子分类:
- B30B1/001: .{通过爆炸装药}
- B30B1/002: .{通过内燃机}
- B30B1/003: .{通过由流体压力膨胀的弹性袋或薄膜}
- B30B1/005: .{通过热膨胀或热蒸发作用}
- B30B1/006: .{通过剪刀或钳子}
- B30B1/007: .{驱动装置和压头之间通过流体连接}
- B30B1/008: .{固定平面和压头之间通过杆来回摆动}
- B30B1/02: .有杠杆机构(有肘节机构入B30B1/10)
- B30B1/10: .用肘节机构
- B30B1/18: .用螺旋装置{(B30B9/3064优先)}
- B30B1/24: .用齿条-小齿轮装置{(B30B9/30G3)}
- B30B1/26: .用凸轮、偏心轮或曲柄
- B30B1/30: .用链或绳拉的{(B30B9/3071优先)}
- B30B1/32: .用液压柱塞的
- B30B1/40: .用楔形装置
- B30B1/42: .用磁力装置,如电磁
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 161 | Rotary type high pressure laser furnace | JP6015484 | 1984-03-28 | JPS60206433A | 1985-10-18 | KASAMATSU MITSUO; OKUTOMI MAMORU |
| PURPOSE:To make it possible to generate high pressure and a high temp., by using laser beam in heating within a laser furnace used in preparing diamond or BN and using centrifugal force in the generation of high pressure. CONSTITUTION:When a high frequency motor 6 is started, a rotary shaft 1 is gradually accelerated to reach a constant high speed and a hollow arm 2 is rotated at a high speed by said rotary shaft 1 to apply high pressure to a specimen M by centrifugal force. Laser beam LB from a laser beam introducing window 9 is incident to the specimen M while reflected by a rotary laser beam reflective mirror 8 to heat the specimen M. By this method, a high temp. and high pressure are applied to specimen M. | ||||||
| 162 | Small transfer molding machine | JP4071884 | 1984-03-02 | JPS60184818A | 1985-09-20 | FUKUDA TAKUO |
| PURPOSE:To achieve a smaller size and a lighter weight with a simple construction for driving a plunger of a small transfer molding machine by operating the plunger with a spring made of a shape memory alloy heated by electric energization thereof. CONSTITUTION:A ring-shaped conductive terminal 16 is fixed on a plunger 14 and a coil spring 17 made of a shape memory alloy is provided with both ends thereof connected to a guide member 15 and the conductive terminal 16. Dies 7 and 8 are set on a molding machine and preheated with hot plates 12 and 13. At the same time or after a fixed time, a switch 19 is closed to run current to the spring 17. With the energization thereof, the spring 17 generates heat and extents with a rising temperature. With such an arrangement, the plunger 14 lowers and fits between pots 21 to perform a molding press melting a tablet. After a fixed time passes, the switch 19 turns OFF to release the spring of the dies 7 and 8 and then, the dies 7 and 8 are pulled out horizontally. As a result, the spring 17 is cooled and shrunk to pull the plunger 14 up to the original position thereby completing the molding. | ||||||
| 163 | JPS596807B2 - | JP13872482 | 1982-08-09 | JPS596807B2 | 1984-02-14 | ISHIKAWA TOSHIISA; TANAKA JUNICHI; TOMINAGA YOICHIRO; MATSUBARA KUNIO; KITATSUME YOSHIHIKO; HAYASE TOKUJI |
| 164 | JPS57501614A - | JP50308381 | 1981-09-24 | JPS57501614A | 1982-09-09 | |
| 165 | Apparatus for ramming waste | JP10119877 | 1977-08-25 | JPS5341073A | 1978-04-14 | ROBAATO ARUFURETSUDO PIITAASON |
| 166 | JPS5041181A - | JP9656373 | 1973-08-28 | JPS5041181A | 1975-04-15 | |
| 167 | SYSTEMS AND METHODS FOR ELECTROMAGNETIC FORMING OF CONTAINERS | US16107249 | 2018-08-21 | US20180354016A1 | 2018-12-13 | Richard H. Lee |
| Systems and methods of forming articles using electromagnetic radiation are disclosed. In some aspects, the system includes a plurality of forming modules movably mounted relative to an infeed mechanism. The infeed mechanism is configured to supply pre-form articles to the plurality of forming modules, and each of the plurality of forming modules includes a multi-segment mold disposed about an electromagnetic coil. The electromagnetic coil is configured to impart an electromagnetic force on the pre-form articles when supplied with electrical energy that urges the pre-form articles into contact with the multi-segment mold to produce the formed containers. | ||||||
| 168 | CYLINDER DEVICE, PRESS MACHINE, WORKPIECE CLAMPING APPARATUS, CYLINDER DEVICE ACTUATING METHOD, METHOD FOR CLAMPING WORKPIECE, AND METHOD FOR PRESSING WORKPIECE | US15919732 | 2018-03-13 | US20180264603A1 | 2018-09-20 | Shigehiro ARAI |
| A pneumatic chamber 20 is configured to include a first pneumatic chamber 21 pressurizing a first piston 11 and a second pneumatic chamber 22 pressurizing a second piston 12. The first pneumatic chamber 21 communicates with the second pneumatic chamber 22. The hydraulic pressure generating unit 55 is internally provided with a hydraulic chamber 30, and the hydraulic chamber 30 is configured to have a first hydraulic chamber 31 pressurized by the first pneumatic chamber 21 via the first piston 11 and a second hydraulic chamber 32 pressurized by the second pneumatic chamber 22 via the second piston 12. The hydraulic pressure generating unit 55 is movable in a thrust direction in a cylinder 2, and the second hydraulic chamber 32 has a function of fixing the moving hydraulic pressure generating unit 55 in the cylinder 2 by causing a thin portion 15 to be elastically deformed in a radial direction due to hydraulic pressure. The first hydraulic chamber 31 outputs hydraulic pressure of the first hydraulic chamber 31, which is increased by the fixing, to an output rod 7. | ||||||
