子分类:
| 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 | 一种二氧化碳循环式水氢动力镐 | CN201610220554.1 | 2016-04-11 | CN105762387A | 2016-07-13 | 向华 |
| 本发明揭示了一种二氧化碳循环式水氢动力镐,包括:甲醇制氢系统、氢气发电系统、甲醇制备设备、镐本体,甲醇制氢系统与氢气发电系统连接,氢气发电系统与甲醇制备设备连接;所述甲醇制氢系统利用甲醇水蒸气重整制备氢气,氢气通过镀有钯银合金的膜分离装置获得高纯度的氢气,获取的氢气通过氢气发电系统发电;所述甲醇制备设备包括:氢气输送装置、第二输送装置、合成反应器;所述第二输送装置为二氧化碳输送装置或/和一氧化碳输送装置;所述氢气输送装置、第二输送装置分别与合成反应器连接;所述合成反应器内氢气与二氧化碳或一氧化碳反应,生成甲醇及水。本发明提出的循环式水氢动力镐,可自制发电系统所需的甲醇,并避免二氧化碳的排放。 | ||||||
| 2 | 钢化玻璃破碎器 | CN201510041620.4 | 2015-01-28 | CN104724037A | 2015-06-24 | 仲杏英 |
| 本发明提供一种钢化玻璃破碎器,包括一个长圆柱形气筒,所述气筒的后端封闭,前端匹配一个旋盖;所述气筒内部设有一个可沿气筒内壁自由滑动的滑塞;所述滑塞前端连接一根与滑塞同轴的支杆,所述支杆前端连接一根与支杆同轴的螺杆,所述螺杆的前端连接一个带有尖锥的破击部件;所述旋盖中央开设有与所述螺杆相匹配的螺孔;所述气筒内部,靠近气筒前端处设有一个内径小于所述螺杆的外径的限位环,对所述滑塞构成限位;所述滑塞到达所述限位环的位置时,被所述滑塞封闭的气筒内的气压大于1个标准大气压。该钢化玻璃破碎器结构简单,使用方便,且理论上可以破碎任意坚固的钢化玻璃。 | ||||||
| 3 | 手持式工具机及其控制方法 | CN201310132618.9 | 2013-04-17 | CN103372851B | 2016-07-27 | M·哈特曼; E·普法伊费尔 |
| 本发明涉及一种手持式工具机及其控制方法,该手持式工具机包括:用于在工作轴线(10)上保持凿用工具的工具支座;气动的冲击机构,该冲击机构具有在工作轴线上可移动的锤(13)、通过马达在前面的远工具死点和近工具死点之间来回被驱动的激励器(12)以及由激励器和锤封闭的气动室(15),该气动室用于将激励器的运动耦合到锤上;以及缓冲装置,其具有预压缩器(19)以及受控制的排气阀(32),当激励器处在远工具死点附近时,受控制的排气阀允许空气从预压缩器流入气动室中。 | ||||||
| 4 | 一种针对容器内衬里拆除的专用工具 | CN201310275415.5 | 2013-07-02 | CN104275675A | 2015-01-14 | 王怀绪; 赵瑞林; 祁洪军 |
| 本发明公开了一种针对容器内衬里拆除的专用工具,包括支架、风镐和气缸,所述支架上设有风镐和气缸,支架与气缸固定连接,支架与风镐为滑动连接,气缸上设有气缸杆,风镐上设有镐柄和镐筒,所述镐筒上设有导向管,所述导向管与所述支架滑动连接,所述支架上侧设有悬挂吊架,所述支架后端两侧均设有把手,所述把手内侧设有给气阀。本发明操作简单,有效的提高了劳动效率,降低了劳动强度。 | ||||||
| 5 | 具有独立气体弹簧的液压锤 | CN201680017557.3 | 2016-03-30 | CN107438693A | 2017-12-05 | L·P·皮勒斯二世 |
| 公开了一种用于与锤(12)一起使用的气体弹簧(38)。气体弹簧具有主体(44),其具有中心轴线(46)和孔(48),该孔与中心轴线对准并且延伸至主体的至少一个开口轴向端。气体弹簧还具有由主体完全包围并且彼此隔离的多个气室(50)。孔具有与多个气室连通的柔性环形壁。 | ||||||
| 6 | 冲击装置及拆卸该冲击装置的方法 | CN201410641453.2 | 2014-11-13 | CN104632069B | 2017-10-03 | 蒂莫·穆托宁; 米科·海迈莱伊宁; 拉斯·坎德林; 泰穆·希耶塔卡里 |
| 本发明涉及冲击装置及拆卸该冲击装置的方法。所述冲击装置(12)包括衬套(16),在衬套(16)内是撞击活塞(21)。所述冲击装置被布置在破碎装置(15)的框架(20)内形成的冲击装置空间内。所述撞击活塞设置有拉肩(33),该拉肩(33)允许拆卸力(FB)在返回方向(B)上从所述撞击活塞传递到所述衬套。因此,所述衬套借助于所述撞击活塞从所述框架被取出。 | ||||||
| 7 | 冲击装置及拆卸该冲击装置的方法 | CN201410641453.2 | 2014-11-13 | CN104632069A | 2015-05-20 | 蒂莫·穆托宁; 米科·海迈莱伊宁; 拉斯·坎德林; 泰穆·希耶塔卡里 |
| 本发明涉及冲击装置及拆卸该冲击装置的方法。所述冲击装置(12)包括衬套(16),在衬套(16)内是撞击活塞(21)。所述冲击装置被布置在破碎装置(15)的框架(20)内形成的冲击装置空间内。所述撞击活塞设置有拉肩(33),该拉肩(33)允许拆卸力(FB)在返回方向(B)上从所述撞击活塞传递到所述衬套。因此,所述衬套借助于所述撞击活塞从所述框架被取出。 | ||||||
