| 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 | 管道输送系统 | CN201180014649.3 | 2011-01-19 | CN102811931A | 2012-12-05 | 伊恩·多伊格 |
| 一种配备有至少一泵(400)的管道(500),其运输分散于管道中共同运输的检管器之间的间隔内的传递流体中的颗粒。各个泵和各个检管器配置为在所述检管器和颗粒通过各个泵期间保持检管器之间的间隔以及所述检管器的定向。而且,作为保持颗粒分散于管道内的装置,各个检管器可以包括周边的孔,其提供传递流体泄漏进入各个检管器下游间隔。在绘示的示例中,颗粒通过进口供给料斗(400)引入该管道,并且颗粒在输送料斗650处从该管道移除。料斗404在该管道进口引入检管器,并且料斗652在该管道出口移除检管器;检管器通过管道(500A)返回至料斗(404)。 | ||||||
| 2 | INTERLOCKING TEETH FOR STRENGTHENING PINNED CONNECTION BETWEEN KNUCKLE-JOINTED LANCE SEGMENTS | US16030579 | 2018-07-09 | US20180318892A1 | 2018-11-08 | William C. Thomas |
| A Knuckle Jointed Lance (KJL), comprising a segmented lance including a plurality of elongate and hollow KJL segments in a concatenated string thereof. The first segment end of one KJL segment is rotatably connected to the second segment end of a neighboring KJL segment via a pinned connection. Neighboring pairs of KJL segments together provide an interlocking toothed connection such that each interlocking toothed connection restrains relative torsional displacement between the neighboring pair of KJL segments. In other embodiments, pinned connections also provide ears, each with cooperating ear ledges and ear ledge recesses to strengthen the pinned connection. | ||||||
| 3 | SYSTEM AND METHOD FOR CLEANING PNEUMATIC CONVEY LINES | US15584504 | 2017-05-02 | US20170313524A1 | 2017-11-02 | Jonathan O. THORN; Russell A. HEINEN |
| A cleaning system for cleaning a pneumatic conveyance system used to transport particulate material. The pneumatic conveyance system includes a material-introduction device for introducing particulate material into a convey line, and a motive air source for generating an air flow to propel the particulate material through the convey line. The cleaning system comprises a projectile comprising a cleaning surface for cleaning an interior of the convey line as the projectile travels through the convey line, a launcher for injecting the projectile into the convey line, with the launcher being coupled with the convey line at a position upstream from the material-introduction device, and a catcher vessel for receiving the projectile upon said projectile exiting the convey line. | ||||||
| 4 | High density pneumatic transport system for use in powdered or granular materials | US445669 | 1989-12-01 | US5154545A | 1992-10-13 | Kiyoshi Morimoto; Akikazu Iwamoto; Masuo Moriyama; Junji Nakagawa |
| An improvement of a high density pneumatic transport system for pneumatically transporting powdered or granular materials placed in an airtight storage container to a collector through a transport pipe having a vertical riser pipe intermediately thereof by the use of pressurized gas. The transport pipe comprises a lower horizontal pipe being connected to the airtight storage container and having a convergent cylindrical accelerating reducer, an upper horizontal pipe being connected to the collector and having a divergent cylindrical decelerating reducer at its initial end, and a vertical riser pipe which connects the lower horizontal pipe to the upper horizontal pipe. The vertical riser pipe is provided at intermediate thereof up and down with an acceleration regulating reducer having a convergent accelerating portion above its bottom having a constricted portion and a divergent cylindrical decelerating reducer. | ||||||
| 5 | System and method for cleaning pneumatic convey lines | US15584504 | 2017-05-02 | US10092934B2 | 2018-10-09 | Jonathan O. Thorn; Russell A. Heinen |
| A cleaning system for cleaning a pneumatic conveyance system used to transport particulate material. The pneumatic conveyance system includes a material-introduction device for introducing particulate material into a convey line, and a motive air source for generating an air flow to propel the particulate material through the convey line. The cleaning system comprises a projectile comprising a cleaning surface for cleaning an interior of the convey line as the projectile travels through the convey line, a launcher for injecting the projectile into the convey line, with the launcher being coupled with the convey line at a position upstream from the material-introduction device, and a catcher vessel for receiving the projectile upon said projectile exiting the convey line. | ||||||
