序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
---|---|---|---|---|---|---|
301 | 締結部構造 | JP2014501119 | 2013-12-17 | JP6308437B2 | 2018-04-11 | 井上 卓也; 山口 晃司; 松岡 英夫; 中越 宏明 |
302 | 伸縮アームを用いた形状可変枠体 | JP2016161979 | 2016-08-22 | JP2018031391A | 2018-03-01 | 松岡 徳康 |
【課題】伸縮アームの伸縮動作に応じて形状を変えることのできる形状可変枠体を提供する。 【解決手段】形状可変枠体100は、枠を形作るように配置された複数の伸縮アームA,B,C,Dと、隣接する伸縮アームの端部同士を連動可能に連結する連結機構30とを備え、各伸縮アームは、X字状に交差させた2個の剛性部材21,22を中央連結軸23を介して回動可能に連結したクロスユニット20の複数個と、隣接するクロスユニットの端部同士を回動可能に連結する端部連結部とを含み、連結機構は、隣接する一方の伸縮アームの内側端連結軸と他方の伸縮アームの外側端連結軸とを回動可能に連結する第1折れ曲がり部材と、隣接する一方の伸縮アームの外側端連結軸と他方の伸縮アームの内側端連結軸とを回動可能に連結する第2折れ曲がり部材と、第1折れ曲がり部材と第2折れ曲がり部材とを交差部で回動可能に連結する屈曲部連結軸とを有する。 【選択図】図4 |
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303 | 構造的なモジュール式建物のコネクタ | JP2017508717 | 2015-04-30 | JP2017515027A | 2017-06-08 | ボーロン、ジュリアン |
下部コネクタに対して結合された上部コネクタと上部コネクタと下部コネクタとの間で挟まれたガセットプレートとを有するコネクタ組立体。さらに開示されたのは、引き上げ可能なコネクタ組立体、持ち上げフレーム組立体、モジュール式フレームユニットのための結合システム、コネクタ組立体を用いてモジュールユニットを組み立てるための方法、ならびに、コネクタ組立体を有するモジュール式フレームユニットおよび建物。【選択図】図11 | ||||||
304 | 車両の補剛構造 | JP2016202533 | 2016-10-14 | JP2017024719A | 2017-02-02 | トーマス・クラウシャー |
【課題】構造部材(2)と、前記構造部材(2)の空洞(3)内に配置された補剛部(4)とを有する補剛構造(1)を与える。 【解決手段】前記補剛部(4)は、支持部(5)と結合手段(6)とを有しており、前記支持部(5)は前記空洞(3)内に配置されているので、前記支持部(5)と前記構造部材(2)との間の距離が、前記構造部材(2)への外部からの力の作用(8)の下で変形する可能性が比較的高い前記構造部材(2)の箇所(7)において、外部からの力の作用(8)の下で変形する可能性が比較的低い前記構造部材(2)の箇所(9)に対して、より小さくなる。 【選択図】図1 |
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305 | 車両の補剛構造 | JP2014156769 | 2014-07-31 | JP2014218246A | 2014-11-20 | THOMAS KRAUSHAAR |
【課題】構造部材(2)と、前記構造部材(2)の空洞(3)内に配置された補剛部(4)とを有する補剛構造(1)を与える。【解決手段】前記補剛部(4)は、支持部(5)と結合手段(6)とを有しており、前記支持部(5)は前記空洞(3)内に配置されているので、前記支持部(5)と前記構造部材(2)との間の距離が、前記構造部材(2)への外部からの力の作用(8)の下で変形する可能性が比較的高い前記構造部材(2)の箇所(7)において、外部からの力の作用(8)の下で変形する可能性が比較的低い前記構造部材(2)の箇所(9)に対して、より小さくなる。【選択図】図1 | ||||||
306 | Stiffening the structure of the vehicle | JP2011527329 | 2009-09-18 | JP5592376B2 | 2014-09-17 | トーマス・クラウシャー |
307 | Stiffening the structure of the vehicle | JP2011527329 | 2009-09-18 | JP2012502841A | 2012-02-02 | トーマス・クラウシャー |
構造部材(2)と、前記構造部材(2)の空洞(3)内に配置された補剛部(4)とを有する補剛構造(1)において、前記補剛部(4)は、支持部(5)と結合手段(6)とを有しており、前記支持部(5)は前記空洞(3)内に配置されているので、前記支持部(5)と前記構造部材(2)との間の距離が、前記構造部材(2)への外部からの力の作用(8)の下で変形する可能性が比較的高い前記構造部材(2)の箇所(7)において、外部からの力の作用(8)の下で変形する可能性が比較的低い前記構造部材(2)の箇所(9)に対して、より小さくなる。 | ||||||
308 | Heating or airrconditioning case for automobile | JP10143580 | 1980-07-25 | JPS5660712A | 1981-05-25 | HANSU TORUUBE; HERUMAN GURIMU; BUORUFUGANGU BUORUTSU |
309 | Assembly apparatus | JP2042078 | 1978-02-25 | JPS53110218A | 1978-09-26 | YOHANESU MARUCHINUSU RAIYONAAD |
310 | LAMINATE CELL CONSTRUCTION SYSTEM | US15764254 | 2016-09-27 | US20180274222A1 | 2018-09-27 | Carlos Gadsden Lopez; Carlos Eduardo Gadsden Hevia |
The present invention proposes a novel construction system consisting of the attachment of modified hyperboloid shaped-structural elements called “laminate cells” which, when working together, create a structural system with integrated cover having the capacity of absorbing and transmitting stresses in all directions and orientations. | ||||||
311 | SHIM PLATE | US15580415 | 2016-05-31 | US20180149187A1 | 2018-05-31 | Jae-Hyoung Jeon; Yang-Bae Jo; Won-Chan Park |
According to an aspect of the present disclosure, a shim plate which is inserted between components that are assembled to and disassembled from one another via at least one shaft may be provided. The shim plate includes a plurality of plate pieces that are separable from one another, wherein the plurality of plate pieces are configured such that one plate piece is connected to the other plate piece in a circumferential direction, and an internal ring-shaped empty space is formed. | ||||||