| 8 | 手持式工具机及其控制方法 | CN201310132618.9 | 2013-04-17 | CN103372851A | 2013-10-30 | M·哈特曼; E·普法伊费尔 |
| 本发明涉及一种手持式工具机及其控制方法,该手持式工具机包括:用于在工作轴线(10)上保持凿用工具的工具支座;气动的冲击机构,该冲击机构具有在工作轴线上可移动的锤(13)、通过马达在前面的远工具死点和近工具死点之间来回被驱动的激励器(12)以及由激励器和锤封闭的气动室(15),该气动室用于将激励器的运动耦合到锤上;以及缓冲装置,其具有预压缩器(19)以及受控制的排气阀(32),当激励器处在远工具死点附近时,受控制的排气阀允许空气从预压缩器流入气动室中。 | ||||||
| 9 | 鉄筋コンクリートの制御されたブリーチングのための装置及び方法 | JP2008321234 | 2008-12-17 | JP5809776B2 | 2015-11-11 | マイク ブレナン; ブレット ゴールドステイン; ルイス ジラルド; ロブ ウォレス; ジョン ライアン; エド デゼリック; マイク ミルスポー |
| 10 | JPS5867670U - | JP16118681 | 1981-10-30 | JPS5867670U | 1983-05-09 | |
| 11 | WERKZEUGVORSATZ FÜR EINE HANDWERKZEUGMASCHINE | EP14713817.6 | 2014-03-26 | EP2981395A1 | 2016-02-10 | BLUM, Jens; ROEHM, Heiko; WELKE, Joerg; SAUR, Dietmar; HERR, Tobias |
| The invention relates to a tool attachment (300) for a hand-held power tool, which hand-held power tool has a housing having a fastening interface. The tool attachment comprises an attachment housing (305), on which a locking unit (350) for locking the tool attachment (300) to the fastening interface of the hand-held power tool and a tool receptacle (340) for receiving an insertion tool are arranged. An impact unit (320) is arranged in the attachment housing (305), which impact unit is designed to apply impacts performed in the axial direction of the tool receptacle (340) to the insertion tool during impact operation of the tool attachment (300). | ||||||
| 12 | Device and method for controlled breaching of reinforced concrete | EP08254024.6 | 2008-12-17 | EP2072190A1 | 2009-06-24 | Brennan, Mike; Goldstein, Brett; Giraldo, Luis; Wallace, Rob; Ryan, John; Dezelick, Ed; Millspaugh, Mike |
A breaching apparatus (100) includes an impactor element (106,108) and a self-contained energy source. The self-contained energy source (102) enables the impactor element (106,108) to impact a first surface of a structure. The impactor element is configured to transmit a localized shock wave through the structure upon impact. The self-contained energy source (102) is capable of accelerating the impactor element (106,108) to a velocity sufficient to induce spalling at a second surface of the structure. Multiple breaching apparatuses can be supported by a frame (704) to facilitate simultaneous or successive breaching of the structure. The breaching apparatus (100) can be used in a method to breach a concrete structure.