| 6 | Enhanced knuckle-jointed lance useful for internal cleaning and inspection of tubulars | US15603332 | 2017-05-23 | US10016793B2 | 2018-07-10 | William C. Thomas |
| A Knuckle Jointed Lance (KJL), comprising a segmented lance including a plurality of connected KJL segments in a concatenated string thereof. The first end of one KJL segment is rotatably connected to the second end of a neighboring KJL segment via a pinned connection. Responsive to user assignment of a predetermined length to each KJL segment in the concatenated string according to the KJL segment's corresponding pre-ordained position in the concatenated string, the lance is disposed to spool onto a reel in “nested” fashion, such that as the lance makes spooling revolutions onto the reel, (a) KJL segments stack in circumferential registered layers around the reel and (b) pinned connections trace substantially radial vectors from a center of the reel. Other embodiments provide additional features to facilitate nesting and to generally strengthen the KJL. | ||||||
| 7 | ENHANCED KNUCKLE-JOINTED LANCE USEFUL FOR INTERNAL CLEANING AND INSPECTION OF TUBULARS | US15603332 | 2017-05-23 | US20170252783A1 | 2017-09-07 | William C. Thomas |
| A Knuckle Jointed Lance (KJL), comprising a segmented lance including a plurality of connected KJL segments in a concatenated string thereof. The first end of one KJL segment is rotatably connected to the second end of a neighboring KJL segment via a pinned connection. Responsive to user assignment of a predetermined length to each KJL segment in the concatenated string according to the KJL segment's corresponding pre-ordained position in the concatenated string, the lance is disposed to spool onto a reel in “nested” fashion, such that as the lance makes spooling revolutions onto the reel, (a) KJL segments stack in circumferential registered layers around the reel and (b) pinned connections trace substantially radial vectors from a center of the reel. Other embodiments provide additional features to facilitate nesting and to generally strengthen the KJL. | ||||||
| 8 | System and method for traversing pipes | US14818799 | 2015-08-05 | US09739411B1 | 2017-08-22 | Shaun Azimi; Darby Magruder; Justin Ridley; Anthony Lapp; Jodi Graf; Ross Pettinger |
| A system and method is provided for traversing inside one or more pipes. In an embodiment, a fluid is injected into the one or more pipes thereby promoting a fluid flow. An inspection device is deployed into the one or more pipes at least partially filled with a flowing fluid. The inspection device comprises a housing wherein the housing is designed to exploit the hydrokinetic effects associated with a fluid flow in one or more pipes as well as maneuver past a variety of pipe configurations. The inspection device may contain one or more sensors capable of performing a variety of inspection tasks. | ||||||
| 9 | Coin collection system for multiple parking meter stations | US65564967 | 1967-07-24 | US3419209A | 1968-12-31 | BEN MUNN |
| 10 | Sample automatic extraction system of automatic sample extraction method and solids of solids | JP29088389 | 1989-11-08 | JP3027837B2 | 2000-04-04 | 順二 中川; 昭和 岩本; 富郎 新井; 圭雄 森山; 清 森本; 正彦 清水; 勝也 渡邊 |
| 11 | High density pneumatic transport method and apparatus of the powder particles | JP25117286 | 1986-10-21 | JP2640812B2 | 1997-08-13 | MORIMOTO KYOSHI; IWAMOTO AKIKAZU; MORYAMA YOSHIO; SONODA TOYORO |
| 12 | Pneumatic transport method of solid pneumatic transport for the transport plug of material and solid material using the same | JP30800490 | 1990-11-13 | JP2640873B2 | 1997-08-13 | MORIMOTO KYOSHI; MIWA SADAKAZU; ISHII SHINZO; MURATA KAZUHIDE |
| 13 | Transport of powdered granule by high concentration gas and apparatus thereof | JP25117286 | 1986-10-21 | JPS63106230A | 1988-05-11 | MORIMOTO KIYOSHI; IWAMOTO AKIKAZU; MORIYAMA YOSHIO; SONODA TOYORO |