312 | CELLULAR STRUCTURES WITH TWELVE-CORNERED CELLS | US15291465 | 2016-10-12 | US20180100621A1 | 2018-04-12 | Tau TYAN; Leonard Anthony SHANER |
A cellular structure may include a plurality of cells. Each cell of the plurality of cells may have a twelve-cornered cross section. The twelve-cornered cross-section may include two sides each having a first cross-sectional length, and ten sides each having a second cross-sectional length that differs from the first cross-sectional length. | ||||||
313 | Fitting for strut channel | US14541812 | 2014-11-14 | US09926957B2 | 2018-03-27 | Zhihui Zhang; Qiang Li |
A fitting for connecting first and second pieces of strut to one another includes a coupling component. The coupling component has first and second coupling portions configured for reception in respective fitting grooves of the first and second pieces of strut when the coupling component is in a first orientation. Each of the coupling portions are rotatable within the respective fitting grooves from the first orientation to a second orientation to connect the first and second pieces of strut to one another. An anti-rotation plate is connected to the coupling component. The anti-rotation plate has an unlocked position relative to the coupling component to allow the first and second coupling portions to be received in the respective fitting grooves, and a locked position relative to the coupling component to inhibit rotation of each of the first and second coupling portions from the second orientation to the first orientation. | ||||||
314 | METHOD FOR CONNECTING HOLLOW PROFILES | US15800308 | 2017-11-01 | US20180065313A1 | 2018-03-08 | Markus Flaig; Philipp Scheiner |
A method is provided for connecting hollow profiles (1-4) in a joint (10) to produce a load-bearing structure (5). The method includes placing ends of hollow profiles (1-4) in a mold and pressing the ends together with at least one semi-finished product to connect the ends of the hollow profiles to the semi-finished product. | ||||||
315 | Construction method for foldable units | US14796288 | 2015-07-10 | US09857026B1 | 2018-01-02 | Charles Hoberman |
A foldable unit comprised of linkages in the form of tubular prisms is provided. The unit may be additionally comprised of polygonal panels. Linkages and panels correspond to a central polyhedral design that may be specified from a wide variety of geometric arrangements. | ||||||
316 | Shape-morphing space frame apparatus using unit cell bistable elements | US15197203 | 2016-06-29 | US09783977B2 | 2017-10-10 | Ahmad Alqasimi; Craig Lusk |
Unit cell bistable elements, and particular arrangements thereof, that can transform or morph a structure from one shape to another. In certain embodiments, the current invention includes unit cell bistable elements, and particular arrangements and uses thereof, that can transform or morph a structure from one shape to another. In an embodiment, the current invention provides a method/ability to transform any four-bar compliant mechanism into a bistable compliant mechanism. It is an object of the current invention to facilitate structures morphing from one specific shape to another specific shape using unit cell bistable elements. | ||||||
317 | Systems and methods for value bearing indicia balance reservation | US13217896 | 2011-08-25 | US09727860B1 | 2017-08-08 | Geoffrey C. Begen |