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| 13 | SEAL PLACEMENT DEVICE | US15123883 | 2014-03-03 | US20170014960A1 | 2017-01-19 | Gregory MENISSEZ; Remi DURIEU |
| A device (100) for placing a seal (J) on a mounting (S) including a vibration generator (10), that includes: a main body (11); a distal portion (12), movable relative to the main body, onto which a cap (13) having a contact surface (13a) for engaging with the seal is attached; and drive elements (14), configured to drive the distal portion in reciprocal translation relative to the main body, such as to place the seal on the mounting when the contact surface (13a) of the cap (13) engages with the seal (J) that is placed on the mounting (S). The device includes: a grasping handle (20), connected to the main body; and resilient connection elements (30a, 30b) that are located between the main body and the grasping handle and are configured such as to limit the propagation, in the grasping handle, of the vibrations generated by the reciprocal translation movement. | ||||||
| 14 | HYDRAULIC HAMMER HAVING SELF-CONTAINED GAS SPRING | US14679499 | 2015-04-06 | US20160288306A1 | 2016-10-06 | Lauritz Phillip PILLERS, II |
| A gas spring is disclosed for use with a hammer. The gas spring may have a body with a central axis, and a bore aligned with the central axis and extending to at least one open axial end of the body. The gas spring may also have a plurality of gas chambers fully enclosed by the body and isolated from each other. The bore may have a flexible annular wall in communication with the plurality of gas chambers. | ||||||
| 15 | Device and method for controlled breaching of reinforced concrete | US12906443 | 2010-10-18 | US08342069B2 | 2013-01-01 | Mike Brennan; Brett Goldstein; Luis Giraldo; Rob Wallace; John Ryan; Ed Dezelick; Mike Millspaugh |
| A breaching apparatus includes an impactor element and a self-contained energy source. The self-contained energy source enables the impactor element to impact a first surface of a structure. The impactor element is configured to transmit a localized shock wave through the structure upon impact. The self-contained energy source is capable of accelerating the impactor element to a velocity sufficient to induce spalling at a second surface of the structure. Multiple breaching apparatuses can be supported by a frame to facilitate simultaneous or successive breaching of the structure. The breaching apparatus can be used in a method to breach a concrete structure. | ||||||
| 16 | Device and Method for Controlled Breaching of Reinforced Concrete | US12906443 | 2010-10-18 | US20110030539A1 | 2011-02-10 | Mike Brennan; Brett Goldstein; Luis Giraldo; Rob Wallace; John Ryan; Ed Dezelick; Mike Millspaugh |
| A breaching apparatus includes an impactor element and a self-contained energy source. The self-contained energy source enables the impactor element to impact a first surface of a structure. The impactor element is configured to transmit a localized shock wave through the structure upon impact. The self-contained energy source is capable of accelerating the impactor element to a velocity sufficient to induce spalling at a second surface of the structure. Multiple breaching apparatuses can be supported by a frame to facilitate simultaneous or successive breaching of the structure. The breaching apparatus can be used in a method to breach a concrete structure. | ||||||
| 17 | Molding and emblem removal tool | US884899 | 1997-06-30 | US5930899A | 1999-08-03 | Robert L. Hartman; Roger A. Koessl |