| PURPOSE: To transport the powdered granules at an exceedingly low speed without applying an impact onto the powdered granules by taking out the powdered granules into a transport conduit by intermittently feeding a gas pressure into a sealed storage container and synchronously feeding transport cocks into the transport conduit and successively forming the cylindrical transported articles of the powder granules which are divided by the transport cocks. CONSTITUTION: The powdered granules in a storage container 1 are sent into a trans port conduit 4 by the pressure of the compressed air which is intermittently supplied through an air feeding pipe 3. At this time, a transport cock 16 is sent from the basic edge part of the transport conduit 4 through the air feeding pipe 3. Then, the powdered granules are applied with a pressing force by the transport cock 16 which is transported from the behind and transported compulsorily in a horizontal conduit part 42. Therefore the powdered granules are formed into a long cylindrical transported article P in the horizontal conduit part 42, and transported at an exceedingly low speed, and after the speed is further reduced in a speed decelerating device 10, the article P is collected into a collecting device 5. Since the transport at the exceedingly low speed is permitted, no impact force is applied onto the powdered granules. COPYRIGHT: (C)1988,JPO&Japio | ||||||
| 14 | AUTOMATED PIPELINE PIG HANDLING SYSTEM | US15280079 | 2016-09-29 | US20170089502A1 | 2017-03-30 | Pablo Daniel Genta |
| Certain aspects of the subject matter described here can be implemented as a method. A location of an entrance to a pipeline pig launcher configured to launch a pipeline pig into a pipeline is determined by an automated pipeline pig handling system positioned at a starting location. The pipeline pig is self-aligned with the entrance to the pipeline pig launcher by the automated pipeline pig handling system. The entrance to the pipeline pig launcher is open. The pipeline pig is inserted by the automated pipeline pig handling system into the entrance to the pipeline pig launcher. The entrance to the pipeline pig launcher is closed by the automated pipeline pig handling system after the pipeline pig is inserted into the entrance. The automated pipeline pig handling system is self-returned to the starting location after inserting the pipeline pig into the entrance to the pipeline pig launcher. | ||||||
| 15 | Pipeline Conveyor Systems | US13577275 | 2011-01-19 | US20130011209A1 | 2013-01-10 | Ian D. Doig |
| A pipeline (500) equipped with at least one pump (400) transports granules dispersed in a carrier fluid in intervals between co-transported pigs in a pipeline. Each pump and each pig is configured to preserve the intervals between pigs, and the orientation of the pigs, during passage of the pigs and granules through each pump. Also, each pig may comprise peripheral apertures providing a leakage of carrier fluid into the intervals downstream of each pig as a means of preserving the dispersion of granules within the pipeline. In the example shown granules are introduced to the pipeline by inlet feed hopper (400), and granules are removed from the pipeline at outlet delivery hopper 650. Hopper 404 introduces pigs at the pipeline inlet and hopper 652 removes pigs at the pipeline outlet: pigs are returned to hopper (404) by the pipeline (500A). | ||||||
| 16 | Transport plug for use in pneumatically transporting solid materials and a pneumatic transport method employing the transport plug | US791974 | 1991-11-13 | US5211514A | 1993-05-18 | Kiyoshi Morimoto; Teiichi Miwa; Shinzo Ishii; Murata Kazue |
| A transport plug for pneumatically transporting solid materials in a transport pipe by the use of a pressurized transport gas and a pneumatic transport method of solid materials employing the transport plug. The transport plug comprises two bodies consisting of a front body and a rear body defining a material storing space for storing solid materials between the two bodies, at least one supplementary body connected to the rear body, and flexible connecting means coupling said three bodies. A supplementary material storing space is defined between the supplementary body and the rear body. Solid materials are fed into the material storing space of the transport plug, transported through the transport pipe together with the transport plug, and received in a collector under gravitational fall. | ||||||
| 17 | Method of sampling solid materials and sampling system to execute the method | US457248 | 1989-12-27 | US5056962A | 1991-10-15 | Kiyoshi Morimoto; Akikazu Iwamoto; Katsuya Watanabe; Masahiko Shimizu; Masuo Moriyama |