| 169 | SYSTEM AND METHOD FOR BENDING METAL INCLUDING TANDEM PRESS BRAKES | US15814221 | 2017-11-15 | US20180133774A1 | 2018-05-17 | Stephen HILTON; Allen GUERNSEY |
| Two press brake machines each using a single, central hydraulic actuator are provided. The press brake machines are configured to operate separately or in tandem, depending upon a size of a sheet metal workpiece to be deformed. A locking device that may include an upper connecting block and a lower connecting block is provided on each of the at least two press brake machines to allow the machines to interlock when the machines are adjacent to one another and are operating in tandem. The upper connecting block may be “L” shaped to help provide the interlocking. Interlocking of the press brake machines during tandem operation helps prevent distortion that can occur in the upper and lower portions of the ram due to the press brake machine's use of a single, central hydraulic actuator. | ||||||
| 170 | PRESSING ASSEMBLY | US15600772 | 2017-05-21 | US20170341329A1 | 2017-11-30 | JIAN CUI; LONG-FONG CHEN |
| A pressing assembly includes a button, a first connection portion, a receiving portion, a first elastic element, a pressing rod, and a pressing portion. The first connection portion includes a first end movably connected to the button and a second end connected to the receiving portion. The receiving portion defines a receiving space. A part of the pressing rod is movably received in the receiving space. The first elastic element is received in the receiving space. One end of the first elastic element is fixed, another end of the first elastic element resists the pressing rod. The pressing portion is connected to the pressing rod. | ||||||
| 171 | System and method of varying dwell time in a honeycomb plate press | US14609429 | 2015-01-30 | US09782817B2 | 2017-10-10 | William K Chapin |
| A system and method of increasing a dwell time in a foil stamping press is provided. The dwell time is readily adjusted on the fly by the user for a given operating rate. A timer is used to adjust the press to stop on top dead center with changes in images per hour. An air clutch and an original equipment air brake are used in tandem to provide the desired dwell time. A pair of timers governs a pneumatic switch for control of the air clutch and the air brake. The present system and method increase die image area capacity as compared to conventional foil stamping presses. The increased dwell time press yields a flawless foil stamped image for an impression pressure less than that required in a conventional machine for a given die, mounted at a given height upon a stationary platen, and at a given temperature. | ||||||
| 172 | COMPACTION RECEPTACLE | US15401754 | 2017-01-09 | US20170197783A1 | 2017-07-13 | Luke Lundquist; James Faucher |
| A compaction capable receptacle may include a housing with a trash receiving opening, a compaction unit arranged within the housing, and a trash bin arranged within the housing and configured for rotating trash within the bin below the compaction unit. | ||||||
| 173 | Compressive Sintering Apparatus Comprising Protected Opposing Rams | US15147077 | 2016-05-05 | US20160325354A1 | 2016-11-10 | Luke S. Walker; Andrew Bolton |
| A compressive sintering system is described that comprises a die set and a vacuum chamber into which the die set is placed. The die set comprises a die casing and opposing rams forming a die cavity loaded with material to be sintered and is configured to compress the material during sintering. At least one of the opposing rams comprises a surface protection layer, such as a faceplate, in contact with the material to be sintered. | ||||||
| 174 | Activation Assembly for a Press Apparatus | US15059713 | 2016-03-03 | US20160256914A1 | 2016-09-08 | Eric D. Orcutt; Ryan Thomas Ellerbrock |
| A press apparatus includes a press assembly and an activation assembly. The press assembly includes a plurality of dies. The plurality of dies defines a center opening for receiving a work piece. The central opening defines a central longitudinal axis. The activation assembly is adapted to actuate the press assembly. The activation assembly includes a first switch and a second switch. The second switch includes a capacitive touch surface that faces in a direction toward the central longitudinal axis of the press assembly. | ||||||
| 175 | SYSTEM AND METHOD OF VARYING DWELL TIME IN A HONEYCOMB PLATE PRESS | US14846867 | 2015-09-07 | US20160221061A1 | 2016-08-04 | William K. Chapin |