| A pneumatic scraping tool includes a pneumatic hammer assembly including a cylinder in which a piston reciprocates for repeated impact against an anvil or blade holder which is rotatably received within an end of the cylinder and carries a scraping blade. The anvil has an annular flange which stops its insertion in the cylinder, and is retained in place by a nut threadedly engaged with the cylinder and having an end wall spaced from the cylinder end a distance slightly greater than the flange thickness to permit reciprocation of the anvil. Exhaust air passes along a groove in the outer surface of the cylinder to an annular chamber in the nut and thence through four exhaust ports exiting at the end wall of the nut. A plug portion of the anvil projects through a central opening in the nut end wall and is received into a socket in a blade housing. Blade fingers project laterally into the socket. Alternating side grooves and flats on the plug portion allow the blade assembly to be rotated roughly one-quarter turn between a latched condition and a release condition in which the plug portion can be inserted into and removed from the socket. A spring-biased detent ball in the cylinder engages a square inner end of the anvil to form a ratchet, accommodating rotation of the anvil in only one direction. | ||||||
| 18 | Percussion device | US667281 | 1984-11-01 | US4630687A | 1986-12-23 | Paul Dummermuth |
| A pneumatic hammer comprises a cylindrical housing, in which are a free piston, an anvil, and needles the rear ends of which end in heads designed to rest against the anvil and supported by a tool holder. The anvil comprises a steel cylinder in the lateral surface of which is an annular rebate. The cylinder is surrounded by a plastics material in the rebate, the outer surface of which material forms the cylindrical sliding surface of the anvil. The volume occupied by the plastics material is approximately 50% of the total volume, such that the mass of the anvil is approximately halved. | ||||||
| 19 | Transducer for converting fluid pressure oscillations into mechanical oscillations | US3583158D | 1969-01-10 | US3583158A | 1971-06-08 | FOSTER KEITH; DUFF JOHN FREDERICTON |
| A transducer for converting fluid pressure oscillations into mechanical oscillations comprising a piston member moveable in a cylinder, first and second opposing faces of the piston member being disposed in first and second chambers of the cylinder, both chambers being adapted to contain pressure fluid, means to connect at least the first chamber to a source of oscillating pressure fluid to cause the piston member to oscillate relatively to the cylinder, and cooling means to permit a restricted flow of pressure fluid sequentially through one said chamber and then through the other said chamber to a relatively low pressure region, whereby to cool the transducer.
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| 20 | Werkzeugmaschine | EP13163866.0 | 2013-04-16 | EP2653269A3 | 2017-01-04 | Hartmann, Markus; Pfeiffer, Eduard |
Die erfindungsgemäße Handwerkzeugmaschine hat eine Werkzeugaufnahme zum Haltern eines meißelnden Werkzeugs auf einer Arbeitsachse 10. Ein pneumatisches Schlagwerk hat auf der Arbeitsachse 10 einen beweglichen Schläger 13, einen Erreger 12 und eine von dem Erreger 12 und dem Schläger 13 abgeschlossene pneumatische Kammer 15, die die Bewegung des Erregers 12 an den Schläger 13 ankoppelt. Der Erreger 12 ist von einem Motor angetrieben und bewegt sich zwischen einem werkzeug-fernen vorderen Totpunkt und einem werkzeug-nahen Totpunkt hin-und-her. Eine Dämpfeinrichtung enthält einen Vorverdichter 19 und ein gesteuertes Auslassventil 32. Das gesteuerte Auslassventil 32 lässt Luft von dem Vorverdichter 19 in die pneumatische Kammer 15 einströmen, wenn der Erreger 12 in der Nähe des werkzeug-fernen Totpunkts ist.
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