| A method and the related system for sampling solid materials. Materials as continuously manufactured from a compression molding machine are sampled at fixed intervals and the materials thus sampled are fed into a transport pipe so as to be transferred by being accompanied by a transport plug into an inspecting station at low speed from its stand-by position in the pipe when a gas control means is set in a feed mode. After transferring sampled materials the transport plug left at its terminal position in the transport pipe is automatically returned to the stand-by position through the transport pipe when the gas control means is set in a suction mode. By executing the above steps repeatedly, sampled materials are successively transferred into the inspecting station by being accompanied by the transport plug under unmanned operation. | ||||||
| 18 | High density pneumatic transport method for use in powder or granular material and system for practicing the method | US112106 | 1987-10-20 | US4856941A | 1989-08-15 | Kiyoshi Morimoto; Akikazu Iwamoto; Masuo Moriyama; Atsuroh Sonoda |
| An improved method and the related system for pneumatically transporting a powder or granular material placed in an airtight storage container through a transport pipe in high density. In the invention, pressurized gas is being intermittently supplied to the airtight storage container containing the material therein so as to take out of the container and a transport plug is being synchronously fed into the base of the transport pipe, whereby the powder or granular material is successively formed into a long column inside the transport pipe and is pneumatically transported at very slow speed. | ||||||
| 19 | Horizontal type hydrohoist | US447357 | 1974-03-01 | US3938912A | 1976-02-17 | Masakatsu Sakamoto; Kenji Uchida; Makoto Saito; Yasunori Yamada; Yoshiyuki Takenaka |
| There is disclosed a horizontal type hydrohoist, in which slurry is forced to feed under lower pressure into feed pipes which are connected to a transport pipeline at their one ends and to a high pressure clear water pump at the others, said pump being adapted to deliver clear water under a high pressure, after which clear water is transferred under a high pressure through said feed pipe from said high pressure clear water pump, thereby transferring said slurry. This hydrohoist system presents the provision of means for preventing mixing and its spreading at the boundary portion between slurry and water within the feed pipes. More particularly, a separator which is designed not to rotate during the transfer is inserted in the aforesaid boundary portion in a manner that the separator may be transferred together with fluid, thus preventing the mixing of water with slurry as well as the resultant spreading thereof. According to a further aspect of the invention, at the completion of the slurry transfer under a high pressure, the separator is caused to be gradually slowed down to stop for the purpose of obviating a water hammer phenomenon within the pipings. In addition, after the removal of the slurry remaining around the separator by using a high pressure water, the feeding of the high pressure water is interrupted, thereby preventing mixing and its spreading at the boundary portion of water with slurry at the time of the subsequent introduction of slurry under lower pressure. | ||||||
| 20 | Transfer plug for air transfer of solid material and air transfer method of solid material using the same | JP30800490 | 1990-11-13 | JPH04217512A | 1992-08-07 | MORIMOTO KIYOSHI; MIWA SADAKAZU; ISHII SHINZO; MURATA KAZUHIDE |
| PURPOSE: To hinder the biting in of a solid material even when the solid material is filled in from a material input port by providing at least one auxiliary column on the rear part of two columns that specify material storing space, and by coupling these columns together through a soft coupling material. CONSTITUTION: Measured solid material is input and filled in between two columns 11 and 12 that specify the material storing space (a) of a transfer column, from a material input port formed on the starting end of a transfer pipe. A transfer column A is pneumatically transferred at low speed by supplying a pressurized transfer gas in the transfer pipe. The solid material leaked and thus dropped at the time is stored in the space (b) between the rear column 12 and an auxiliary column 13. COPYRIGHT: (C)1992,JPO&Japio | ||||||
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