| A system and method of increasing a dwell time in a foil stamping press is provided. The dwell time is readily adjusted on the fly by the user for a given operating rate. A timer is used to adjust the press to stop on top dead center with changes in images per hour. An air clutch and an original equipment air brake are used in tandem to provide the desired dwell time. A pair of timers governs a pneumatic switch for control of the air clutch and the air brake. The present system and method increase die image area capacity as compared to conventional foil stamping presses. The increased dwell time of the present system and method yield a flawless foil stamped image for an impression pressure less than that required in a conventional machine for a given die, mounted at a given height upon a stationary platen, and at a given temperature. | ||||||
| 176 | LINK-LOCK POWER WORK DEVICE, COMPONENTS THEREOF, AND METHODS OF MAKING AND USING THE SAME | US14146939 | 2014-01-03 | US20150190924A1 | 2015-07-09 | Todd M. Clees; Marek P. Bieciuk |
| A number of variations may include a link-lock power work device, components thereof and methods of making and using the same. | ||||||
| 177 | Method and apparatus for compressing particulate matter | US13382061 | 2010-06-23 | US08679387B2 | 2014-03-25 | Hisao Yoshioka; Sigeyasu Ito |
| A compression molding apparatus for particulate matter comprising a magnetostrictive actuator functioning as an impact force applying means arranged at least between an upper ram or a lower ram and an upper punch or a lower punch. Particulate matter is compressed by a static pressure, and then an impact force is applied to the particulate matter to reduce internal stress. After compressing the particulate matter by the static pressure, the upper ram is allowed to fall gravitationally to shorten a molding time. | ||||||
| 178 | LINEAR MOTOR MOUNTED PRESS MACHINE AND METHOD FOR CONTROLLING LINEAR MOTOR MOUNTED PRESS MACHINE | US11842265 | 2007-08-21 | US20080041241A1 | 2008-02-21 | Hiroichi SAKAMOTO |
| The present invention provides a linear motor mounted press machine which uses a boosting mechanism to enable machining with a greater press tonnage using a press driving source with relatively low power and which, for machining with a smaller press tonnage, enables efficient high-speed machining. A linear motor mounted press machine includes a boosting mechanism 10 having an output portion that performs a rectilinear reciprocating operation, a first linear motor 11 coupled to an output portion of the boosting mechanism 10, a second linear motor 12 having an output shaft that drives a press tool 6 forward and backward, and a coupling switching mechanism 13. The coupling switching mechanism 13 releasably couples the output shaft of the second linear motor 12 to the output portion of the boosting mechanism 10. The boosting mechanism 10 is a toggle type link mechanism or the like. A servo motor and a crank mechanism or the like may be used in place of the first linear motor 11. | ||||||
| 179 | Platen press | US09844310 | 2001-04-27 | US06935228B2 | 2005-08-30 | Henry A Brandtjen, Jr.; Kenneth Rinard; Robert W. Palmer |
| A method and an apparatus for varying the dwell parameters for a platen press are disclosed. The method involves creating an impression force between first and second platens using a driven biasing member where movement of the member is controlled by a tensioner. The apparatus includes a driven biasing member that is linked to at least one of the first and second platens that form the press and a tensioner linked to the biasing member. The bias and tensioner permit the dwell time to be extended and allows the impression force between the platens to be variably applied. | ||||||
| 180 | Smart card connector with retain and eject means | US09706423 | 2000-11-03 | US06539853B1 | 2003-04-01 | Achim Hess; Martin Gollhofer; Klaus Siegert |
| A press that includes a push rod (12) that can be pushed downward to cut and mold miniature components, has a small size and a minimum number of components, and can be easily and precisely controlled. The push rod has a largely upwardly-facing shoulder (140) that lies in a chamber that can receive pressured hydraulic fluid to push down the push rod. A piezoelectric actuator, or piezoactor (18), moves a piston (20) that lies in a pressure cylinder. One end of the pressure cylinder holds hydraulic fluid (130), and when the piezoactor pushes the piston it pressurizes the hydraulic fluid therein. Pressured hydraulic fluid in the pressure cylinder flows through a passage (23) to the rod chamber to press down the push rod. The cross-sectional area of the pressure cylinder is many times greater than the cross-sectional area of the push rod shoulder so slight movement of the piezoactor is magnified many times by the hydraulic fluid to move the push rod with a long stroke. | ||||||
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