Systems and methods which operate to reserve an amount of value associated with a value bearing indicia (VBI) request or requests are shown. Embodiments facilitate completion of a multiple VBI session without failing due to insufficient value balance once the session has begun. Additionally or alternatively, embodiments facilitate later or subsequent (e.g., scheduled) completion of a VBI session, whether a session for a single VBI or multiple VBI, without failing due to insufficient value balance. Value reservations may be made automatically and/or manually. Embodiments provide various reservation priority levels, such as to individual users, user groups, user systems, sessions, types of sessions, jobs, etc., in order to facilitate completion of various desired operations without failure due to insufficient value. Value reservation techniques according to embodiments do not introduce additional transactions into a normal VBI session flow. | ||||||
318 | Self-erecting shapes | US15156132 | 2016-05-16 | US09695586B1 | 2017-07-04 | Matthew W. Reading |
Technologies for making self-erecting structures are described herein. An exemplary self-erecting structure comprises a plurality of shape-memory members that connect two or more hub components. When forces are applied to the self-erecting structure, the shape-memory members can deform, and when the forces are removed the shape-memory members can return to their original pre-deformation shape, allowing the self-erecting structure to return to its own original shape under its own power. A shape of the self-erecting structure depends on a spatial orientation of the hub components, and a relative orientation of the shape-memory members, which in turn depends on an orientation of joining of the shape-memory members with the hub components. | ||||||
319 | SHAPE-MORPHING SPACE FRAME APPARATUS USING UNIT CELL BISTABLE ELEMENTS | US15197203 | 2016-06-29 | US20170145681A1 | 2017-05-25 | Ahmad Alqasimi; Craig Lusk |
Unit cell bistable elements, and particular arrangements thereof, that can transform or morph a structure from one shape to another. In certain embodiments, the current invention includes unit cell bistable elements, and particular arrangements and uses thereof, that can transform or morph a structure from one shape to another. In an embodiment, the current invention provides a method/ability to transform any four-bar compliant mechanism into a bistable compliant mechanism. It is an object of the current invention to facilitate structures morphing from one specific shape to another specific shape using unit cell bistable elements. | ||||||
320 | 3-D Honeycomb Foam Structure | US15110402 | 2015-01-07 | US20160325520A1 | 2016-11-10 | Jonathan Berger |
What is presented is a unit cell that has a cellular geometry that comprises cell walls and cell edges arranged into a combination of a cubic cell geometry and a tetrahedral cell geometry and assembled structures that comprise a plurality of unit cells. The voids of the unit cell created by the combination of geometries comprise regular tetrahedrons, irregular tetrahedrons, and octahedrons. In some embodiments, the thickness of selected cell walls can vary and in some embodiments have zero thickness. In some embodiments selected cell walls and selected cell edges have a varied thickness. In other embodiments selected cell walls are non-planar. In some embodiments selected cell walls may have one or more holes. Selected cell edges of some embodiments of unit cell may have varying cross-sectional geometry that vary along a length of the cell edge. Some embodiments of the unit cell may comprise fillets to blunt stress concentrations. |