a part of the air supply chamber corresponding to a burning burner group. | ||||||
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